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* [[MATERIALE DIDATTICO]] <br><br></div>Apolemihttps://web.ing.unimo.it/wiki/index.php?title=Research_Activity&diff=7418Research Activity2010-06-23T01:50:48Z<p>Apolemi: /* TOPICS */</p>
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<div>= TOPICS <br> =<br />
My research activity begins at the Department of Information Engineering of the University of Siena, mainly oriented to the asymptotic study of the Green’s function associated with truncated periodic arrays of elementary sources embedded in multilayered environment. This activity has been pursed in collaboration with Prof. Felsen (University of Boston). Contemporarily, my scientific activity has also investigated analytical and numerical methods in electromagnetism, for the prediction of the electromagnetic scattering frm large objects, with Prof. Roberto Tiberio and Prof. Stefano Maci as supervisors. The research activity has also been developed in the framework of national research programs (PRIN), university research programs (PAR), and in the framework of projects financed by the Italian Space Agency (ASI). I also participated to European research programs, as ACE and EAML. <br />
<br />
The experience on periodic structures and on Green's function for multilayered structures has allowed me to start a fruitful collaboration with Politecnico di Torino, to arrange new and efficient tools for the analysis of aperiodic and periodic printed elements embedded in dielectric materials. Also, my interests have been focused on lens antennas, for which I am involved in a European Research Networking Program (RNP) with University of Rennes, Radio Frequency IDentification systems, and on microwave radiometers for fire detection. <br />
<br />
I’m currently involved in a European working group (lead by Prof. Per-Simon Kildal from Chalmers Univeristy of Technology) focused on the investigation of new generations of waveguides, to be employed in the higher region of the microwave spectrum. In this working group, I developed analytical models to describe the dispersion characteristic of metallic waveguides based on periodic stop band surfaces.<br />
<br />
Recently, in the framework of a collaboration with Prof. Nader Engheta (University of Pennsylvania) and Prof. Andrea Alù (University of Texas at Austin), I started to work on metamaterials and plasmonic structure at optical frequencies, with particular interest towards plasmonic channels and nanocircuits. My interest concerns specifically the numerical and analytical description of the dispersion characteristic of plasmonic waveguides, together with the possibility to load them with nanoparticles, which act as nanoinductors and nanocapacitors. <br />
<br />
Also, within the collaboration with Prof. Kevin Shuford at the Drexel University, I recently started to work on the interaction between nanoparticles and molecules, providing both analytical and numerical support to the investigation the spectra of assembled nanoparticles, with particular interest to periodic SERS nanosurface. <br />
<br><br><br><br><br />
<br />
== ASYMPTOTIC METHODS FOR ARRAY ANTENNAS<br> ==<br />
The research activity in this area is focused on the development and application of asymptotic methods for analysis and design of array antennas embedded in multilayered dielectric environment. In particular, the research is mainly dedicated to the characterization of diffraction phenomena, generated by the periodicity truncation (semi-infinite array, sectoral array) through the array Green’s function (AGF), and through the subsequent integration of the representation into full-wave codes for the efficient analysis of printed antennas. <br><br />
<br />
<br />
===Array Green’s function (AGF): diffraction phenomena generated by edge truncation on dielectric slab===<br />
For a correct description of the diffraction generated by the array edge truncation, and interpreted in terms of rays according to the Geometrical Theory of Diffraction (GTD) generalized to periodic structures, the AGF must take into account not only for the presence of dielectrics, but also for the presence of periodicity. If the array is infinite, the Floquet theorem allows to express the AGF as superposition of a complete set of modes (Floquet modes), weighted by the spectral Green’s function of the single element in the periodicity. If the array is finite, this expansion cannot be directly applied. The aim of this research branch is that to formulate an AGF for an efficient treatment of truncated periodic array on dielectric slabs. The goal is reached referring to appropriate canonical problems. The first is that of introducing the truncation effects due to the edge (semi-infinite array), either for an array of line sources [R2], or for an array of point sources [R1][R4][C1]-[C5]. The integral describing the diffraction from the array edge can be evaluated applying asymptotic techniques. The knowledge of the asymptotic array Green’s function, not only is of advantage for the computational times, but it also allows to check separately the various field contributions (truncated Floquet modes, truncated surface and leaky waves), predicting the eventual interaction [R5][R6][C9][C11].<br />
<br />
[[File:AGF.png|900px]]<br><br />
Fig.1 Phenomenology associated with Semi-Infinite Array Green’s Function (AGF).(left) Semi-infinite elementary sources on multilayered environment (middle) Topology of the AGF (right) Schematic representation of the transition from a conical wave to a plane surface wave in 3D and 2D views<br />
<br />
=== Array Green’s function (AGF): diffraction phenomena generated by vertex truncation on dielectric slab ===<br />
In order to complete the extension o the Geometrical Theory of Diffraction (GTD) generalized to periodic structures it is necessary to develop an efficient asymptotic solution for the canonical problem associated with a sectoral array, where the truncation is present along both directions, including either spatial diffraction contribution or guided waves diffraction contribution. An hybrid technique based on an appropriate decomposition into canonical problems is developed to include diffraction terms, with particular care to the observation on the array surface, which is of basic importance when the continuity conditions of electric and magnetic fields must be applied [C14][C20][C23]. The method is based on an iterative process of subtraction, from the infinite array, of canonical problems constituted by semi-infinite and sectoral arrays. Each of these problems can be treated separately, applying convenient techniques, according to the observation region [C26][C28][C33].<br />
<br />
<br />
[[File:sector.png|800px]]<br><br />
Fig.2 Phenomenology associated with the Sectoral Array Green’s Function (AGF).(left) Sector of elementary sources on multilayered environment (middle) and (right) Schematic representation of the transition from edge and vertex diffracted waves. <br />
<br />
=== Introduction of the array Green’s function inside full-wave codes for the analysis of larege array antennas===<br />
The asymptotic Green’s function allows also to describe the field contributions due to the presence of double truncations. Thus, it could be efficiently employed to extend the applicability of full-wave methods also to very large array. This objective is reached solving the MoM through an appropriate regularized integral equation (“fringe” equation), where the unknown current is expanded on entire domain basis function, with behaviour imposed by dominant diffraction contributions [C6][C7][C10][C12][C16]. The main objective of this activity is concerned with an efficient evaluation of the Array Green’s Function (AGF) and its clever application into a MoM, while remaining in the application framework of arrays or periodic<br />
surfaces which exhibit weak variability with respect to periodicity of geometry and excitation. The high frequency method used here has the advantage to be additive with respect to the one associated with the infinite structure, with additional (edge)<br />
contribution which is not invariant by phase shifted translation, thus allowing the reuse of already existing numerical codes [C20]. The strategy adopted is briefly the following. All the elements of the array are discretized with triangular cells, where the Rao-Wilton-Glisson (RWG) basis functions are defined; in the AGF-MoM approach, the MoM problem is set-up and solved for each element in isolation, instead to implement the global array MoM reactions with a reduction of complexity and memory occupation. Thus, the key advantage in using the AGF in the MoM is in the possibility of evaluating and solving only the MoM<br />
matrix of each element against itself, instead of the MoM matrix of the whole array. The integration of the AGF with the MoM is organized in two steps and repeated for all the array elements.<br />
<br />
[[File:MOM.png|500px]]<br><br />
Fig.3 MoM Strategy for finite size arrays <br />
<br />
<br><br><br><br><br />
<br />
== GREEN'S FUNCTION CHARACTERIZATION FOR STRATIFIED DIELECTRICS<br> ==<br />
<br />
The activity is essentially devoted to the modeling of printed antenna.<br><br />
<br />
=== Characterization of guided phenomena===<br />
The presence of dielectric substrates influences the real radiating antenna performance and complicates the electromagnetic analysis. In fact, the structure supports guided waves propagation, in particular surface waves or leaky waves. On one hand, these kinds of guided waves can degrade the radiating antenna performance, on the other hand they can be employed to improve directivity/gain. Indeed, composite planar dielectric structures used for increasing the directivity of a point<br />
source, have been investigated since many years. This substrate/superstrate structure was demonstrated to establish a resonance condition, which maximizes antenna gain, radiation resistance, and radiation efficiency. Particular attention has been given to the physical interpretation of this resonance gain effect, which can be described in terms<br />
of leaky waves (LW) excited in the structure. Under certain resonance conditions, a pair of weakly attenuated TE/TM leaky waves become the dominant contributions to the antenna aperture field. Although the demonstrated interest in such<br />
type of configurations, the polarization characteristics of the structure wasn't investigated enough. The aim of this research activity has been to rigorously demonstrate that the conventional choice of the stratification, not only ensures a large aperture field, but the same field is also well polarized when excited by any linearly polarized point source [R7] [C29].<br><br />
<br />
[[File:Lens.png|800px]]<br><br />
Fig.4 (left) Topological investigation of coalescence of leaky waves (resonance condition) in a substrate/superstrate structure; (middle) and (left) purity of polarization of the copolar component of a linear polarized source embedded in such a substrate/superstrate structure.<br />
<br />
<br />
=== Asymptotic models===<br />
To characterize the dielectric structures, different methods have been employed for the efficient evaluation of the Green’s function, which, if known analytically in the spectral domain (wavenumber), can be transformed into the spatial domain through the Fourier transformation. In the hypothesis of high frequency, the evaluation of this integral can be performed asymptotically, through dominant contribution of the integral (saddle point and poles residues contributions). The Green’s function expressed in terms of these contributions, even if approximated, is convenient in terms of calculation time [R7]. <br><br />
<br />
=== Numerical models ===<br />
In the case when the radiating element is embedded into multilayered dielectric structures, the Green’s function calculation even in the spectral domain is more complex, and the integral relevant to the Fourier transformation is typically solved numerically. Nevertheless, this integral shows some difficulties related to the presence of poles associated with surface and leaky waves, and to its oscillating behavior. In this context, more effort has been devoted to the choice of alternative integrations paths and integration techniques which can improve the efficiency of numerical codes [RT1]. To accelerate the Green’s function calculation even in the near zone where the asymptotic technique fail, the research activity has regarded the implementation of numerical codes based on approximations known in literature as complex images , which allow the representation of the Green’s function in terms of a few spherical sources, whose ray can be complex. Particular attention has been given to improve the convergence of these methods, with the scope to be inserted into a MoM code for the analysis of printed antennas, already developed in co-operation with Politecnico of Turin, and up to now based standard integration techniques [RT4][RT5]. The convergence has been improved by properly extracting dominant contributions of the Green’s function, related to the quasi-static term, and to the guided waves. This approach is particularly efficient in the near zone, where other techniques, as the asymptotic one, fail.<br />
<br />
<br />
<br><br><br><br><br />
<br />
== HIGH FREQUENCY METHODS FOR SCATTERING PREDICTION FROM PERFECTLY AND NON PERFECTLY CONDUCTING OBJECTS<br> ==<br />
<br />
This research activity concerns the development of new uniform diffraction coefficients and incremental techniques, suitable for prediction of scattering from perfectly and non perfectly conducting obstacles. This activity is of fundamental importance in the analysis of the field scattered or diffracted by large objects in terms of wavelength, such for the design and analysis of large antennas (e.g., reflectors), for the prediction of Radar Cross Section propagation in complex environments (e.g., urban propagation), for antenna installation and inter-antenna coupling (e.g., on ships, aircrafts, space platforms…).<br><br />
<br />
[[File: Large.png|800px]]<br><br />
Fig.5 Different scenarios for applications of high frquency methods<br />
<br />
<br />
===Generalization of Incremental Theory of Diffraction===<br />
Within this research activity, a general systematic procedure has been reached for defining incremental field contributions in the framework of scattering prediction from large conducting objects [R3]. The procedure is based on a generalization of the Incremental Theory of Diffraction (ITD) localization process for uniform cylindrical, local canonical problems with elementary source illumination and arbitrary observation aspects. In particular, it is shown that the spectral integral formulation of the exact solution for the local canonical problem may also be represented as a spatial integral convolution along the longitudinal coordinates of the cylindrical configuration. Its integrand is then directly used to define the relevant incremental field contribution. For the sake of convenience, but without loss of generality, this procedure is illustrated for the case of local wedge configurations. Also, a specific suitable asymptotic analysis is developed to derive new closed form high-frequency expressions from the spectral integral formulation. These expressions for the incremental field contributions explicitly satisfy reciprocity and are applicable at any incidence and observation aspect. This generalization of the ITD localization process together with its more accurate asymptotic analysis provides a definite improvement of the method. <br><br />
<br />
<br />
===Extension of Geometrical Theory of Diffraction for analysis of scattering from canonical planar structures===<br />
In the framework of high frequency techniques, the research activity has been addressed to the extension of methods for scattering prediction from planar structures such as wedge, also non perfectly conducting (dielectric, if necessary), with reference to the canonical problem associated with the half-plane and the junction of two parts plane [C24]. In the contest of the Uniform Theory of Diffraction (UTD), usually applied to the scattering of metallic or opaque surfaces, a heuristic formulation, simple but sufficiently accurate for most engineering applications, can be derived starting from the rigorous formulation of non penetrable screens, involving standard reflection and transmission coefficients, easily calculated for planar dielectric structures. These coefficients contain already known transition functions [C18][C21][C22]. Particular attention has been given to the inclusion of surface waves that can be guided by non perfectly conducting surfaces [C25][C27][C32]. The analysis, UTD-based, has been developed by calculating surface waves poles associated with the non perfectly conducting wedge faces (half-plane or two-parts junction), and from them appropriate diffraction coefficients are derived, heuristically extrapolated from the relevant canonical problems of surface impedance wedges. <br />
<br />
[[File: UTD.png|700px]]<br><br />
Fig.6 (left) High frequency localization principles; (right) Overall compensation mechanism in scattering from a dielectric half plane<br />
<br />
<br />
===Extension of Incremental Theory of Diffraction for analysis of scattering from planar canonical structures===<br />
The applicability of the Incremental Theory of Diffraction (ITD), tipically limited to the scattering from metallic surfaces, has been extended to non perfectly conducting surfaces (alse dielectric). The ITD is based on a suitable use of canonical problem solutions which locally approximate the structure geometry. A localization process allows to define incremental coefficients which, integrated along discontinuity lines or shadow lines, furnish the diffracted field[R3]. The main objective has been the derivation of a heuristic ITD formulation, simple but still accurate for most of engineering applications, starting from the rigorous formulation for metallic screens, with reference to the canonical problem associated with half-plane and two-parts junction [C13][C17][C18][C21][C30]. The so derived incremental diffraction coefficient is implicitly reciprocal and reduces to the ITD coefficient for conducting faces wedges (pec or pmc), in limiting cases. Through this formulation has been treated the scattering from faceted structures formed by composite materials, also in caustic zones, where the UTD ray-description becomes singular. In addiction, the ITD diffraction coefficient has also been written in terms of "fringe" contribution, in order to be inserted in already available PO codes. <br />
<br />
[[File: ITD.png|500px]]<br><br />
Fig.7 ITD application to circular dielectric structures<br />
<br />
===Extension of Incremental Theory of Diffraction to complex source illuminations===<br />
When representing arbitrarily shaped antenna radiation patterns, Gaussian Beams (GBs) turn out as very effective. GBs are solution of Maxwell equations only in the paraxial region but they are deeply concerned with the concept of the Complex Source Point (CSP), whose field is Maxwellian throughout the space (also outside the paraxial region), as can be easily inferred<br />
via an analytic continuation of the source point Green’s function when the source position is allowed to be complex. Such a GBs/CSPs representation can be used within a ray code to predict the interaction between antenna and the actual environment, if standard diffraction formulations are extended to the CSP case. The CSP extension of ray techniques like UTD appears to be substantially more problematic than that of incremental ray theories, such as ITD. Thus, this activity has been oriented to analyze this CSP extension of discrete and incremental ray techniques, with particular reference to the ITD formulation [R9][C11][C14].<br />
<br />
[[File: csp.png|700px]]<br><br />
Fig.8 ITD extension to Complex Source Points (CSP)<br />
<br />
<br><br><br><br><br />
<br />
<br />
== DESIGN OF ANTENNAS FOR MODERN WIRELESS APPLICATIONS<br> ==<br />
Recently, the activity has been oriented towards emerging radiating systems employed in different wireless applications(RFID, Bluetooth, ZigBee, body-centric networks, sensors networks, etc.). In this field, the activity concerns the analysis, design and prototyping of printed technology antennas, which are versatile, easy to be realized, and at low cost.<br><br />
<br />
[[File:wireless.png|900px]]<br><br />
Fig.9 Emerging wireless applications<br />
<br />
<br />
===Antennas for sensors networks===<br />
In sensors networks, antennas are mounted on-board and disseminated in different areas (environment, on human body, cars, etc.). They usually communicate with a main access point, which can be a personal computer, a PDA, or other. Antennas for these kinds of applications must be omnidirectional, in order to guarantee communication independently on their actual displacement with respect to the main access point. Unfortunately, their placement on objects of different nature degrades the performance, such as the efficiency and the input impedance. Especially this last must be taken under control in order to guarantee the right matching with the sensor itself. As a consequence, the antenna design must include the presence of possible objects thus resulting in customized design. A particular application has been developed in the framework of a Research Contract involving the company MicroDetectors spa (Modena, Italy) and the Institute of Applied Acoustic (CNR-IDAC, Rome, Italy). This work concerned the design of an antenna part of a radio sensor unit (for temperature applications) based on the employment of a surface acoustic wave (SAW) device. The matching between the SAW and the antenna on the Tag is a critical issue of the design, if no matching network are used in order to maintain the costs low. The antenna efficiency must be taken under control, and in particular its gain pattern, to guarantee omnidirectionality and to improve the radio activation distance. Possible shieldings have also been investigated to allow the sensor to be independent on its placement [C24].<br />
<br />
[[File:SAW.png|900px]]<br><br />
Fig.10 (left) Geometry of the proposed antenna; (middle) gain pattern; (right) experimental measure set-up<br><br />
<br />
===Antennas for RFID tags===<br />
Radio Frequency Identification (RFID) is a recent technology which found applications in many practical areas such as automatic identification and location of objects, people tracking, supply chain management, security access to controlled<br />
areas, etc. A typical component of an RFID system is a small tag or transponder, which is located on the objects to be identified. A passive tag is composed by a transponder chip (IC) and a matched antenna enabling it to either capturing<br />
electromagnetic energy from an interrogating field or communicating with an RFID reader or interrogator. Passive RFID at UHF band (866-869 MHz, European band) and Microwave (2.45 GHz) communicate using the modulated scattered technique, where the reflected signal from the tag is modulated by the IC connected directly to the antenna. To obtain the maximum power transfer to the chip, a tag antenna is typically designed to be conjugate matched to it. In order to reduce costs and size, matching networks or other lumped elements are avoided. Moreover, the microchip is usually presenting a highly capacitive input impedance, thus the antenna input impedance should be intrinsically inductive. As a consequences, the design of<br />
tag antennas, that can be effectively integrated with the IC transponders, is one of the major constraint. This activity mainly concerns the development of a planar dual band slot-type binocular tag antenna operating at the frequencies of 868MHz and 2.45GHz is presented. The particular geometry resulting from the design has suggested the name of binocular antenna. This shape allows to obtain a good conjugate match to the input impedance of a chip operating at both frequency bands. The proposed antenna is also mechanically robust against possible vibrations and provide a quasi isotropic radiation patterns [C22].<br />
<br />
[[File:bino.png|800px]]<br><br />
Fig.11 (left) Geometry of the proposed antenna; (right) current displacement at the two operating frequencies<br><br />
<br />
===Microwave radiometer===<br />
Within a National Research Program (PRIN), a low-cost integrated X-band microwave radiometer for ground-based applications has been designed. The microwave frequencies offer advantages over the well established InfraRed (IR) technology, because a microwave signal can penetrate all materials (except of metals) allowing detection also through thick smokes and vapours. On the other hand, the longer wavelength of the microwave radiation, compared to IR, reduces the spatial resolution. An usual way to improve the spatial resolution is to address higher frequencies (up to the extreme limit of imaging capabilities) to get a better antenna directivity even if at the cost of a more expensive electronics of the microwave front-end. This research activity has regarded the design and prototyping of the antenna, designed as an array of patches, where number of elements, spacing and feeding currents have been optimized to fulfil requirements of low side lobe level and good cross polarization. First the single radiator has been optimized, then the feeding network and the overall array displacement have been designed [R8][C17]. The antenna, printed on a standard single layer Taconic substrate, has been then prototyped and its performance, in terms of input impedance and radiation pattern, measured with a customized set-up [C23].<br />
<br />
[[File:radiometer.png|900px]]<br><br />
Fig.12 (left) Geometry of the array antenna and prototype; (middle) input impedance characterization; (right) radiation pattern characterization<br><br />
<br />
== REGULARIZATION OF 3D SINGULAR KERNEL IN INTEGRAL EQUATIONS<br> ==<br />
The problem addressed in this research activity with Politecnico di Torino regards the well known problems that the Green’s functions employed in integral equation methods, such as the Method-of-Moments (MoM), diverge when observation and source points coincide; this is at the origin of the difficulties in computing the MoM matrix entries, and in handling the near-field interactions in FFT-based fast methods and other sampling-based methods. We have shown [R10][C16][C18][C19] that this singularity can be avoided, and a modified regular Green’s function can be used instead. This latter is obtained from the spectral representation of the usual Green’s function via windowing of its spectrum; the width of the spectral window depends on the size of the mesh employed for discretizing the problem, so that the proposed regular Green’s function is a mesh-adapted regular kernel. Numerical results for 3D antenna and scattering problems discretized with Rao-Wilton-Glisson (RWG) functions, have been produced to show the effectiveness of the approach, both for uniform and non-uniform meshing. They show that the<br />
proposed method yields accurate solutions also for the antenna input impedance.<br />
<br />
<br />
[[File:spectral.png|900px]]<br><br />
Fig.13 (left) Basis and test functions lying in different planes, generically oriented; (right) amplitude of the Fourier Transform of an RWG function of the mesh for both radial and angular component <br><br />
<br />
<br />
== ONGOING ACTIVITIES<br> ==<br />
===Ridge gap Waveguides===<br />
This activity is on the attempt to elaborate an approximate analytical analysis of the quasi-TEM dominant mode in a parallel plate metamaterial-based waveguide. This waveguide is constituted by a bed of nails surface interrupted by a metal strip, and covered by a metallic plate. This structure is simple to manufacture, especially at millimetre and sub-millimetre wave frequencies [C25][R13].<br />
<br />
[[File:gap.png|400px]]<br><br />
Fig14 Ridge gap waveguide geometry<br />
<br />
===Hollow Core Fibre for THz Applications===<br />
Hollow Core Photonic Band Gap Fibres (HC-PBGFs) are investigated in order to obtain low loss wave guiding and good aperture field distribution in the terahertz region (0.1 − 10THz) of the electromagnetic spectrum. Waveguides and antennas design<br />
in this spectral region is a major challenge due to the high conductivity losses of metals and high absorption of dielectrics. Numerical results show the possibility to reach propagation loss two decades lower than the bulk absorption losses of the material used to fabricate the fibre, over a wide range of wavelength. The purity of the aperture field distribution at the<br />
HC-PBGF section suggests a possible employment of such a structure as aperture antenna, for possible feed systems in THz applications [C26][C28].<br />
<br />
[[File:fibre.png|400px]]<br><br />
Fig.15 Possible photonic band gap fibres cross sections, investigated at THz.<br />
<br />
===Groove Waveguides at Optical Frequencies===<br />
This activity is carried on within the collaboration of Prof. Engheta (University of Pennsylvania, Philadelphia) and Prof. Alù (University of Austin, Texas). It mainly concerns on the theoretical and numerical analysis of an open waveguide, made by a groove on metals, and employed at optical frequencies. At these frequencies, metals (such as silver or gold) can be characterized by an equivalent Drude model permittivity, and in the region of negative permittivity values, surface polaritons can be propagated along the surface. Under certain resonance conditions, at least one of these polaritons are well confined inside the groove, thus allowing the wave guiding effect even in an open environment.<br />
<br />
[[File:groove.png|400px]]<br><br />
Fig.16 Effect of field confinement into the open waveguide.<br />
<br />
<br><br><br><br><br />
<br />
=PUBLICATIONS<br>=<br />
[http://www.dii.unimo.it/wiki/index.php/My_publications Publications]<br />
<br />
<br />
<br><br><br><br />
[[Image:home.gif|30px|left]] <br><br />
[[User:Apolemi | Home]]</div>Apolemihttps://web.ing.unimo.it/wiki/index.php?title=Research_Activity&diff=7417Research Activity2010-06-23T01:50:27Z<p>Apolemi: /* TOPICS */</p>
<hr />
<div>= TOPICS <br> =<br />
My research activity begins at the Department of Information Engineering of the University of Siena, mainly oriented to the asymptotic study of the Green’s function associated with truncated periodic arrays of elementary sources embedded in multilayered environment. This activity has been pursed in collaboration with Prof. Felsen (University of Boston). Contemporarily, my scientific activity has also investigated analytical and numerical methods in electromagnetism, for the prediction of the electromagnetic scattering frm large objects, with Prof. Roberto Tiberio and Prof. Stefano Maci as supervisors. The research activity has also been developed in the framework of national research programs (PRIN), university research programs (PAR), and in the framework of projects financed by the Italian Space Agency (ASI). I also also participated to European research programs, as ACE and EAML. <br />
<br />
The experience on periodic structures and on Green's function for multilayered structures has allowed me to start a fruitful collaboration with Politecnico di Torino, to arrange new and efficient tools for the analysis of aperiodic and periodic printed elements embedded in dielectric materials. Also, my interests have been focused on lens antennas, for which I am involved in a European Research Networking Program (RNP) with University of Rennes, Radio Frequency IDentification systems, and on microwave radiometers for fire detection. <br />
<br />
I’m currently involved in a European working group (lead by Prof. Per-Simon Kildal from Chalmers Univeristy of Technology) focused on the investigation of new generations of waveguides, to be employed in the higher region of the microwave spectrum. In this working group, I developed analytical models to describe the dispersion characteristic of metallic waveguides based on periodic stop band surfaces.<br />
<br />
Recently, in the framework of a collaboration with Prof. Nader Engheta (University of Pennsylvania) and Prof. Andrea Alù (University of Texas at Austin), I started to work on metamaterials and plasmonic structure at optical frequencies, with particular interest towards plasmonic channels and nanocircuits. My interest concerns specifically the numerical and analytical description of the dispersion characteristic of plasmonic waveguides, together with the possibility to load them with nanoparticles, which act as nanoinductors and nanocapacitors. <br />
<br />
Also, within the collaboration with Prof. Kevin Shuford at the Drexel University, I recently started to work on the interaction between nanoparticles and molecules, providing both analytical and numerical support to the investigation the spectra of assembled nanoparticles, with particular interest to periodic SERS nanosurface. <br />
<br><br><br><br><br />
<br />
== ASYMPTOTIC METHODS FOR ARRAY ANTENNAS<br> ==<br />
The research activity in this area is focused on the development and application of asymptotic methods for analysis and design of array antennas embedded in multilayered dielectric environment. In particular, the research is mainly dedicated to the characterization of diffraction phenomena, generated by the periodicity truncation (semi-infinite array, sectoral array) through the array Green’s function (AGF), and through the subsequent integration of the representation into full-wave codes for the efficient analysis of printed antennas. <br><br />
<br />
<br />
===Array Green’s function (AGF): diffraction phenomena generated by edge truncation on dielectric slab===<br />
For a correct description of the diffraction generated by the array edge truncation, and interpreted in terms of rays according to the Geometrical Theory of Diffraction (GTD) generalized to periodic structures, the AGF must take into account not only for the presence of dielectrics, but also for the presence of periodicity. If the array is infinite, the Floquet theorem allows to express the AGF as superposition of a complete set of modes (Floquet modes), weighted by the spectral Green’s function of the single element in the periodicity. If the array is finite, this expansion cannot be directly applied. The aim of this research branch is that to formulate an AGF for an efficient treatment of truncated periodic array on dielectric slabs. The goal is reached referring to appropriate canonical problems. The first is that of introducing the truncation effects due to the edge (semi-infinite array), either for an array of line sources [R2], or for an array of point sources [R1][R4][C1]-[C5]. The integral describing the diffraction from the array edge can be evaluated applying asymptotic techniques. The knowledge of the asymptotic array Green’s function, not only is of advantage for the computational times, but it also allows to check separately the various field contributions (truncated Floquet modes, truncated surface and leaky waves), predicting the eventual interaction [R5][R6][C9][C11].<br />
<br />
[[File:AGF.png|900px]]<br><br />
Fig.1 Phenomenology associated with Semi-Infinite Array Green’s Function (AGF).(left) Semi-infinite elementary sources on multilayered environment (middle) Topology of the AGF (right) Schematic representation of the transition from a conical wave to a plane surface wave in 3D and 2D views<br />
<br />
=== Array Green’s function (AGF): diffraction phenomena generated by vertex truncation on dielectric slab ===<br />
In order to complete the extension o the Geometrical Theory of Diffraction (GTD) generalized to periodic structures it is necessary to develop an efficient asymptotic solution for the canonical problem associated with a sectoral array, where the truncation is present along both directions, including either spatial diffraction contribution or guided waves diffraction contribution. An hybrid technique based on an appropriate decomposition into canonical problems is developed to include diffraction terms, with particular care to the observation on the array surface, which is of basic importance when the continuity conditions of electric and magnetic fields must be applied [C14][C20][C23]. The method is based on an iterative process of subtraction, from the infinite array, of canonical problems constituted by semi-infinite and sectoral arrays. Each of these problems can be treated separately, applying convenient techniques, according to the observation region [C26][C28][C33].<br />
<br />
<br />
[[File:sector.png|800px]]<br><br />
Fig.2 Phenomenology associated with the Sectoral Array Green’s Function (AGF).(left) Sector of elementary sources on multilayered environment (middle) and (right) Schematic representation of the transition from edge and vertex diffracted waves. <br />
<br />
=== Introduction of the array Green’s function inside full-wave codes for the analysis of larege array antennas===<br />
The asymptotic Green’s function allows also to describe the field contributions due to the presence of double truncations. Thus, it could be efficiently employed to extend the applicability of full-wave methods also to very large array. This objective is reached solving the MoM through an appropriate regularized integral equation (“fringe” equation), where the unknown current is expanded on entire domain basis function, with behaviour imposed by dominant diffraction contributions [C6][C7][C10][C12][C16]. The main objective of this activity is concerned with an efficient evaluation of the Array Green’s Function (AGF) and its clever application into a MoM, while remaining in the application framework of arrays or periodic<br />
surfaces which exhibit weak variability with respect to periodicity of geometry and excitation. The high frequency method used here has the advantage to be additive with respect to the one associated with the infinite structure, with additional (edge)<br />
contribution which is not invariant by phase shifted translation, thus allowing the reuse of already existing numerical codes [C20]. The strategy adopted is briefly the following. All the elements of the array are discretized with triangular cells, where the Rao-Wilton-Glisson (RWG) basis functions are defined; in the AGF-MoM approach, the MoM problem is set-up and solved for each element in isolation, instead to implement the global array MoM reactions with a reduction of complexity and memory occupation. Thus, the key advantage in using the AGF in the MoM is in the possibility of evaluating and solving only the MoM<br />
matrix of each element against itself, instead of the MoM matrix of the whole array. The integration of the AGF with the MoM is organized in two steps and repeated for all the array elements.<br />
<br />
[[File:MOM.png|500px]]<br><br />
Fig.3 MoM Strategy for finite size arrays <br />
<br />
<br><br><br><br><br />
<br />
== GREEN'S FUNCTION CHARACTERIZATION FOR STRATIFIED DIELECTRICS<br> ==<br />
<br />
The activity is essentially devoted to the modeling of printed antenna.<br><br />
<br />
=== Characterization of guided phenomena===<br />
The presence of dielectric substrates influences the real radiating antenna performance and complicates the electromagnetic analysis. In fact, the structure supports guided waves propagation, in particular surface waves or leaky waves. On one hand, these kinds of guided waves can degrade the radiating antenna performance, on the other hand they can be employed to improve directivity/gain. Indeed, composite planar dielectric structures used for increasing the directivity of a point<br />
source, have been investigated since many years. This substrate/superstrate structure was demonstrated to establish a resonance condition, which maximizes antenna gain, radiation resistance, and radiation efficiency. Particular attention has been given to the physical interpretation of this resonance gain effect, which can be described in terms<br />
of leaky waves (LW) excited in the structure. Under certain resonance conditions, a pair of weakly attenuated TE/TM leaky waves become the dominant contributions to the antenna aperture field. Although the demonstrated interest in such<br />
type of configurations, the polarization characteristics of the structure wasn't investigated enough. The aim of this research activity has been to rigorously demonstrate that the conventional choice of the stratification, not only ensures a large aperture field, but the same field is also well polarized when excited by any linearly polarized point source [R7] [C29].<br><br />
<br />
[[File:Lens.png|800px]]<br><br />
Fig.4 (left) Topological investigation of coalescence of leaky waves (resonance condition) in a substrate/superstrate structure; (middle) and (left) purity of polarization of the copolar component of a linear polarized source embedded in such a substrate/superstrate structure.<br />
<br />
<br />
=== Asymptotic models===<br />
To characterize the dielectric structures, different methods have been employed for the efficient evaluation of the Green’s function, which, if known analytically in the spectral domain (wavenumber), can be transformed into the spatial domain through the Fourier transformation. In the hypothesis of high frequency, the evaluation of this integral can be performed asymptotically, through dominant contribution of the integral (saddle point and poles residues contributions). The Green’s function expressed in terms of these contributions, even if approximated, is convenient in terms of calculation time [R7]. <br><br />
<br />
=== Numerical models ===<br />
In the case when the radiating element is embedded into multilayered dielectric structures, the Green’s function calculation even in the spectral domain is more complex, and the integral relevant to the Fourier transformation is typically solved numerically. Nevertheless, this integral shows some difficulties related to the presence of poles associated with surface and leaky waves, and to its oscillating behavior. In this context, more effort has been devoted to the choice of alternative integrations paths and integration techniques which can improve the efficiency of numerical codes [RT1]. To accelerate the Green’s function calculation even in the near zone where the asymptotic technique fail, the research activity has regarded the implementation of numerical codes based on approximations known in literature as complex images , which allow the representation of the Green’s function in terms of a few spherical sources, whose ray can be complex. Particular attention has been given to improve the convergence of these methods, with the scope to be inserted into a MoM code for the analysis of printed antennas, already developed in co-operation with Politecnico of Turin, and up to now based standard integration techniques [RT4][RT5]. The convergence has been improved by properly extracting dominant contributions of the Green’s function, related to the quasi-static term, and to the guided waves. This approach is particularly efficient in the near zone, where other techniques, as the asymptotic one, fail.<br />
<br />
<br />
<br><br><br><br><br />
<br />
== HIGH FREQUENCY METHODS FOR SCATTERING PREDICTION FROM PERFECTLY AND NON PERFECTLY CONDUCTING OBJECTS<br> ==<br />
<br />
This research activity concerns the development of new uniform diffraction coefficients and incremental techniques, suitable for prediction of scattering from perfectly and non perfectly conducting obstacles. This activity is of fundamental importance in the analysis of the field scattered or diffracted by large objects in terms of wavelength, such for the design and analysis of large antennas (e.g., reflectors), for the prediction of Radar Cross Section propagation in complex environments (e.g., urban propagation), for antenna installation and inter-antenna coupling (e.g., on ships, aircrafts, space platforms…).<br><br />
<br />
[[File: Large.png|800px]]<br><br />
Fig.5 Different scenarios for applications of high frquency methods<br />
<br />
<br />
===Generalization of Incremental Theory of Diffraction===<br />
Within this research activity, a general systematic procedure has been reached for defining incremental field contributions in the framework of scattering prediction from large conducting objects [R3]. The procedure is based on a generalization of the Incremental Theory of Diffraction (ITD) localization process for uniform cylindrical, local canonical problems with elementary source illumination and arbitrary observation aspects. In particular, it is shown that the spectral integral formulation of the exact solution for the local canonical problem may also be represented as a spatial integral convolution along the longitudinal coordinates of the cylindrical configuration. Its integrand is then directly used to define the relevant incremental field contribution. For the sake of convenience, but without loss of generality, this procedure is illustrated for the case of local wedge configurations. Also, a specific suitable asymptotic analysis is developed to derive new closed form high-frequency expressions from the spectral integral formulation. These expressions for the incremental field contributions explicitly satisfy reciprocity and are applicable at any incidence and observation aspect. This generalization of the ITD localization process together with its more accurate asymptotic analysis provides a definite improvement of the method. <br><br />
<br />
<br />
===Extension of Geometrical Theory of Diffraction for analysis of scattering from canonical planar structures===<br />
In the framework of high frequency techniques, the research activity has been addressed to the extension of methods for scattering prediction from planar structures such as wedge, also non perfectly conducting (dielectric, if necessary), with reference to the canonical problem associated with the half-plane and the junction of two parts plane [C24]. In the contest of the Uniform Theory of Diffraction (UTD), usually applied to the scattering of metallic or opaque surfaces, a heuristic formulation, simple but sufficiently accurate for most engineering applications, can be derived starting from the rigorous formulation of non penetrable screens, involving standard reflection and transmission coefficients, easily calculated for planar dielectric structures. These coefficients contain already known transition functions [C18][C21][C22]. Particular attention has been given to the inclusion of surface waves that can be guided by non perfectly conducting surfaces [C25][C27][C32]. The analysis, UTD-based, has been developed by calculating surface waves poles associated with the non perfectly conducting wedge faces (half-plane or two-parts junction), and from them appropriate diffraction coefficients are derived, heuristically extrapolated from the relevant canonical problems of surface impedance wedges. <br />
<br />
[[File: UTD.png|700px]]<br><br />
Fig.6 (left) High frequency localization principles; (right) Overall compensation mechanism in scattering from a dielectric half plane<br />
<br />
<br />
===Extension of Incremental Theory of Diffraction for analysis of scattering from planar canonical structures===<br />
The applicability of the Incremental Theory of Diffraction (ITD), tipically limited to the scattering from metallic surfaces, has been extended to non perfectly conducting surfaces (alse dielectric). The ITD is based on a suitable use of canonical problem solutions which locally approximate the structure geometry. A localization process allows to define incremental coefficients which, integrated along discontinuity lines or shadow lines, furnish the diffracted field[R3]. The main objective has been the derivation of a heuristic ITD formulation, simple but still accurate for most of engineering applications, starting from the rigorous formulation for metallic screens, with reference to the canonical problem associated with half-plane and two-parts junction [C13][C17][C18][C21][C30]. The so derived incremental diffraction coefficient is implicitly reciprocal and reduces to the ITD coefficient for conducting faces wedges (pec or pmc), in limiting cases. Through this formulation has been treated the scattering from faceted structures formed by composite materials, also in caustic zones, where the UTD ray-description becomes singular. In addiction, the ITD diffraction coefficient has also been written in terms of "fringe" contribution, in order to be inserted in already available PO codes. <br />
<br />
[[File: ITD.png|500px]]<br><br />
Fig.7 ITD application to circular dielectric structures<br />
<br />
===Extension of Incremental Theory of Diffraction to complex source illuminations===<br />
When representing arbitrarily shaped antenna radiation patterns, Gaussian Beams (GBs) turn out as very effective. GBs are solution of Maxwell equations only in the paraxial region but they are deeply concerned with the concept of the Complex Source Point (CSP), whose field is Maxwellian throughout the space (also outside the paraxial region), as can be easily inferred<br />
via an analytic continuation of the source point Green’s function when the source position is allowed to be complex. Such a GBs/CSPs representation can be used within a ray code to predict the interaction between antenna and the actual environment, if standard diffraction formulations are extended to the CSP case. The CSP extension of ray techniques like UTD appears to be substantially more problematic than that of incremental ray theories, such as ITD. Thus, this activity has been oriented to analyze this CSP extension of discrete and incremental ray techniques, with particular reference to the ITD formulation [R9][C11][C14].<br />
<br />
[[File: csp.png|700px]]<br><br />
Fig.8 ITD extension to Complex Source Points (CSP)<br />
<br />
<br><br><br><br><br />
<br />
<br />
== DESIGN OF ANTENNAS FOR MODERN WIRELESS APPLICATIONS<br> ==<br />
Recently, the activity has been oriented towards emerging radiating systems employed in different wireless applications(RFID, Bluetooth, ZigBee, body-centric networks, sensors networks, etc.). In this field, the activity concerns the analysis, design and prototyping of printed technology antennas, which are versatile, easy to be realized, and at low cost.<br><br />
<br />
[[File:wireless.png|900px]]<br><br />
Fig.9 Emerging wireless applications<br />
<br />
<br />
===Antennas for sensors networks===<br />
In sensors networks, antennas are mounted on-board and disseminated in different areas (environment, on human body, cars, etc.). They usually communicate with a main access point, which can be a personal computer, a PDA, or other. Antennas for these kinds of applications must be omnidirectional, in order to guarantee communication independently on their actual displacement with respect to the main access point. Unfortunately, their placement on objects of different nature degrades the performance, such as the efficiency and the input impedance. Especially this last must be taken under control in order to guarantee the right matching with the sensor itself. As a consequence, the antenna design must include the presence of possible objects thus resulting in customized design. A particular application has been developed in the framework of a Research Contract involving the company MicroDetectors spa (Modena, Italy) and the Institute of Applied Acoustic (CNR-IDAC, Rome, Italy). This work concerned the design of an antenna part of a radio sensor unit (for temperature applications) based on the employment of a surface acoustic wave (SAW) device. The matching between the SAW and the antenna on the Tag is a critical issue of the design, if no matching network are used in order to maintain the costs low. The antenna efficiency must be taken under control, and in particular its gain pattern, to guarantee omnidirectionality and to improve the radio activation distance. Possible shieldings have also been investigated to allow the sensor to be independent on its placement [C24].<br />
<br />
[[File:SAW.png|900px]]<br><br />
Fig.10 (left) Geometry of the proposed antenna; (middle) gain pattern; (right) experimental measure set-up<br><br />
<br />
===Antennas for RFID tags===<br />
Radio Frequency Identification (RFID) is a recent technology which found applications in many practical areas such as automatic identification and location of objects, people tracking, supply chain management, security access to controlled<br />
areas, etc. A typical component of an RFID system is a small tag or transponder, which is located on the objects to be identified. A passive tag is composed by a transponder chip (IC) and a matched antenna enabling it to either capturing<br />
electromagnetic energy from an interrogating field or communicating with an RFID reader or interrogator. Passive RFID at UHF band (866-869 MHz, European band) and Microwave (2.45 GHz) communicate using the modulated scattered technique, where the reflected signal from the tag is modulated by the IC connected directly to the antenna. To obtain the maximum power transfer to the chip, a tag antenna is typically designed to be conjugate matched to it. In order to reduce costs and size, matching networks or other lumped elements are avoided. Moreover, the microchip is usually presenting a highly capacitive input impedance, thus the antenna input impedance should be intrinsically inductive. As a consequences, the design of<br />
tag antennas, that can be effectively integrated with the IC transponders, is one of the major constraint. This activity mainly concerns the development of a planar dual band slot-type binocular tag antenna operating at the frequencies of 868MHz and 2.45GHz is presented. The particular geometry resulting from the design has suggested the name of binocular antenna. This shape allows to obtain a good conjugate match to the input impedance of a chip operating at both frequency bands. The proposed antenna is also mechanically robust against possible vibrations and provide a quasi isotropic radiation patterns [C22].<br />
<br />
[[File:bino.png|800px]]<br><br />
Fig.11 (left) Geometry of the proposed antenna; (right) current displacement at the two operating frequencies<br><br />
<br />
===Microwave radiometer===<br />
Within a National Research Program (PRIN), a low-cost integrated X-band microwave radiometer for ground-based applications has been designed. The microwave frequencies offer advantages over the well established InfraRed (IR) technology, because a microwave signal can penetrate all materials (except of metals) allowing detection also through thick smokes and vapours. On the other hand, the longer wavelength of the microwave radiation, compared to IR, reduces the spatial resolution. An usual way to improve the spatial resolution is to address higher frequencies (up to the extreme limit of imaging capabilities) to get a better antenna directivity even if at the cost of a more expensive electronics of the microwave front-end. This research activity has regarded the design and prototyping of the antenna, designed as an array of patches, where number of elements, spacing and feeding currents have been optimized to fulfil requirements of low side lobe level and good cross polarization. First the single radiator has been optimized, then the feeding network and the overall array displacement have been designed [R8][C17]. The antenna, printed on a standard single layer Taconic substrate, has been then prototyped and its performance, in terms of input impedance and radiation pattern, measured with a customized set-up [C23].<br />
<br />
[[File:radiometer.png|900px]]<br><br />
Fig.12 (left) Geometry of the array antenna and prototype; (middle) input impedance characterization; (right) radiation pattern characterization<br><br />
<br />
== REGULARIZATION OF 3D SINGULAR KERNEL IN INTEGRAL EQUATIONS<br> ==<br />
The problem addressed in this research activity with Politecnico di Torino regards the well known problems that the Green’s functions employed in integral equation methods, such as the Method-of-Moments (MoM), diverge when observation and source points coincide; this is at the origin of the difficulties in computing the MoM matrix entries, and in handling the near-field interactions in FFT-based fast methods and other sampling-based methods. We have shown [R10][C16][C18][C19] that this singularity can be avoided, and a modified regular Green’s function can be used instead. This latter is obtained from the spectral representation of the usual Green’s function via windowing of its spectrum; the width of the spectral window depends on the size of the mesh employed for discretizing the problem, so that the proposed regular Green’s function is a mesh-adapted regular kernel. Numerical results for 3D antenna and scattering problems discretized with Rao-Wilton-Glisson (RWG) functions, have been produced to show the effectiveness of the approach, both for uniform and non-uniform meshing. They show that the<br />
proposed method yields accurate solutions also for the antenna input impedance.<br />
<br />
<br />
[[File:spectral.png|900px]]<br><br />
Fig.13 (left) Basis and test functions lying in different planes, generically oriented; (right) amplitude of the Fourier Transform of an RWG function of the mesh for both radial and angular component <br><br />
<br />
<br />
== ONGOING ACTIVITIES<br> ==<br />
===Ridge gap Waveguides===<br />
This activity is on the attempt to elaborate an approximate analytical analysis of the quasi-TEM dominant mode in a parallel plate metamaterial-based waveguide. This waveguide is constituted by a bed of nails surface interrupted by a metal strip, and covered by a metallic plate. This structure is simple to manufacture, especially at millimetre and sub-millimetre wave frequencies [C25][R13].<br />
<br />
[[File:gap.png|400px]]<br><br />
Fig14 Ridge gap waveguide geometry<br />
<br />
===Hollow Core Fibre for THz Applications===<br />
Hollow Core Photonic Band Gap Fibres (HC-PBGFs) are investigated in order to obtain low loss wave guiding and good aperture field distribution in the terahertz region (0.1 − 10THz) of the electromagnetic spectrum. Waveguides and antennas design<br />
in this spectral region is a major challenge due to the high conductivity losses of metals and high absorption of dielectrics. Numerical results show the possibility to reach propagation loss two decades lower than the bulk absorption losses of the material used to fabricate the fibre, over a wide range of wavelength. The purity of the aperture field distribution at the<br />
HC-PBGF section suggests a possible employment of such a structure as aperture antenna, for possible feed systems in THz applications [C26][C28].<br />
<br />
[[File:fibre.png|400px]]<br><br />
Fig.15 Possible photonic band gap fibres cross sections, investigated at THz.<br />
<br />
===Groove Waveguides at Optical Frequencies===<br />
This activity is carried on within the collaboration of Prof. Engheta (University of Pennsylvania, Philadelphia) and Prof. Alù (University of Austin, Texas). It mainly concerns on the theoretical and numerical analysis of an open waveguide, made by a groove on metals, and employed at optical frequencies. At these frequencies, metals (such as silver or gold) can be characterized by an equivalent Drude model permittivity, and in the region of negative permittivity values, surface polaritons can be propagated along the surface. Under certain resonance conditions, at least one of these polaritons are well confined inside the groove, thus allowing the wave guiding effect even in an open environment.<br />
<br />
[[File:groove.png|400px]]<br><br />
Fig.16 Effect of field confinement into the open waveguide.<br />
<br />
<br><br><br><br><br />
<br />
=PUBLICATIONS<br>=<br />
[http://www.dii.unimo.it/wiki/index.php/My_publications Publications]<br />
<br />
<br />
<br><br><br><br />
[[Image:home.gif|30px|left]] <br><br />
[[User:Apolemi | Home]]</div>Apolemihttps://web.ing.unimo.it/wiki/index.php?title=Research_Activity&diff=7416Research Activity2010-06-23T01:46:58Z<p>Apolemi: /* ASYMPTOTIC METHODS FOR ARRAY ANTENNAS */</p>
<hr />
<div>= TOPICS <br> =<br />
<br />
The Alessia Polemi research activity begins at the Department of Information Engineering of the University of Siena, in the period of preparation of the master thesis degree, oriented to the asymptotic study of the Green’s function associated with truncated periodic arrays of elementary sources embedded in multilayered environment. This activity continued after the master thesis degree in cooperation with Prof. Felsen from the University of Boston, and it produced the publication of a sequence of three papers on this subject. Contemporarily, the scientific activity of Alessia Polemi also investigated the field of electromagnetic analytical and numerical methods, particularly referring to the high frequency techniques for the prediction of the electromagnetic scattering, with Prof. Roberto Tiberio and Prof. Stefano Maci as supervisors. The research activity has also been developed in the framework of national research programs (PRIN), university research programs (PAR), and in the framework of projects financed by the Italian Space Agency (ASI). She also participates to European research programs, as ACE and EAML. The experience on periodic structures and on Green's function for multilayered structures allowed her to start a fruitful collaboration with Politecnico di Torino, to assest new and efficient tools for the analysis of aperiodic and periodic printed elements embedded in dielectric materials. The collaboration with Politecnico di Torino has been also addressed to the problem of kernel regularization in 3D singular integral equations. Recently, her research activity is focusing on lens antenna, for which she is involved in a European Research Networking Program (RNP) with University of Rennes, on RFID antenna design, on microwave radiometers, and on metamaterials and plasmonic structure at optical frequencies, on which she is undertaking an international collaboration with Prof. Nader Engheta (University of Pennsylvania) and Prof. Andrea Alù (University of Austin, Texas).<br />
<br><br><br><br><br />
<br />
== ASYMPTOTIC METHODS FOR ARRAY ANTENNAS<br> ==<br />
The research activity in this area is focused on the development and application of asymptotic methods for analysis and design of array antennas embedded in multilayered dielectric environment. In particular, the research is mainly dedicated to the characterization of diffraction phenomena, generated by the periodicity truncation (semi-infinite array, sectoral array) through the array Green’s function (AGF), and through the subsequent integration of the representation into full-wave codes for the efficient analysis of printed antennas. <br><br />
<br />
<br />
===Array Green’s function (AGF): diffraction phenomena generated by edge truncation on dielectric slab===<br />
For a correct description of the diffraction generated by the array edge truncation, and interpreted in terms of rays according to the Geometrical Theory of Diffraction (GTD) generalized to periodic structures, the AGF must take into account not only for the presence of dielectrics, but also for the presence of periodicity. If the array is infinite, the Floquet theorem allows to express the AGF as superposition of a complete set of modes (Floquet modes), weighted by the spectral Green’s function of the single element in the periodicity. If the array is finite, this expansion cannot be directly applied. The aim of this research branch is that to formulate an AGF for an efficient treatment of truncated periodic array on dielectric slabs. The goal is reached referring to appropriate canonical problems. The first is that of introducing the truncation effects due to the edge (semi-infinite array), either for an array of line sources [R2], or for an array of point sources [R1][R4][C1]-[C5]. The integral describing the diffraction from the array edge can be evaluated applying asymptotic techniques. The knowledge of the asymptotic array Green’s function, not only is of advantage for the computational times, but it also allows to check separately the various field contributions (truncated Floquet modes, truncated surface and leaky waves), predicting the eventual interaction [R5][R6][C9][C11].<br />
<br />
[[File:AGF.png|900px]]<br><br />
Fig.1 Phenomenology associated with Semi-Infinite Array Green’s Function (AGF).(left) Semi-infinite elementary sources on multilayered environment (middle) Topology of the AGF (right) Schematic representation of the transition from a conical wave to a plane surface wave in 3D and 2D views<br />
<br />
=== Array Green’s function (AGF): diffraction phenomena generated by vertex truncation on dielectric slab ===<br />
In order to complete the extension o the Geometrical Theory of Diffraction (GTD) generalized to periodic structures it is necessary to develop an efficient asymptotic solution for the canonical problem associated with a sectoral array, where the truncation is present along both directions, including either spatial diffraction contribution or guided waves diffraction contribution. An hybrid technique based on an appropriate decomposition into canonical problems is developed to include diffraction terms, with particular care to the observation on the array surface, which is of basic importance when the continuity conditions of electric and magnetic fields must be applied [C14][C20][C23]. The method is based on an iterative process of subtraction, from the infinite array, of canonical problems constituted by semi-infinite and sectoral arrays. Each of these problems can be treated separately, applying convenient techniques, according to the observation region [C26][C28][C33].<br />
<br />
<br />
[[File:sector.png|800px]]<br><br />
Fig.2 Phenomenology associated with the Sectoral Array Green’s Function (AGF).(left) Sector of elementary sources on multilayered environment (middle) and (right) Schematic representation of the transition from edge and vertex diffracted waves. <br />
<br />
=== Introduction of the array Green’s function inside full-wave codes for the analysis of larege array antennas===<br />
The asymptotic Green’s function allows also to describe the field contributions due to the presence of double truncations. Thus, it could be efficiently employed to extend the applicability of full-wave methods also to very large array. This objective is reached solving the MoM through an appropriate regularized integral equation (“fringe” equation), where the unknown current is expanded on entire domain basis function, with behaviour imposed by dominant diffraction contributions [C6][C7][C10][C12][C16]. The main objective of this activity is concerned with an efficient evaluation of the Array Green’s Function (AGF) and its clever application into a MoM, while remaining in the application framework of arrays or periodic<br />
surfaces which exhibit weak variability with respect to periodicity of geometry and excitation. The high frequency method used here has the advantage to be additive with respect to the one associated with the infinite structure, with additional (edge)<br />
contribution which is not invariant by phase shifted translation, thus allowing the reuse of already existing numerical codes [C20]. The strategy adopted is briefly the following. All the elements of the array are discretized with triangular cells, where the Rao-Wilton-Glisson (RWG) basis functions are defined; in the AGF-MoM approach, the MoM problem is set-up and solved for each element in isolation, instead to implement the global array MoM reactions with a reduction of complexity and memory occupation. Thus, the key advantage in using the AGF in the MoM is in the possibility of evaluating and solving only the MoM<br />
matrix of each element against itself, instead of the MoM matrix of the whole array. The integration of the AGF with the MoM is organized in two steps and repeated for all the array elements.<br />
<br />
[[File:MOM.png|500px]]<br><br />
Fig.3 MoM Strategy for finite size arrays <br />
<br />
<br><br><br><br><br />
<br />
== GREEN'S FUNCTION CHARACTERIZATION FOR STRATIFIED DIELECTRICS<br> ==<br />
<br />
The activity is essentially devoted to the modeling of printed antenna.<br><br />
<br />
=== Characterization of guided phenomena===<br />
The presence of dielectric substrates influences the real radiating antenna performance and complicates the electromagnetic analysis. In fact, the structure supports guided waves propagation, in particular surface waves or leaky waves. On one hand, these kinds of guided waves can degrade the radiating antenna performance, on the other hand they can be employed to improve directivity/gain. Indeed, composite planar dielectric structures used for increasing the directivity of a point<br />
source, have been investigated since many years. This substrate/superstrate structure was demonstrated to establish a resonance condition, which maximizes antenna gain, radiation resistance, and radiation efficiency. Particular attention has been given to the physical interpretation of this resonance gain effect, which can be described in terms<br />
of leaky waves (LW) excited in the structure. Under certain resonance conditions, a pair of weakly attenuated TE/TM leaky waves become the dominant contributions to the antenna aperture field. Although the demonstrated interest in such<br />
type of configurations, the polarization characteristics of the structure wasn't investigated enough. The aim of this research activity has been to rigorously demonstrate that the conventional choice of the stratification, not only ensures a large aperture field, but the same field is also well polarized when excited by any linearly polarized point source [R7] [C29].<br><br />
<br />
[[File:Lens.png|800px]]<br><br />
Fig.4 (left) Topological investigation of coalescence of leaky waves (resonance condition) in a substrate/superstrate structure; (middle) and (left) purity of polarization of the copolar component of a linear polarized source embedded in such a substrate/superstrate structure.<br />
<br />
<br />
=== Asymptotic models===<br />
To characterize the dielectric structures, different methods have been employed for the efficient evaluation of the Green’s function, which, if known analytically in the spectral domain (wavenumber), can be transformed into the spatial domain through the Fourier transformation. In the hypothesis of high frequency, the evaluation of this integral can be performed asymptotically, through dominant contribution of the integral (saddle point and poles residues contributions). The Green’s function expressed in terms of these contributions, even if approximated, is convenient in terms of calculation time [R7]. <br><br />
<br />
=== Numerical models ===<br />
In the case when the radiating element is embedded into multilayered dielectric structures, the Green’s function calculation even in the spectral domain is more complex, and the integral relevant to the Fourier transformation is typically solved numerically. Nevertheless, this integral shows some difficulties related to the presence of poles associated with surface and leaky waves, and to its oscillating behavior. In this context, more effort has been devoted to the choice of alternative integrations paths and integration techniques which can improve the efficiency of numerical codes [RT1]. To accelerate the Green’s function calculation even in the near zone where the asymptotic technique fail, the research activity has regarded the implementation of numerical codes based on approximations known in literature as complex images , which allow the representation of the Green’s function in terms of a few spherical sources, whose ray can be complex. Particular attention has been given to improve the convergence of these methods, with the scope to be inserted into a MoM code for the analysis of printed antennas, already developed in co-operation with Politecnico of Turin, and up to now based standard integration techniques [RT4][RT5]. The convergence has been improved by properly extracting dominant contributions of the Green’s function, related to the quasi-static term, and to the guided waves. This approach is particularly efficient in the near zone, where other techniques, as the asymptotic one, fail.<br />
<br />
<br />
<br><br><br><br><br />
<br />
== HIGH FREQUENCY METHODS FOR SCATTERING PREDICTION FROM PERFECTLY AND NON PERFECTLY CONDUCTING OBJECTS<br> ==<br />
<br />
This research activity concerns the development of new uniform diffraction coefficients and incremental techniques, suitable for prediction of scattering from perfectly and non perfectly conducting obstacles. This activity is of fundamental importance in the analysis of the field scattered or diffracted by large objects in terms of wavelength, such for the design and analysis of large antennas (e.g., reflectors), for the prediction of Radar Cross Section propagation in complex environments (e.g., urban propagation), for antenna installation and inter-antenna coupling (e.g., on ships, aircrafts, space platforms…).<br><br />
<br />
[[File: Large.png|800px]]<br><br />
Fig.5 Different scenarios for applications of high frquency methods<br />
<br />
<br />
===Generalization of Incremental Theory of Diffraction===<br />
Within this research activity, a general systematic procedure has been reached for defining incremental field contributions in the framework of scattering prediction from large conducting objects [R3]. The procedure is based on a generalization of the Incremental Theory of Diffraction (ITD) localization process for uniform cylindrical, local canonical problems with elementary source illumination and arbitrary observation aspects. In particular, it is shown that the spectral integral formulation of the exact solution for the local canonical problem may also be represented as a spatial integral convolution along the longitudinal coordinates of the cylindrical configuration. Its integrand is then directly used to define the relevant incremental field contribution. For the sake of convenience, but without loss of generality, this procedure is illustrated for the case of local wedge configurations. Also, a specific suitable asymptotic analysis is developed to derive new closed form high-frequency expressions from the spectral integral formulation. These expressions for the incremental field contributions explicitly satisfy reciprocity and are applicable at any incidence and observation aspect. This generalization of the ITD localization process together with its more accurate asymptotic analysis provides a definite improvement of the method. <br><br />
<br />
<br />
===Extension of Geometrical Theory of Diffraction for analysis of scattering from canonical planar structures===<br />
In the framework of high frequency techniques, the research activity has been addressed to the extension of methods for scattering prediction from planar structures such as wedge, also non perfectly conducting (dielectric, if necessary), with reference to the canonical problem associated with the half-plane and the junction of two parts plane [C24]. In the contest of the Uniform Theory of Diffraction (UTD), usually applied to the scattering of metallic or opaque surfaces, a heuristic formulation, simple but sufficiently accurate for most engineering applications, can be derived starting from the rigorous formulation of non penetrable screens, involving standard reflection and transmission coefficients, easily calculated for planar dielectric structures. These coefficients contain already known transition functions [C18][C21][C22]. Particular attention has been given to the inclusion of surface waves that can be guided by non perfectly conducting surfaces [C25][C27][C32]. The analysis, UTD-based, has been developed by calculating surface waves poles associated with the non perfectly conducting wedge faces (half-plane or two-parts junction), and from them appropriate diffraction coefficients are derived, heuristically extrapolated from the relevant canonical problems of surface impedance wedges. <br />
<br />
[[File: UTD.png|700px]]<br><br />
Fig.6 (left) High frequency localization principles; (right) Overall compensation mechanism in scattering from a dielectric half plane<br />
<br />
<br />
===Extension of Incremental Theory of Diffraction for analysis of scattering from planar canonical structures===<br />
The applicability of the Incremental Theory of Diffraction (ITD), tipically limited to the scattering from metallic surfaces, has been extended to non perfectly conducting surfaces (alse dielectric). The ITD is based on a suitable use of canonical problem solutions which locally approximate the structure geometry. A localization process allows to define incremental coefficients which, integrated along discontinuity lines or shadow lines, furnish the diffracted field[R3]. The main objective has been the derivation of a heuristic ITD formulation, simple but still accurate for most of engineering applications, starting from the rigorous formulation for metallic screens, with reference to the canonical problem associated with half-plane and two-parts junction [C13][C17][C18][C21][C30]. The so derived incremental diffraction coefficient is implicitly reciprocal and reduces to the ITD coefficient for conducting faces wedges (pec or pmc), in limiting cases. Through this formulation has been treated the scattering from faceted structures formed by composite materials, also in caustic zones, where the UTD ray-description becomes singular. In addiction, the ITD diffraction coefficient has also been written in terms of "fringe" contribution, in order to be inserted in already available PO codes. <br />
<br />
[[File: ITD.png|500px]]<br><br />
Fig.7 ITD application to circular dielectric structures<br />
<br />
===Extension of Incremental Theory of Diffraction to complex source illuminations===<br />
When representing arbitrarily shaped antenna radiation patterns, Gaussian Beams (GBs) turn out as very effective. GBs are solution of Maxwell equations only in the paraxial region but they are deeply concerned with the concept of the Complex Source Point (CSP), whose field is Maxwellian throughout the space (also outside the paraxial region), as can be easily inferred<br />
via an analytic continuation of the source point Green’s function when the source position is allowed to be complex. Such a GBs/CSPs representation can be used within a ray code to predict the interaction between antenna and the actual environment, if standard diffraction formulations are extended to the CSP case. The CSP extension of ray techniques like UTD appears to be substantially more problematic than that of incremental ray theories, such as ITD. Thus, this activity has been oriented to analyze this CSP extension of discrete and incremental ray techniques, with particular reference to the ITD formulation [R9][C11][C14].<br />
<br />
[[File: csp.png|700px]]<br><br />
Fig.8 ITD extension to Complex Source Points (CSP)<br />
<br />
<br><br><br><br><br />
<br />
<br />
== DESIGN OF ANTENNAS FOR MODERN WIRELESS APPLICATIONS<br> ==<br />
Recently, the activity has been oriented towards emerging radiating systems employed in different wireless applications(RFID, Bluetooth, ZigBee, body-centric networks, sensors networks, etc.). In this field, the activity concerns the analysis, design and prototyping of printed technology antennas, which are versatile, easy to be realized, and at low cost.<br><br />
<br />
[[File:wireless.png|900px]]<br><br />
Fig.9 Emerging wireless applications<br />
<br />
<br />
===Antennas for sensors networks===<br />
In sensors networks, antennas are mounted on-board and disseminated in different areas (environment, on human body, cars, etc.). They usually communicate with a main access point, which can be a personal computer, a PDA, or other. Antennas for these kinds of applications must be omnidirectional, in order to guarantee communication independently on their actual displacement with respect to the main access point. Unfortunately, their placement on objects of different nature degrades the performance, such as the efficiency and the input impedance. Especially this last must be taken under control in order to guarantee the right matching with the sensor itself. As a consequence, the antenna design must include the presence of possible objects thus resulting in customized design. A particular application has been developed in the framework of a Research Contract involving the company MicroDetectors spa (Modena, Italy) and the Institute of Applied Acoustic (CNR-IDAC, Rome, Italy). This work concerned the design of an antenna part of a radio sensor unit (for temperature applications) based on the employment of a surface acoustic wave (SAW) device. The matching between the SAW and the antenna on the Tag is a critical issue of the design, if no matching network are used in order to maintain the costs low. The antenna efficiency must be taken under control, and in particular its gain pattern, to guarantee omnidirectionality and to improve the radio activation distance. Possible shieldings have also been investigated to allow the sensor to be independent on its placement [C24].<br />
<br />
[[File:SAW.png|900px]]<br><br />
Fig.10 (left) Geometry of the proposed antenna; (middle) gain pattern; (right) experimental measure set-up<br><br />
<br />
===Antennas for RFID tags===<br />
Radio Frequency Identification (RFID) is a recent technology which found applications in many practical areas such as automatic identification and location of objects, people tracking, supply chain management, security access to controlled<br />
areas, etc. A typical component of an RFID system is a small tag or transponder, which is located on the objects to be identified. A passive tag is composed by a transponder chip (IC) and a matched antenna enabling it to either capturing<br />
electromagnetic energy from an interrogating field or communicating with an RFID reader or interrogator. Passive RFID at UHF band (866-869 MHz, European band) and Microwave (2.45 GHz) communicate using the modulated scattered technique, where the reflected signal from the tag is modulated by the IC connected directly to the antenna. To obtain the maximum power transfer to the chip, a tag antenna is typically designed to be conjugate matched to it. In order to reduce costs and size, matching networks or other lumped elements are avoided. Moreover, the microchip is usually presenting a highly capacitive input impedance, thus the antenna input impedance should be intrinsically inductive. As a consequences, the design of<br />
tag antennas, that can be effectively integrated with the IC transponders, is one of the major constraint. This activity mainly concerns the development of a planar dual band slot-type binocular tag antenna operating at the frequencies of 868MHz and 2.45GHz is presented. The particular geometry resulting from the design has suggested the name of binocular antenna. This shape allows to obtain a good conjugate match to the input impedance of a chip operating at both frequency bands. The proposed antenna is also mechanically robust against possible vibrations and provide a quasi isotropic radiation patterns [C22].<br />
<br />
[[File:bino.png|800px]]<br><br />
Fig.11 (left) Geometry of the proposed antenna; (right) current displacement at the two operating frequencies<br><br />
<br />
===Microwave radiometer===<br />
Within a National Research Program (PRIN), a low-cost integrated X-band microwave radiometer for ground-based applications has been designed. The microwave frequencies offer advantages over the well established InfraRed (IR) technology, because a microwave signal can penetrate all materials (except of metals) allowing detection also through thick smokes and vapours. On the other hand, the longer wavelength of the microwave radiation, compared to IR, reduces the spatial resolution. An usual way to improve the spatial resolution is to address higher frequencies (up to the extreme limit of imaging capabilities) to get a better antenna directivity even if at the cost of a more expensive electronics of the microwave front-end. This research activity has regarded the design and prototyping of the antenna, designed as an array of patches, where number of elements, spacing and feeding currents have been optimized to fulfil requirements of low side lobe level and good cross polarization. First the single radiator has been optimized, then the feeding network and the overall array displacement have been designed [R8][C17]. The antenna, printed on a standard single layer Taconic substrate, has been then prototyped and its performance, in terms of input impedance and radiation pattern, measured with a customized set-up [C23].<br />
<br />
[[File:radiometer.png|900px]]<br><br />
Fig.12 (left) Geometry of the array antenna and prototype; (middle) input impedance characterization; (right) radiation pattern characterization<br><br />
<br />
== REGULARIZATION OF 3D SINGULAR KERNEL IN INTEGRAL EQUATIONS<br> ==<br />
The problem addressed in this research activity with Politecnico di Torino regards the well known problems that the Green’s functions employed in integral equation methods, such as the Method-of-Moments (MoM), diverge when observation and source points coincide; this is at the origin of the difficulties in computing the MoM matrix entries, and in handling the near-field interactions in FFT-based fast methods and other sampling-based methods. We have shown [R10][C16][C18][C19] that this singularity can be avoided, and a modified regular Green’s function can be used instead. This latter is obtained from the spectral representation of the usual Green’s function via windowing of its spectrum; the width of the spectral window depends on the size of the mesh employed for discretizing the problem, so that the proposed regular Green’s function is a mesh-adapted regular kernel. Numerical results for 3D antenna and scattering problems discretized with Rao-Wilton-Glisson (RWG) functions, have been produced to show the effectiveness of the approach, both for uniform and non-uniform meshing. They show that the<br />
proposed method yields accurate solutions also for the antenna input impedance.<br />
<br />
<br />
[[File:spectral.png|900px]]<br><br />
Fig.13 (left) Basis and test functions lying in different planes, generically oriented; (right) amplitude of the Fourier Transform of an RWG function of the mesh for both radial and angular component <br><br />
<br />
<br />
== ONGOING ACTIVITIES<br> ==<br />
===Ridge gap Waveguides===<br />
This activity is on the attempt to elaborate an approximate analytical analysis of the quasi-TEM dominant mode in a parallel plate metamaterial-based waveguide. This waveguide is constituted by a bed of nails surface interrupted by a metal strip, and covered by a metallic plate. This structure is simple to manufacture, especially at millimetre and sub-millimetre wave frequencies [C25][R13].<br />
<br />
[[File:gap.png|400px]]<br><br />
Fig14 Ridge gap waveguide geometry<br />
<br />
===Hollow Core Fibre for THz Applications===<br />
Hollow Core Photonic Band Gap Fibres (HC-PBGFs) are investigated in order to obtain low loss wave guiding and good aperture field distribution in the terahertz region (0.1 − 10THz) of the electromagnetic spectrum. Waveguides and antennas design<br />
in this spectral region is a major challenge due to the high conductivity losses of metals and high absorption of dielectrics. Numerical results show the possibility to reach propagation loss two decades lower than the bulk absorption losses of the material used to fabricate the fibre, over a wide range of wavelength. The purity of the aperture field distribution at the<br />
HC-PBGF section suggests a possible employment of such a structure as aperture antenna, for possible feed systems in THz applications [C26][C28].<br />
<br />
[[File:fibre.png|400px]]<br><br />
Fig.15 Possible photonic band gap fibres cross sections, investigated at THz.<br />
<br />
===Groove Waveguides at Optical Frequencies===<br />
This activity is carried on within the collaboration of Prof. Engheta (University of Pennsylvania, Philadelphia) and Prof. Alù (University of Austin, Texas). It mainly concerns on the theoretical and numerical analysis of an open waveguide, made by a groove on metals, and employed at optical frequencies. At these frequencies, metals (such as silver or gold) can be characterized by an equivalent Drude model permittivity, and in the region of negative permittivity values, surface polaritons can be propagated along the surface. Under certain resonance conditions, at least one of these polaritons are well confined inside the groove, thus allowing the wave guiding effect even in an open environment.<br />
<br />
[[File:groove.png|400px]]<br><br />
Fig.16 Effect of field confinement into the open waveguide.<br />
<br />
<br><br><br><br><br />
<br />
=PUBLICATIONS<br>=<br />
[http://www.dii.unimo.it/wiki/index.php/My_publications Publications]<br />
<br />
<br />
<br><br><br><br />
[[Image:home.gif|30px|left]] <br><br />
[[User:Apolemi | Home]]</div>Apolemihttps://web.ing.unimo.it/wiki/index.php?title=Research_Activity&diff=7412Research Activity2010-06-19T00:15:50Z<p>Apolemi: /* Hollow Core Fibre for THz Applications */</p>
<hr />
<div>= TOPICS <br> =<br />
<br />
The Alessia Polemi research activity begins at the Department of Information Engineering of the University of Siena, in the period of preparation of the master thesis degree, oriented to the asymptotic study of the Green’s function associated with truncated periodic arrays of elementary sources embedded in multilayered environment. This activity continued after the master thesis degree in cooperation with Prof. Felsen from the University of Boston, and it produced the publication of a sequence of three papers on this subject. Contemporarily, the scientific activity of Alessia Polemi also investigated the field of electromagnetic analytical and numerical methods, particularly referring to the high frequency techniques for the prediction of the electromagnetic scattering, with Prof. Roberto Tiberio and Prof. Stefano Maci as supervisors. The research activity has also been developed in the framework of national research programs (PRIN), university research programs (PAR), and in the framework of projects financed by the Italian Space Agency (ASI). She also participates to European research programs, as ACE and EAML. The experience on periodic structures and on Green's function for multilayered structures allowed her to start a fruitful collaboration with Politecnico di Torino, to assest new and efficient tools for the analysis of aperiodic and periodic printed elements embedded in dielectric materials. The collaboration with Politecnico di Torino has been also addressed to the problem of kernel regularization in 3D singular integral equations. Recently, her research activity is focusing on lens antenna, for which she is involved in a European Research Networking Program (RNP) with University of Rennes, on RFID antenna design, on microwave radiometers, and on metamaterials and plasmonic structure at optical frequencies, on which she is undertaking an international collaboration with Prof. Nader Engheta (University of Pennsylvania) and Prof. Andrea Alù (University of Austin, Texas).<br />
<br><br><br><br><br />
<br />
== ASYMPTOTIC METHODS FOR ARRAY ANTENNAS<br> ==<br />
The research activity in this area has the objective the development and application of asymptotic methods for analysis and design of array antennas embedded in multilayered dielectric environment. In particular, the research is mainly dedicated to the characterization of diffraction phenomena, generated by the periodicity truncation (semi-infinite array, sectoral array) through the array Green’s function (AGF), and through the subsequent integration of the representation into full-wave codes for the efficient analysis of printed antennas. <br><br />
<br />
<br />
===Array Green’s function (AGF): diffraction phenomena generated by edge truncation on dielectric slab===<br />
For a correct description of the diffraction generated by the array edge truncation, and interpreted in terms of rays according to the Geometrical Theory of Diffraction (GTD) generalized to periodic structures, the AGF must take into account not only for the presence of dielectrics, but also for the presence of periodicity. If the array is infinite, the Floquet theorem allows to express the AGF as superposition of a complete set of modes (Floquet modes), weighted by the spectral Green’s function of the single element in the periodicity. If the array is finite, this expansion cannot be directly applied. The aim of this research branch is that to formulate an AGF for an efficient treatment of truncated periodic array on dielectric slabs. The goal is reached referring to appropriate canonical problems. The first is that of introducing the truncation effects due to the edge (semi-infinite array), either for an array of line sources [R2], or for an array of point sources [R1][R4][C1]-[C5]. The integral describing the diffraction from the array edge can be evaluated applying asymptotic techniques. The knowledge of the asymptotic array Green’s function, not only is of advantage for the computational times, but it also allows to check separately the various field contributions (truncated Floquet modes, truncated surface and leaky waves), predicting the eventual interaction [R5][R6][C9][C11].<br />
<br />
[[File:AGF.png|900px]]<br><br />
Fig.1 Phenomenology associated with Semi-Infinite Array Green’s Function (AGF).(left) Semi-infinite elementary sources on multilayered environment (middle) Topology of the AGF (right) Schematic representation of the transition from a conical wave to a plane surface wave in 3D and 2D views<br />
<br />
=== Array Green’s function (AGF): diffraction phenomena generated by vertex truncation on dielectric slab ===<br />
In order to complete the extension o the Geometrical Theory of Diffraction (GTD) generalized to periodic structures it is necessary to develop an efficient asymptotic solution for the canonical problem associated with a sectoral array, where the truncation is present along both directions, including either spatial diffraction contribution or guided waves diffraction contribution. An hybrid technique based on an appropriate decomposition into canonical problems is developed to include diffraction terms, with particular care to the observation on the array surface, which is of basic importance when the continuity conditions of electric and magnetic fields must be applied [C14][C20][C23]. The method is based on an iterative process of subtraction, from the infinite array, of canonical problems constituted by semi-infinite and sectoral arrays. Each of these problems can be treated separately, applying convenient techniques, according to the observation region [C26][C28][C33].<br />
<br />
<br />
[[File:sector.png|800px]]<br><br />
Fig.2 Phenomenology associated with the Sectoral Array Green’s Function (AGF).(left) Sector of elementary sources on multilayered environment (middle) and (right) Schematic representation of the transition from edge and vertex diffracted waves. <br />
<br />
=== Introduction of the array Green’s function inside full-wave codes for the analysis of larege array antennas===<br />
The asymptotic Green’s function allows also to describe the field contributions due to the presence of double truncations. Thus, it could be efficiently employed to extend the applicability of full-wave methods also to very large array. This objective is reached solving the MoM through an appropriate regularized integral equation (“fringe” equation), where the unknown current is expanded on entire domain basis function, with behaviour imposed by dominant diffraction contributions [C6][C7][C10][C12][C16]. The main objective of this activity is concerned with an efficient evaluation of the Array Green’s Function (AGF) and its clever application into a MoM, while remaining in the application framework of arrays or periodic<br />
surfaces which exhibit weak variability with respect to periodicity of geometry and excitation. The high frequency method used here has the advantage to be additive with respect to the one associated with the infinite structure, with additional (edge)<br />
contribution which is not invariant by phase shifted translation, thus allowing the reuse of already existing numerical codes [C20]. The strategy adopted is briefly the following. All the elements of the array are discretized with triangular cells, where the Rao-Wilton-Glisson (RWG) basis functions are defined; in the AGF-MoM approach, the MoM problem is set-up and solved for each element in isolation, instead to implement the global array MoM reactions with a reduction of complexity and memory occupation. Thus, the key advantage in using the AGF in the MoM is in the possibility of evaluating and solving only the MoM<br />
matrix of each element against itself, instead of the MoM matrix of the whole array. The integration of the AGF with the MoM is organized in two steps and repeated for all the array elements.<br />
<br />
[[File:MOM.png|500px]]<br><br />
Fig.3 MoM Strategy for finite size arrays <br />
<br />
<br><br><br><br><br />
<br />
== GREEN'S FUNCTION CHARACTERIZATION FOR STRATIFIED DIELECTRICS<br> ==<br />
<br />
The activity is essentially devoted to the modeling of printed antenna.<br><br />
<br />
=== Characterization of guided phenomena===<br />
The presence of dielectric substrates influences the real radiating antenna performance and complicates the electromagnetic analysis. In fact, the structure supports guided waves propagation, in particular surface waves or leaky waves. On one hand, these kinds of guided waves can degrade the radiating antenna performance, on the other hand they can be employed to improve directivity/gain. Indeed, composite planar dielectric structures used for increasing the directivity of a point<br />
source, have been investigated since many years. This substrate/superstrate structure was demonstrated to establish a resonance condition, which maximizes antenna gain, radiation resistance, and radiation efficiency. Particular attention has been given to the physical interpretation of this resonance gain effect, which can be described in terms<br />
of leaky waves (LW) excited in the structure. Under certain resonance conditions, a pair of weakly attenuated TE/TM leaky waves become the dominant contributions to the antenna aperture field. Although the demonstrated interest in such<br />
type of configurations, the polarization characteristics of the structure wasn't investigated enough. The aim of this research activity has been to rigorously demonstrate that the conventional choice of the stratification, not only ensures a large aperture field, but the same field is also well polarized when excited by any linearly polarized point source [R7] [C29].<br><br />
<br />
[[File:Lens.png|800px]]<br><br />
Fig.4 (left) Topological investigation of coalescence of leaky waves (resonance condition) in a substrate/superstrate structure; (middle) and (left) purity of polarization of the copolar component of a linear polarized source embedded in such a substrate/superstrate structure.<br />
<br />
<br />
=== Asymptotic models===<br />
To characterize the dielectric structures, different methods have been employed for the efficient evaluation of the Green’s function, which, if known analytically in the spectral domain (wavenumber), can be transformed into the spatial domain through the Fourier transformation. In the hypothesis of high frequency, the evaluation of this integral can be performed asymptotically, through dominant contribution of the integral (saddle point and poles residues contributions). The Green’s function expressed in terms of these contributions, even if approximated, is convenient in terms of calculation time [R7]. <br><br />
<br />
=== Numerical models ===<br />
In the case when the radiating element is embedded into multilayered dielectric structures, the Green’s function calculation even in the spectral domain is more complex, and the integral relevant to the Fourier transformation is typically solved numerically. Nevertheless, this integral shows some difficulties related to the presence of poles associated with surface and leaky waves, and to its oscillating behavior. In this context, more effort has been devoted to the choice of alternative integrations paths and integration techniques which can improve the efficiency of numerical codes [RT1]. To accelerate the Green’s function calculation even in the near zone where the asymptotic technique fail, the research activity has regarded the implementation of numerical codes based on approximations known in literature as complex images , which allow the representation of the Green’s function in terms of a few spherical sources, whose ray can be complex. Particular attention has been given to improve the convergence of these methods, with the scope to be inserted into a MoM code for the analysis of printed antennas, already developed in co-operation with Politecnico of Turin, and up to now based standard integration techniques [RT4][RT5]. The convergence has been improved by properly extracting dominant contributions of the Green’s function, related to the quasi-static term, and to the guided waves. This approach is particularly efficient in the near zone, where other techniques, as the asymptotic one, fail.<br />
<br />
<br />
<br><br><br><br><br />
<br />
== HIGH FREQUENCY METHODS FOR SCATTERING PREDICTION FROM PERFECTLY AND NON PERFECTLY CONDUCTING OBJECTS<br> ==<br />
<br />
This research activity concerns the development of new uniform diffraction coefficients and incremental techniques, suitable for prediction of scattering from perfectly and non perfectly conducting obstacles. This activity is of fundamental importance in the analysis of the field scattered or diffracted by large objects in terms of wavelength, such for the design and analysis of large antennas (e.g., reflectors), for the prediction of Radar Cross Section propagation in complex environments (e.g., urban propagation), for antenna installation and inter-antenna coupling (e.g., on ships, aircrafts, space platforms…).<br><br />
<br />
[[File: Large.png|800px]]<br><br />
Fig.5 Different scenarios for applications of high frquency methods<br />
<br />
<br />
===Generalization of Incremental Theory of Diffraction===<br />
Within this research activity, a general systematic procedure has been reached for defining incremental field contributions in the framework of scattering prediction from large conducting objects [R3]. The procedure is based on a generalization of the Incremental Theory of Diffraction (ITD) localization process for uniform cylindrical, local canonical problems with elementary source illumination and arbitrary observation aspects. In particular, it is shown that the spectral integral formulation of the exact solution for the local canonical problem may also be represented as a spatial integral convolution along the longitudinal coordinates of the cylindrical configuration. Its integrand is then directly used to define the relevant incremental field contribution. For the sake of convenience, but without loss of generality, this procedure is illustrated for the case of local wedge configurations. Also, a specific suitable asymptotic analysis is developed to derive new closed form high-frequency expressions from the spectral integral formulation. These expressions for the incremental field contributions explicitly satisfy reciprocity and are applicable at any incidence and observation aspect. This generalization of the ITD localization process together with its more accurate asymptotic analysis provides a definite improvement of the method. <br><br />
<br />
<br />
===Extension of Geometrical Theory of Diffraction for analysis of scattering from canonical planar structures===<br />
In the framework of high frequency techniques, the research activity has been addressed to the extension of methods for scattering prediction from planar structures such as wedge, also non perfectly conducting (dielectric, if necessary), with reference to the canonical problem associated with the half-plane and the junction of two parts plane [C24]. In the contest of the Uniform Theory of Diffraction (UTD), usually applied to the scattering of metallic or opaque surfaces, a heuristic formulation, simple but sufficiently accurate for most engineering applications, can be derived starting from the rigorous formulation of non penetrable screens, involving standard reflection and transmission coefficients, easily calculated for planar dielectric structures. These coefficients contain already known transition functions [C18][C21][C22]. Particular attention has been given to the inclusion of surface waves that can be guided by non perfectly conducting surfaces [C25][C27][C32]. The analysis, UTD-based, has been developed by calculating surface waves poles associated with the non perfectly conducting wedge faces (half-plane or two-parts junction), and from them appropriate diffraction coefficients are derived, heuristically extrapolated from the relevant canonical problems of surface impedance wedges. <br />
<br />
[[File: UTD.png|700px]]<br><br />
Fig.6 (left) High frequency localization principles; (right) Overall compensation mechanism in scattering from a dielectric half plane<br />
<br />
<br />
===Extension of Incremental Theory of Diffraction for analysis of scattering from planar canonical structures===<br />
The applicability of the Incremental Theory of Diffraction (ITD), tipically limited to the scattering from metallic surfaces, has been extended to non perfectly conducting surfaces (alse dielectric). The ITD is based on a suitable use of canonical problem solutions which locally approximate the structure geometry. A localization process allows to define incremental coefficients which, integrated along discontinuity lines or shadow lines, furnish the diffracted field[R3]. The main objective has been the derivation of a heuristic ITD formulation, simple but still accurate for most of engineering applications, starting from the rigorous formulation for metallic screens, with reference to the canonical problem associated with half-plane and two-parts junction [C13][C17][C18][C21][C30]. The so derived incremental diffraction coefficient is implicitly reciprocal and reduces to the ITD coefficient for conducting faces wedges (pec or pmc), in limiting cases. Through this formulation has been treated the scattering from faceted structures formed by composite materials, also in caustic zones, where the UTD ray-description becomes singular. In addiction, the ITD diffraction coefficient has also been written in terms of "fringe" contribution, in order to be inserted in already available PO codes. <br />
<br />
[[File: ITD.png|500px]]<br><br />
Fig.7 ITD application to circular dielectric structures<br />
<br />
===Extension of Incremental Theory of Diffraction to complex source illuminations===<br />
When representing arbitrarily shaped antenna radiation patterns, Gaussian Beams (GBs) turn out as very effective. GBs are solution of Maxwell equations only in the paraxial region but they are deeply concerned with the concept of the Complex Source Point (CSP), whose field is Maxwellian throughout the space (also outside the paraxial region), as can be easily inferred<br />
via an analytic continuation of the source point Green’s function when the source position is allowed to be complex. Such a GBs/CSPs representation can be used within a ray code to predict the interaction between antenna and the actual environment, if standard diffraction formulations are extended to the CSP case. The CSP extension of ray techniques like UTD appears to be substantially more problematic than that of incremental ray theories, such as ITD. Thus, this activity has been oriented to analyze this CSP extension of discrete and incremental ray techniques, with particular reference to the ITD formulation [R9][C11][C14].<br />
<br />
[[File: csp.png|700px]]<br><br />
Fig.8 ITD extension to Complex Source Points (CSP)<br />
<br />
<br><br><br><br><br />
<br />
<br />
== DESIGN OF ANTENNAS FOR MODERN WIRELESS APPLICATIONS<br> ==<br />
Recently, the activity has been oriented towards emerging radiating systems employed in different wireless applications(RFID, Bluetooth, ZigBee, body-centric networks, sensors networks, etc.). In this field, the activity concerns the analysis, design and prototyping of printed technology antennas, which are versatile, easy to be realized, and at low cost.<br><br />
<br />
[[File:wireless.png|900px]]<br><br />
Fig.9 Emerging wireless applications<br />
<br />
<br />
===Antennas for sensors networks===<br />
In sensors networks, antennas are mounted on-board and disseminated in different areas (environment, on human body, cars, etc.). They usually communicate with a main access point, which can be a personal computer, a PDA, or other. Antennas for these kinds of applications must be omnidirectional, in order to guarantee communication independently on their actual displacement with respect to the main access point. Unfortunately, their placement on objects of different nature degrades the performance, such as the efficiency and the input impedance. Especially this last must be taken under control in order to guarantee the right matching with the sensor itself. As a consequence, the antenna design must include the presence of possible objects thus resulting in customized design. A particular application has been developed in the framework of a Research Contract involving the company MicroDetectors spa (Modena, Italy) and the Institute of Applied Acoustic (CNR-IDAC, Rome, Italy). This work concerned the design of an antenna part of a radio sensor unit (for temperature applications) based on the employment of a surface acoustic wave (SAW) device. The matching between the SAW and the antenna on the Tag is a critical issue of the design, if no matching network are used in order to maintain the costs low. The antenna efficiency must be taken under control, and in particular its gain pattern, to guarantee omnidirectionality and to improve the radio activation distance. Possible shieldings have also been investigated to allow the sensor to be independent on its placement [C24].<br />
<br />
[[File:SAW.png|900px]]<br><br />
Fig.10 (left) Geometry of the proposed antenna; (middle) gain pattern; (right) experimental measure set-up<br><br />
<br />
===Antennas for RFID tags===<br />
Radio Frequency Identification (RFID) is a recent technology which found applications in many practical areas such as automatic identification and location of objects, people tracking, supply chain management, security access to controlled<br />
areas, etc. A typical component of an RFID system is a small tag or transponder, which is located on the objects to be identified. A passive tag is composed by a transponder chip (IC) and a matched antenna enabling it to either capturing<br />
electromagnetic energy from an interrogating field or communicating with an RFID reader or interrogator. Passive RFID at UHF band (866-869 MHz, European band) and Microwave (2.45 GHz) communicate using the modulated scattered technique, where the reflected signal from the tag is modulated by the IC connected directly to the antenna. To obtain the maximum power transfer to the chip, a tag antenna is typically designed to be conjugate matched to it. In order to reduce costs and size, matching networks or other lumped elements are avoided. Moreover, the microchip is usually presenting a highly capacitive input impedance, thus the antenna input impedance should be intrinsically inductive. As a consequences, the design of<br />
tag antennas, that can be effectively integrated with the IC transponders, is one of the major constraint. This activity mainly concerns the development of a planar dual band slot-type binocular tag antenna operating at the frequencies of 868MHz and 2.45GHz is presented. The particular geometry resulting from the design has suggested the name of binocular antenna. This shape allows to obtain a good conjugate match to the input impedance of a chip operating at both frequency bands. The proposed antenna is also mechanically robust against possible vibrations and provide a quasi isotropic radiation patterns [C22].<br />
<br />
[[File:bino.png|800px]]<br><br />
Fig.11 (left) Geometry of the proposed antenna; (right) current displacement at the two operating frequencies<br><br />
<br />
===Microwave radiometer===<br />
Within a National Research Program (PRIN), a low-cost integrated X-band microwave radiometer for ground-based applications has been designed. The microwave frequencies offer advantages over the well established InfraRed (IR) technology, because a microwave signal can penetrate all materials (except of metals) allowing detection also through thick smokes and vapours. On the other hand, the longer wavelength of the microwave radiation, compared to IR, reduces the spatial resolution. An usual way to improve the spatial resolution is to address higher frequencies (up to the extreme limit of imaging capabilities) to get a better antenna directivity even if at the cost of a more expensive electronics of the microwave front-end. This research activity has regarded the design and prototyping of the antenna, designed as an array of patches, where number of elements, spacing and feeding currents have been optimized to fulfil requirements of low side lobe level and good cross polarization. First the single radiator has been optimized, then the feeding network and the overall array displacement have been designed [R8][C17]. The antenna, printed on a standard single layer Taconic substrate, has been then prototyped and its performance, in terms of input impedance and radiation pattern, measured with a customized set-up [C23].<br />
<br />
[[File:radiometer.png|900px]]<br><br />
Fig.12 (left) Geometry of the array antenna and prototype; (middle) input impedance characterization; (right) radiation pattern characterization<br><br />
<br />
== REGULARIZATION OF 3D SINGULAR KERNEL IN INTEGRAL EQUATIONS<br> ==<br />
The problem addressed in this research activity with Politecnico di Torino regards the well known problems that the Green’s functions employed in integral equation methods, such as the Method-of-Moments (MoM), diverge when observation and source points coincide; this is at the origin of the difficulties in computing the MoM matrix entries, and in handling the near-field interactions in FFT-based fast methods and other sampling-based methods. We have shown [R10][C16][C18][C19] that this singularity can be avoided, and a modified regular Green’s function can be used instead. This latter is obtained from the spectral representation of the usual Green’s function via windowing of its spectrum; the width of the spectral window depends on the size of the mesh employed for discretizing the problem, so that the proposed regular Green’s function is a mesh-adapted regular kernel. Numerical results for 3D antenna and scattering problems discretized with Rao-Wilton-Glisson (RWG) functions, have been produced to show the effectiveness of the approach, both for uniform and non-uniform meshing. They show that the<br />
proposed method yields accurate solutions also for the antenna input impedance.<br />
<br />
<br />
[[File:spectral.png|900px]]<br><br />
Fig.13 (left) Basis and test functions lying in different planes, generically oriented; (right) amplitude of the Fourier Transform of an RWG function of the mesh for both radial and angular component <br><br />
<br />
<br />
== ONGOING ACTIVITIES<br> ==<br />
===Ridge gap Waveguides===<br />
This activity is on the attempt to elaborate an approximate analytical analysis of the quasi-TEM dominant mode in a parallel plate metamaterial-based waveguide. This waveguide is constituted by a bed of nails surface interrupted by a metal strip, and covered by a metallic plate. This structure is simple to manufacture, especially at millimetre and sub-millimetre wave frequencies [C25][R13].<br />
<br />
[[File:gap.png|400px]]<br><br />
Fig14 Ridge gap waveguide geometry<br />
<br />
===Hollow Core Fibre for THz Applications===<br />
Hollow Core Photonic Band Gap Fibres (HC-PBGFs) are investigated in order to obtain low loss wave guiding and good aperture field distribution in the terahertz region (0.1 − 10THz) of the electromagnetic spectrum. Waveguides and antennas design<br />
in this spectral region is a major challenge due to the high conductivity losses of metals and high absorption of dielectrics. Numerical results show the possibility to reach propagation loss two decades lower than the bulk absorption losses of the material used to fabricate the fibre, over a wide range of wavelength. The purity of the aperture field distribution at the<br />
HC-PBGF section suggests a possible employment of such a structure as aperture antenna, for possible feed systems in THz applications [C26][C28].<br />
<br />
[[File:fibre.png|400px]]<br><br />
Fig.15 Possible photonic band gap fibres cross sections, investigated at THz.<br />
<br />
===Groove Waveguides at Optical Frequencies===<br />
This activity is carried on within the collaboration of Prof. Engheta (University of Pennsylvania, Philadelphia) and Prof. Alù (University of Austin, Texas). It mainly concerns on the theoretical and numerical analysis of an open waveguide, made by a groove on metals, and employed at optical frequencies. At these frequencies, metals (such as silver or gold) can be characterized by an equivalent Drude model permittivity, and in the region of negative permittivity values, surface polaritons can be propagated along the surface. Under certain resonance conditions, at least one of these polaritons are well confined inside the groove, thus allowing the wave guiding effect even in an open environment.<br />
<br />
[[File:groove.png|400px]]<br><br />
Fig.16 Effect of field confinement into the open waveguide.<br />
<br />
<br><br><br><br><br />
<br />
=PUBLICATIONS<br>=<br />
[http://www.dii.unimo.it/wiki/index.php/My_publications Publications]<br />
<br />
<br />
<br><br><br><br />
[[Image:home.gif|30px|left]] <br><br />
[[User:Apolemi | Home]]</div>Apolemihttps://web.ing.unimo.it/wiki/index.php?title=User:Apolemi&diff=7411User:Apolemi2010-06-18T23:30:18Z<p>Apolemi: </p>
<hr />
<div>[[Image:Alessia polemi.jpg|250px|left]] <br />
address: Dipartimento di Ingegneria dell'Informazione, via Vignolese 905, Modena, Italy, I-41125<br> <br />
tel: +39-059-2056326<br> <br />
fax: +39-059-2056129<br> <br />
email: [mailto:alessia.polemi@unimore.it alessia.polemi@unimore.it] <br> <br />
<br> <br />
Alessia Polemi was born in Casteldelpiano, Grosseto, Italy, on July 10, 1973. She received her Doctor of Engineering degree in Telecommunications Engineering(cum laude) from the [http://www.unisi.it University of Siena] in July 1999 discussing a thesis about the [http://lipari.ing.unimo.it/polemi/tesi.pdf Array Green's Function for a Semi-Infinite Array of Dipoles on a Grounded Slab.] <br />
<br />
From November 1999 to October 2002 she was a Ph.D student at the [http://www.dii.unisi.it Department of Information Engineering (DII)] of the University of Siena. She received a Ph.D. degree in Information Engineering in March 2003 with a thesis entitled [http://lipari.ing.unimo.it/polemi/phd_thesis.pdf Frequency-Domain Green’s Function for Planar Periodic Large Phased Arrays in Multilayered Dielectric Regions.]<br />
<br />
From January 2003 to October 2006 she was a post doctorate researcher at the Department of Information Engineering of the University of Siena. During the PhD and post-doc period she attended several different international PhD classes and European schools. <br />
<br />
She serves as a reviewer for important international journals on electrical engineering and electromagnetics such as IEEE, IET, Elsevier Journals and Transactions. <br />
<br />
Since November 2006 she has been an Assistant Professor of Electromagnetic Fields at the [http://www.ing.unimo.it School of Engineering,] within the [http://www.dii.unimo.it Department of Information Engineering] of the [http://www.unimo.it University of Modena and Reggio Emilia,] where she is teaching Radiopropagation and she is the assistant at the course on Electromagnetic Fields. <br />
<br />
Since 2008, she has been frequently a visiting professor at the [http://www.upenn.edu University of Pennsylvania], in Philadelphia, working on plasmonic structures with [http://www.ese.upenn.edu/~engheta Prof. Nader Engheta] and his group. <br />
<br />
Since 2000 she is member of the [http://www.ieee.org Institute of Electrical and Electronic Engineers (IEEE)] and since November 2006 she has been the Italian Student Adviser for the [http://www.iet.org Institution of Engineering and Technology (IET)]. <br />
<br />
In November 2009, she has obtained the tenure track as Assistant Professor at the [http://www.ing.unimo.it School of Engineering,] within the [http://www.dii.unimo.it Department of Information Engineering] of the [http://www.unimo.it University of Modena and Reggio Emilia].<br />
<br />
She is currently Research Scientist at Drexel University, Department of Chemistry, in the framework of a research program on local surface plasmon enhancement at optical frequency, with Prof. Kevin Shuford.<br />
<br />
Her current research includes high frequency scattering theories, asymptotics electromagnetic methods, numerical electromagnetic methods, periodic structures, bandgap structures, antenna design, antenna miniaturization, wideband and ultrawideband antennas, RFID systems, printed devices at microwave frequencies, new emerging waveguides, metamaterials and polaritons at optical frequency. For further details, see [[Research Activity]] section<br />
<br><br><br />
----<br />
* [[My Curriculum Vitae]] (and [[Media:CV_ALESSIA_POLEMI_USA.pdf|pdf]] version) <br> <br> <br />
* [[Research Activity]] <br> <br><br />
* [[My publications]] <br> <br><br />
* [[Teaching Activity]] <br> <br><br />
* [[MATERIALE DIDATTICO]] <br><br><br />
----<br />
;[[Image:news.gif|120px]] [[News and Events]]<br />
----</div>Apolemihttps://web.ing.unimo.it/wiki/index.php?title=User:Apolemi&diff=7409User:Apolemi2010-06-18T23:29:03Z<p>Apolemi: </p>
<hr />
<div>[[Image:Alessia polemi.jpg|250px|left]] <br />
address: Dipartimento di Ingegneria dell'Informazione, via Vignolese 905, Modena, Italy, I-41125<br> <br />
tel: +39-059-2056326<br> <br />
fax: +39-059-2056129<br> <br />
email: [mailto:alessia.polemi@unimore.it alessia.polemi@unimore.it] <br> <br />
<br> <br />
Alessia Polemi was born in Casteldelpiano, Grosseto, Italy, on July 10, 1973. She received her Doctor of Engineering degree in Telecommunications Engineering(cum laude) from the [http://www.unisi.it University of Siena] in July 1999 discussing a thesis about the [http://lipari.ing.unimo.it/polemi/tesi.pdf Array Green's Function for a Semi-Infinite Array of Dipoles on a Grounded Slab.] <br />
<br />
From November 1999 to October 2002 she was a Ph.D student at the [http://www.dii.unisi.it Department of Information Engineering (DII)] of the University of Siena. She received a Ph.D. degree in Information Engineering in March 2003 with a thesis entitled [http://lipari.ing.unimo.it/polemi/phd_thesis.pdf Frequency-Domain Green’s Function for Planar Periodic Large Phased Arrays in Multilayered Dielectric Regions.]<br />
<br />
From January 2003 to October 2006 she was a post doctorate researcher at the Department of Information Engineering of the University of Siena. During the PhD and post-doc period she attended several different international PhD classes and European schools. <br />
<br />
She serves as a reviewer for important international journals on electrical engineering and electromagnetics such as IEEE, IET, Elsevier Journals and Transactions. <br />
<br />
Since November 2006 she has been an Assistant Professor of Electromagnetic Fields at the [http://www.ing.unimo.it School of Engineering,] within the [http://www.dii.unimo.it Department of Information Engineering] of the [http://www.unimo.it University of Modena and Reggio Emilia,] where she is teaching Radiopropagation and she is the assistant at the course on Electromagnetic Fields. <br />
<br />
Since 2008, she has been frequently a visiting professor at the [http://www.upenn.edu University of Pennsylvania], in Philadelphia, working on plasmonic structures with [http://www.ese.upenn.edu/~engheta Prof. Nader Engheta] and his group. <br />
<br />
Since 2000 she is member of the [http://www.ieee.org Institute of Electrical and Electronic Engineers (IEEE)] and since November 2006 she has been the Italian Student Adviser for the [http://www.iet.org Institution of Engineering and Technology (IET)]. <br />
<br />
In November 2009, she has obtained the tenure track as Assistant Professor at the [http://www.ing.unimo.it School of Engineering,] within the [http://www.dii.unimo.it Department of Information Engineering] of the [http://www.unimo.it University of Modena and Reggio Emilia].<br />
<br />
She is currently Research Scientist at Drexel University, Department of Chemistry, in the framework of a research program on local surface plasmon enhancement at optical frequency, with Prof. Kevin Shuford.<br />
<br />
Her current research includes high frequency scattering theories, asymptotics electromagnetic methods, numerical electromagnetic methods, periodic structures, bandgap structures, antenna design, antenna miniaturization, wideband and ultrawideband antennas, RFID systems, printed devices at microwave frequencies, new emerging waveguides, metamaterials and polaritons at optical frequency. For further details, see [[Research Activity]] section<br />
<br><br><br />
----<br />
* [[My Curriculum Vitae]] (and [[Media:CV_ALESSIA_POLEM_USAI.pdf|pdf]] version) <br> <br> <br />
* [[Research Activity]] <br> <br><br />
* [[My publications]] <br> <br><br />
* [[Teaching Activity]] <br> <br><br />
* [[MATERIALE DIDATTICO]] <br><br><br />
----<br />
;[[Image:news.gif|120px]] [[News and Events]]<br />
----</div>Apolemihttps://web.ing.unimo.it/wiki/index.php?title=My_Curriculum_Vitae&diff=7408My Curriculum Vitae2010-06-18T23:25:45Z<p>Apolemi: /* INTERNATIONAL RESEARCH PROGRAMS */</p>
<hr />
<div>'''(LAST UPDATE: 07/12/2009)'''<br><br />
<br />
===PERSONAL INFORMATION===<br />
[[Office address:]] <br><br />
Department of Information Engineering <br><br />
University of Modena and Reggio Emilia <br><br />
Via Vignolese 905<br><br />
41100 Modena, ITALY<br><br />
Tel. +39 059 2056326<br><br />
Fax. +39 059 2056129<br><br />
Mobile: +39 335 7181823<br><br />
E-mail: [mailto:alessia.polemi@unimore.it alessia.polemi@unimore.it]<br><br />
web-site: http://www.dii.unimore.it/polemi<br><br />
<br />
===EDUCATION===<br />
* July 1999: M.S. (cum laude) in Telecommunication Engineering at University of Siena. Thesis dissertation: "Green’s Functions for phased arrays of dipoles on dielectric slab" (supervisors: Prof. S. Maci, Prof. R. Tiberio, Prof. A. Toccafondi). <br><br><br />
* January 2000: national qualification for engineers at the University of Florence. <br><br><br />
* March 2003: PhD in Information Engineering (curriculum: electromagnetic waves) at the University of Siena. Thesis dissertation: "Frequency Domain Green's Function for Periodic Large Phased Arrays in Multilayered Dielectric Regions " (tutor: Prof. R. Tiberio). <br><br><br />
* January 2003-October 2006: post-doc researcher at the Department of Information Engineering, University of Siena<br><br><br />
<br />
===PRESENT EMPLOYMENT===<br />
* November 2006: Assistant Professor at the School of Engineering of University of Modena and Reggio Emilia (scientific area: ELECTROMAGNETIC FIELDS)<br />
<br />
* November 2009: tenure track as Assistant Professor at the School of Engineering of University of Modena and Reggio Emilia (scientific area: ELECTROMAGNETIC FIELDS)<br />
<br />
* January 2010: Research Scientist at Drexel University, Department of Chemistry<br />
<br />
===RESEARCH INTERESTS===<br />
* High frequency scattering theories<br><br />
* Asymptotics electromagnetic methods<br><br />
* Numerical electromagnetic methods<br><br />
* Periodic structures<br><br />
* Bandgap structures<br><br />
* Antenna design<br><br />
* Antenna miniaturization<br><br />
* Wideband and ultrawideband antennas<br><br />
* RFID systems<br><br />
* Printed devices at microwave frequencies<br><br />
* New emerging waveguides<br><br />
* Metamaterials <br><br />
* Plasmon polaritons at optical frequency <br><br />
* Plasmonic channels <br><br />
* Molecule-nanoparticle interaction<br><br />
* Nanoantennas<br><br />
<br />
Further details in [[Research Activity]] section. <br><br><br />
<br />
===PROFESSIONAL SOCIETIES===<br />
* 1999, appointed to the profession of Engineer <br><br><br />
* 2000, Member of the Institute of Electrical and Electronic Engineers (IEEE) <br><br><br />
* September 2003-December 2005, president of the academic spin-off company WaveComm srl.<br><br><br />
* 2006, Italian Student Adviser for the Institution of Engineering and Technology (IET) <br><br><br />
<br><br><br />
<br />
===SOFTWARE SKILLS AND COMPETENCE===<br />
* Operating systems MS Windows 98/NT/2k/XP/Vista <br><br />
* MS Office<br><br />
* Maltlab<br><br />
* CorelDraw<br><br />
* Latex<br><br />
* Fortran<br><br />
* C<br><br />
* Mathematica<br><br />
* Electromagnetic simulation software<br><br />
** Ansoft Designer<br><br />
** HFSS<br><br />
** CST Microwave Studio<br><br />
** Grasp<br><br />
** FEKO<br><br />
** MicroWave Office<br><br />
** Wipl-d<br><br><br />
<br />
===TEACHING ACTIVITY===<br />
* 1999/2000, seminars in the Electromagnetic Field course at the School of Engineering of University of Siena <br><br />
* 2000/2001, seminars in the Microwave course at the School of Engineering of University of Siena <br><br />
* 2001/2002, seminars in the Antennas course at the School of Engineering of University of Siena <br><br />
* 2002/2003, course of Design of Microwave Circuits at the School of Engineering of University of Siena <br><br />
* 2003, course of Numerical Methods for Electromagnetics at the Master on Microwave Systems on Technologies for Telecommunications, Messina (Italy) <br><br />
* 2003/2004 and 2004/2005, course of Electromagnetic Modelling at the School of Engineering of University of Siena <br><br />
* 2005, seminars into the school “High Frequency Methods and Travelling Wave Antennas”, European School of Antennas (ACE – Antenna Centre of Excellence), at University of Siena, about:<br><br />
** Green’s function of the dielectric slab<br> <br />
** Scattering from a perfectly conducting half-plane<br><br><br />
* Since 2005: <br><br />
** course of Radio Propagation class at the School of Engineering of University of Modena and Reggio Emilia<br><br />
** assisting in the Electromagnetic Field class at the School of Engineering of University of Modena and Reggio Emilia<br><br />
** Microwave Lab class at the School of Engineering of University of Modena and Reggio Emilia<br><br><br />
<br />
Visit the page [[Teaching Activity]] for Teaching Statement . <br><br><br />
<br />
===SUPERVISED STUDENTS===<br />
* 2001 M.S. "Giacomo Donzelli", GENERALIZED PENCIL OF FUNCTION TECHNIQUE FOR MULTILAYERED PRINTED STRUCTURES<br><br />
* 2002 M.S. "Alberto Nencini", ASYMPTOTIC GREEN'S FUNCTION FOR A SECTORAL ARRAY OF ELEMENTARY SOURCES ON A DIELECTRIC SLAB<br> <br />
* 2005 M.S. "Giorgio Carluccio", EXTENSION OF THE INCREMENTAL THEORY OF DIFFRACTION TO COMPLEX SOURCES <br><br />
* 2006 M.S. "Michele Gravina", ANTENNA FOR BIOMEDICAL RFID APPLICATION<br><br />
* 2006 M.S. "Daniele Ciccarese", WIMAX: MAN WIRELESS TECHNOLOGY <br><br />
* 2007 M.S. "Guido Santamaria", ELECTROMAGNETIC CHARACTERIZATION OF TRANSITIONS BETWEEN COAXIAL CABLE AND MICROSTRIP<br><br />
* 2007 M.S. "Lorenzo Santunione", DESIGN AND CHARACTERIZATION OF A PRINTED DIPOLE ANTENNA WITH UNBALNCED FEEDING<br><br />
* 2007 Laurea Degree. "Enrico Busi", ANALYSIS AND DESIGN OF A PLANAR ANTENNA FOR UWB APPLICATIONS<br><br />
* 2008 M.S. "Marcello di Clemente", SAW SENSORS<br><br />
* 2008 Laurea Degree. "Gagliardi Giuseppina", WIDE BAND PATCH ANTENNAS DESIGN<br><br />
* 2008 M.S. "Javier Molejón Asenjo", DESIGN OF A DUAL BAND ANTENNA FOR RFID APPLICATIONS IN THE UHF BAND <br><br />
* 2009 M.S. "Luca Morandini", DEVICES FOR THE MONITORING OF ELECTROMAGNETIC INTERFERENCES DURING TIMING IN SPORT RACES, THROUGHOUT RFID SYSTEMS<br><br />
* 2009 M.S. "Erio Gandini", ANALYSIS OF BACKSCATTERING FROM PLANAR FRESNEL LENSES<br><br><br />
<br />
===ATTENDED SPECIALIZED PHD COURSES===<br />
* 2000, at University of Siena <br><br />
** Functional analysis elements <br><br />
** Interpolation and approximation of curves and surfaces <br> <br />
** Optimization Methods <br><br />
** Wavelets <br><br />
** Object Oriented Programming <br><br />
* 2002, at Chalmers University, Gotheborg, Sweden <br><br />
** Artificial Magnetic Conductors and Soft and Hard surfaces and their Use in Antenna Analysis and Design <br><br />
* 2002, at University of Ancona, PhD School <br><br />
** Ground Penetrating Radar <br><br />
*2005, at Denmark Technical University - Ticra, European School of Antennas (ACE - Antenna Center of Excellence) <br><br />
** Reflector antennas: analysis and design <br><br />
* 2005, at Politecnico of Turin, European School of Antennas (ACE - Antenna Center of Excellence) <br><br />
** Computational EM for antenna analysis <br><br />
* 2005, at University of Siena, European School of Antennas (ACE - Antenna Center of Excellence) <br><br />
** High Frequency Methods and Travelling Wave Antennas <br><br />
* 2006, at University of Dubrovnik, European School of Antennas (ACE - Antenna Center of Excellence) <br><br />
** Advanced Mathematics for Antenna Analysis <br><br><br />
<br />
===NATIONAL RESEARCH PROGRAMS===<br />
* 2000-2002. PAR (Piano d’Ateneo per la Ricerca) “Antenna installation for wireless communication systems”<br><br />
* 2000-2002. ASI (Italian Space Agency): “Reflectarrays for satellite applications” <br><br />
* 2003-2005. PRIN (Progetto di ricerca di interesse nazionale) “Electromagnetic models for analysis of passive reflectarrays”<br><br />
* 2005-2007. PRIN (Progetto di ricerca di interesse nazionale) “Microwave Radiometer for fire monitoring” <br><br><br />
<br />
===INTERNATIONAL RESEARCH PROGRAMS===<br />
* 2004-2005. ACE Antenna Centre of Excellence, V Framework Program, WP. 1.1.1 Integration, WP. 3.1.1 European School of Antennas<br><br />
* 2005-2006. ACE Antennas Centre of Excellence, VI Framework Program, WP. 3.1.1 European School of Antennas<br><br />
* 2005-2007. EAML European Antenna Modeling Library, contract with ESA-ESTEC n.18802/04/NL/JD, WP. 1.6.1.0 5S Green’s Function for stratified environment<br><br />
* 2009-ongoing. EAML European Antenna Modeling Library, TT&C Coverage in Complex Environments with the European Space Agency (ESA)<br><br />
* 2009-ongoing. EuroStar Project, New production process for medical bags based on RadioFrequency sterilization and ICT<br><br><br />
<br />
===RESEARCH CONTRACTS===<br />
* 2000-2001. Research contract between Department of Information Engineering (University of Siena) - IDS spa, in the framework of the agreement with Italian Navy for "Electromagnetic models for prediction of scattering objects" <br><br />
* 2000-2002. Research contract Department of Information Engineering (University of Siena) - IDS spa, in the framework of the agreement with IDS spa for "Green’s function for multilayered materials"<br><br />
* 2002-2003. Research contract Department of Information Engineering (University of Siena) - IDS spa, in the framework of the agreement with IDS spa for "Incremental Theory of Diffraction for dielectric screens"<br> <br />
* 2003-2004. Research contract with Consorzio Etruria ed Innovazione scpa, entitled "Feasibility and design of an automatic identification system on controlled areas based on the standard ISO/IEC 15693" <br><br />
* 2004-2005. Research contract with Consorzio Etruria ed Innovazione scpa, entitled "Electromagnetic scattering from non perfectly conducting half-planes and junctions between planes: UTD and ITD formulation" <br><br />
* 2005-2006. Research contract Department of Information Engineering (University of Siena) - IDS spa, in the framework of the agreement with IDS spa for "Green’s functions for dielectric multilayers; extension to magnetic sources" <br><br />
* 2007-2008. Research contract Department of Information Engineering (University of Modena and Reggio Emilia) -Politecnico di Torino, entitled "Evolution and evolutionary maintenance of European Antenna Modeling Library Components" <br><br />
* 2008. Research contract Department of Information Engineering (University of Modena and Reggio Emilia) –MD-Microdetectors (protected by NDA) <br> <br><br />
<br />
===PUBLICATIONS===<br />
[http://www.dii.unimo.it/wiki/index.php/My_publications Publications]<br />
<br />
<br />
<br><br><br><br />
[[Image:home.gif|30px|left]] <br><br />
[[User:Apolemi | Home]]</div>Apolemihttps://web.ing.unimo.it/wiki/index.php?title=My_Curriculum_Vitae&diff=7407My Curriculum Vitae2010-06-18T23:25:27Z<p>Apolemi: /* STUDENT SUPERVISED */</p>
<hr />
<div>'''(LAST UPDATE: 07/12/2009)'''<br><br />
<br />
===PERSONAL INFORMATION===<br />
[[Office address:]] <br><br />
Department of Information Engineering <br><br />
University of Modena and Reggio Emilia <br><br />
Via Vignolese 905<br><br />
41100 Modena, ITALY<br><br />
Tel. +39 059 2056326<br><br />
Fax. +39 059 2056129<br><br />
Mobile: +39 335 7181823<br><br />
E-mail: [mailto:alessia.polemi@unimore.it alessia.polemi@unimore.it]<br><br />
web-site: http://www.dii.unimore.it/polemi<br><br />
<br />
===EDUCATION===<br />
* July 1999: M.S. (cum laude) in Telecommunication Engineering at University of Siena. Thesis dissertation: "Green’s Functions for phased arrays of dipoles on dielectric slab" (supervisors: Prof. S. Maci, Prof. R. Tiberio, Prof. A. Toccafondi). <br><br><br />
* January 2000: national qualification for engineers at the University of Florence. <br><br><br />
* March 2003: PhD in Information Engineering (curriculum: electromagnetic waves) at the University of Siena. Thesis dissertation: "Frequency Domain Green's Function for Periodic Large Phased Arrays in Multilayered Dielectric Regions " (tutor: Prof. R. Tiberio). <br><br><br />
* January 2003-October 2006: post-doc researcher at the Department of Information Engineering, University of Siena<br><br><br />
<br />
===PRESENT EMPLOYMENT===<br />
* November 2006: Assistant Professor at the School of Engineering of University of Modena and Reggio Emilia (scientific area: ELECTROMAGNETIC FIELDS)<br />
<br />
* November 2009: tenure track as Assistant Professor at the School of Engineering of University of Modena and Reggio Emilia (scientific area: ELECTROMAGNETIC FIELDS)<br />
<br />
* January 2010: Research Scientist at Drexel University, Department of Chemistry<br />
<br />
===RESEARCH INTERESTS===<br />
* High frequency scattering theories<br><br />
* Asymptotics electromagnetic methods<br><br />
* Numerical electromagnetic methods<br><br />
* Periodic structures<br><br />
* Bandgap structures<br><br />
* Antenna design<br><br />
* Antenna miniaturization<br><br />
* Wideband and ultrawideband antennas<br><br />
* RFID systems<br><br />
* Printed devices at microwave frequencies<br><br />
* New emerging waveguides<br><br />
* Metamaterials <br><br />
* Plasmon polaritons at optical frequency <br><br />
* Plasmonic channels <br><br />
* Molecule-nanoparticle interaction<br><br />
* Nanoantennas<br><br />
<br />
Further details in [[Research Activity]] section. <br><br><br />
<br />
===PROFESSIONAL SOCIETIES===<br />
* 1999, appointed to the profession of Engineer <br><br><br />
* 2000, Member of the Institute of Electrical and Electronic Engineers (IEEE) <br><br><br />
* September 2003-December 2005, president of the academic spin-off company WaveComm srl.<br><br><br />
* 2006, Italian Student Adviser for the Institution of Engineering and Technology (IET) <br><br><br />
<br><br><br />
<br />
===SOFTWARE SKILLS AND COMPETENCE===<br />
* Operating systems MS Windows 98/NT/2k/XP/Vista <br><br />
* MS Office<br><br />
* Maltlab<br><br />
* CorelDraw<br><br />
* Latex<br><br />
* Fortran<br><br />
* C<br><br />
* Mathematica<br><br />
* Electromagnetic simulation software<br><br />
** Ansoft Designer<br><br />
** HFSS<br><br />
** CST Microwave Studio<br><br />
** Grasp<br><br />
** FEKO<br><br />
** MicroWave Office<br><br />
** Wipl-d<br><br><br />
<br />
===TEACHING ACTIVITY===<br />
* 1999/2000, seminars in the Electromagnetic Field course at the School of Engineering of University of Siena <br><br />
* 2000/2001, seminars in the Microwave course at the School of Engineering of University of Siena <br><br />
* 2001/2002, seminars in the Antennas course at the School of Engineering of University of Siena <br><br />
* 2002/2003, course of Design of Microwave Circuits at the School of Engineering of University of Siena <br><br />
* 2003, course of Numerical Methods for Electromagnetics at the Master on Microwave Systems on Technologies for Telecommunications, Messina (Italy) <br><br />
* 2003/2004 and 2004/2005, course of Electromagnetic Modelling at the School of Engineering of University of Siena <br><br />
* 2005, seminars into the school “High Frequency Methods and Travelling Wave Antennas”, European School of Antennas (ACE – Antenna Centre of Excellence), at University of Siena, about:<br><br />
** Green’s function of the dielectric slab<br> <br />
** Scattering from a perfectly conducting half-plane<br><br><br />
* Since 2005: <br><br />
** course of Radio Propagation class at the School of Engineering of University of Modena and Reggio Emilia<br><br />
** assisting in the Electromagnetic Field class at the School of Engineering of University of Modena and Reggio Emilia<br><br />
** Microwave Lab class at the School of Engineering of University of Modena and Reggio Emilia<br><br><br />
<br />
Visit the page [[Teaching Activity]] for Teaching Statement . <br><br><br />
<br />
===SUPERVISED STUDENTS===<br />
* 2001 M.S. "Giacomo Donzelli", GENERALIZED PENCIL OF FUNCTION TECHNIQUE FOR MULTILAYERED PRINTED STRUCTURES<br><br />
* 2002 M.S. "Alberto Nencini", ASYMPTOTIC GREEN'S FUNCTION FOR A SECTORAL ARRAY OF ELEMENTARY SOURCES ON A DIELECTRIC SLAB<br> <br />
* 2005 M.S. "Giorgio Carluccio", EXTENSION OF THE INCREMENTAL THEORY OF DIFFRACTION TO COMPLEX SOURCES <br><br />
* 2006 M.S. "Michele Gravina", ANTENNA FOR BIOMEDICAL RFID APPLICATION<br><br />
* 2006 M.S. "Daniele Ciccarese", WIMAX: MAN WIRELESS TECHNOLOGY <br><br />
* 2007 M.S. "Guido Santamaria", ELECTROMAGNETIC CHARACTERIZATION OF TRANSITIONS BETWEEN COAXIAL CABLE AND MICROSTRIP<br><br />
* 2007 M.S. "Lorenzo Santunione", DESIGN AND CHARACTERIZATION OF A PRINTED DIPOLE ANTENNA WITH UNBALNCED FEEDING<br><br />
* 2007 Laurea Degree. "Enrico Busi", ANALYSIS AND DESIGN OF A PLANAR ANTENNA FOR UWB APPLICATIONS<br><br />
* 2008 M.S. "Marcello di Clemente", SAW SENSORS<br><br />
* 2008 Laurea Degree. "Gagliardi Giuseppina", WIDE BAND PATCH ANTENNAS DESIGN<br><br />
* 2008 M.S. "Javier Molejón Asenjo", DESIGN OF A DUAL BAND ANTENNA FOR RFID APPLICATIONS IN THE UHF BAND <br><br />
* 2009 M.S. "Luca Morandini", DEVICES FOR THE MONITORING OF ELECTROMAGNETIC INTERFERENCES DURING TIMING IN SPORT RACES, THROUGHOUT RFID SYSTEMS<br><br />
* 2009 M.S. "Erio Gandini", ANALYSIS OF BACKSCATTERING FROM PLANAR FRESNEL LENSES<br><br><br />
<br />
===ATTENDED SPECIALIZED PHD COURSES===<br />
* 2000, at University of Siena <br><br />
** Functional analysis elements <br><br />
** Interpolation and approximation of curves and surfaces <br> <br />
** Optimization Methods <br><br />
** Wavelets <br><br />
** Object Oriented Programming <br><br />
* 2002, at Chalmers University, Gotheborg, Sweden <br><br />
** Artificial Magnetic Conductors and Soft and Hard surfaces and their Use in Antenna Analysis and Design <br><br />
* 2002, at University of Ancona, PhD School <br><br />
** Ground Penetrating Radar <br><br />
*2005, at Denmark Technical University - Ticra, European School of Antennas (ACE - Antenna Center of Excellence) <br><br />
** Reflector antennas: analysis and design <br><br />
* 2005, at Politecnico of Turin, European School of Antennas (ACE - Antenna Center of Excellence) <br><br />
** Computational EM for antenna analysis <br><br />
* 2005, at University of Siena, European School of Antennas (ACE - Antenna Center of Excellence) <br><br />
** High Frequency Methods and Travelling Wave Antennas <br><br />
* 2006, at University of Dubrovnik, European School of Antennas (ACE - Antenna Center of Excellence) <br><br />
** Advanced Mathematics for Antenna Analysis <br><br><br />
<br />
===NATIONAL RESEARCH PROGRAMS===<br />
* 2000-2002. PAR (Piano d’Ateneo per la Ricerca) “Antenna installation for wireless communication systems”<br><br />
* 2000-2002. ASI (Italian Space Agency): “Reflectarrays for satellite applications” <br><br />
* 2003-2005. PRIN (Progetto di ricerca di interesse nazionale) “Electromagnetic models for analysis of passive reflectarrays”<br><br />
* 2005-2007. PRIN (Progetto di ricerca di interesse nazionale) “Microwave Radiometer for fire monitoring” <br><br><br />
<br />
===INTERNATIONAL RESEARCH PROGRAMS===<br />
* 2004-2005. ACE Antenna Centre of Excellence, V Framework Program, WP. 1.1.1 Integration, WP. 3.1.1 European School of Antennas<br><br />
* 2005-2006. ACE Antennas Centre of Excellence, VI Framework Program, WP. 3.1.1 European School of Antennas<br><br />
* 2005-2007. EAML European Antenna Modeling Library, contract with ESA-ESTEC n.18802/04/NL/JD, WP. 1.6.1.0 5S Green’s Function for stratified environment<br><br />
* 2009-ongoing. EAML European Antenna Modeling Library, TT&C Coverage in Complex Environments <br><br />
* 2009-ongoing. EuroStar Project, New production process for medical bags based on RadioFrequency sterilization and ICT<br><br><br />
<br />
===RESEARCH CONTRACTS===<br />
* 2000-2001. Research contract between Department of Information Engineering (University of Siena) - IDS spa, in the framework of the agreement with Italian Navy for "Electromagnetic models for prediction of scattering objects" <br><br />
* 2000-2002. Research contract Department of Information Engineering (University of Siena) - IDS spa, in the framework of the agreement with IDS spa for "Green’s function for multilayered materials"<br><br />
* 2002-2003. Research contract Department of Information Engineering (University of Siena) - IDS spa, in the framework of the agreement with IDS spa for "Incremental Theory of Diffraction for dielectric screens"<br> <br />
* 2003-2004. Research contract with Consorzio Etruria ed Innovazione scpa, entitled "Feasibility and design of an automatic identification system on controlled areas based on the standard ISO/IEC 15693" <br><br />
* 2004-2005. Research contract with Consorzio Etruria ed Innovazione scpa, entitled "Electromagnetic scattering from non perfectly conducting half-planes and junctions between planes: UTD and ITD formulation" <br><br />
* 2005-2006. Research contract Department of Information Engineering (University of Siena) - IDS spa, in the framework of the agreement with IDS spa for "Green’s functions for dielectric multilayers; extension to magnetic sources" <br><br />
* 2007-2008. Research contract Department of Information Engineering (University of Modena and Reggio Emilia) -Politecnico di Torino, entitled "Evolution and evolutionary maintenance of European Antenna Modeling Library Components" <br><br />
* 2008. Research contract Department of Information Engineering (University of Modena and Reggio Emilia) –MD-Microdetectors (protected by NDA) <br> <br><br />
<br />
===PUBLICATIONS===<br />
[http://www.dii.unimo.it/wiki/index.php/My_publications Publications]<br />
<br />
<br />
<br><br><br><br />
[[Image:home.gif|30px|left]] <br><br />
[[User:Apolemi | Home]]</div>Apolemihttps://web.ing.unimo.it/wiki/index.php?title=My_Curriculum_Vitae&diff=7406My Curriculum Vitae2010-06-18T23:23:10Z<p>Apolemi: /* RESEARCH INTERESTS */</p>
<hr />
<div>'''(LAST UPDATE: 07/12/2009)'''<br><br />
<br />
===PERSONAL INFORMATION===<br />
[[Office address:]] <br><br />
Department of Information Engineering <br><br />
University of Modena and Reggio Emilia <br><br />
Via Vignolese 905<br><br />
41100 Modena, ITALY<br><br />
Tel. +39 059 2056326<br><br />
Fax. +39 059 2056129<br><br />
Mobile: +39 335 7181823<br><br />
E-mail: [mailto:alessia.polemi@unimore.it alessia.polemi@unimore.it]<br><br />
web-site: http://www.dii.unimore.it/polemi<br><br />
<br />
===EDUCATION===<br />
* July 1999: M.S. (cum laude) in Telecommunication Engineering at University of Siena. Thesis dissertation: "Green’s Functions for phased arrays of dipoles on dielectric slab" (supervisors: Prof. S. Maci, Prof. R. Tiberio, Prof. A. Toccafondi). <br><br><br />
* January 2000: national qualification for engineers at the University of Florence. <br><br><br />
* March 2003: PhD in Information Engineering (curriculum: electromagnetic waves) at the University of Siena. Thesis dissertation: "Frequency Domain Green's Function for Periodic Large Phased Arrays in Multilayered Dielectric Regions " (tutor: Prof. R. Tiberio). <br><br><br />
* January 2003-October 2006: post-doc researcher at the Department of Information Engineering, University of Siena<br><br><br />
<br />
===PRESENT EMPLOYMENT===<br />
* November 2006: Assistant Professor at the School of Engineering of University of Modena and Reggio Emilia (scientific area: ELECTROMAGNETIC FIELDS)<br />
<br />
* November 2009: tenure track as Assistant Professor at the School of Engineering of University of Modena and Reggio Emilia (scientific area: ELECTROMAGNETIC FIELDS)<br />
<br />
* January 2010: Research Scientist at Drexel University, Department of Chemistry<br />
<br />
===RESEARCH INTERESTS===<br />
* High frequency scattering theories<br><br />
* Asymptotics electromagnetic methods<br><br />
* Numerical electromagnetic methods<br><br />
* Periodic structures<br><br />
* Bandgap structures<br><br />
* Antenna design<br><br />
* Antenna miniaturization<br><br />
* Wideband and ultrawideband antennas<br><br />
* RFID systems<br><br />
* Printed devices at microwave frequencies<br><br />
* New emerging waveguides<br><br />
* Metamaterials <br><br />
* Plasmon polaritons at optical frequency <br><br />
* Plasmonic channels <br><br />
* Molecule-nanoparticle interaction<br><br />
* Nanoantennas<br><br />
<br />
Further details in [[Research Activity]] section. <br><br><br />
<br />
===PROFESSIONAL SOCIETIES===<br />
* 1999, appointed to the profession of Engineer <br><br><br />
* 2000, Member of the Institute of Electrical and Electronic Engineers (IEEE) <br><br><br />
* September 2003-December 2005, president of the academic spin-off company WaveComm srl.<br><br><br />
* 2006, Italian Student Adviser for the Institution of Engineering and Technology (IET) <br><br><br />
<br><br><br />
<br />
===SOFTWARE SKILLS AND COMPETENCE===<br />
* Operating systems MS Windows 98/NT/2k/XP/Vista <br><br />
* MS Office<br><br />
* Maltlab<br><br />
* CorelDraw<br><br />
* Latex<br><br />
* Fortran<br><br />
* C<br><br />
* Mathematica<br><br />
* Electromagnetic simulation software<br><br />
** Ansoft Designer<br><br />
** HFSS<br><br />
** CST Microwave Studio<br><br />
** Grasp<br><br />
** FEKO<br><br />
** MicroWave Office<br><br />
** Wipl-d<br><br><br />
<br />
===TEACHING ACTIVITY===<br />
* 1999/2000, seminars in the Electromagnetic Field course at the School of Engineering of University of Siena <br><br />
* 2000/2001, seminars in the Microwave course at the School of Engineering of University of Siena <br><br />
* 2001/2002, seminars in the Antennas course at the School of Engineering of University of Siena <br><br />
* 2002/2003, course of Design of Microwave Circuits at the School of Engineering of University of Siena <br><br />
* 2003, course of Numerical Methods for Electromagnetics at the Master on Microwave Systems on Technologies for Telecommunications, Messina (Italy) <br><br />
* 2003/2004 and 2004/2005, course of Electromagnetic Modelling at the School of Engineering of University of Siena <br><br />
* 2005, seminars into the school “High Frequency Methods and Travelling Wave Antennas”, European School of Antennas (ACE – Antenna Centre of Excellence), at University of Siena, about:<br><br />
** Green’s function of the dielectric slab<br> <br />
** Scattering from a perfectly conducting half-plane<br><br><br />
* Since 2005: <br><br />
** course of Radio Propagation class at the School of Engineering of University of Modena and Reggio Emilia<br><br />
** assisting in the Electromagnetic Field class at the School of Engineering of University of Modena and Reggio Emilia<br><br />
** Microwave Lab class at the School of Engineering of University of Modena and Reggio Emilia<br><br><br />
<br />
Visit the page [[Teaching Activity]] for Teaching Statement . <br><br><br />
<br />
===STUDENT SUPERVISED===<br />
* 2001 M.S. "Giacomo Donzelli", GENERALIZED PENCIL OF FUNCTION TECHNIQUE FOR MULTILAYERED PRINTED STRUCTURES<br><br />
* 2002 M.S. "Alberto Nencini", ASYMPTOTIC GREEN'S FUNCTION FOR A SECTORAL ARRAY OF ELEMENTARY SOURCES ON A DIELECTRIC SLAB<br> <br />
* 2005 M.S. "Giorgio Carluccio", EXTENSION OF THE INCREMENTAL THEORY OF DIFFRACTION TO COMPLEX SOURCES <br><br />
* 2006 M.S. "Michele Gravina", ANTENNA FOR BIOMEDICAL RFID APPLICATION<br><br />
* 2006 M.S. "Daniele Ciccarese", WIMAX: MAN WIRELESS TECHNOLOGY <br><br />
* 2007 M.S. "Guido Santamaria", ELECTROMAGNETIC CHARACTERIZATION OF TRANSITIONS BETWEEN COAXIAL CABLE AND MICROSTRIP<br><br />
* 2007 M.S. "Lorenzo Santunione", DESIGN AND CHARACTERIZATION OF A PRINTED DIPOLE ANTENNA WITH UNBALNCED FEEDING<br><br />
* 2007 Laurea Degree. "Enrico Busi", ANALYSIS AND DESIGN OF A PLANAR ANTENNA FOR UWB APPLICATIONS<br><br />
* 2008 M.S. "Marcello di Clemente", SAW SENSORS<br><br />
* 2008 Laurea Degree. "Gagliardi Giuseppina", WIDE BAND PATCH ANTENNAS DESIGN<br><br />
* 2008 M.S. "Javier Molejón Asenjo", DESIGN OF A DUAL BAND ANTENNA FOR RFID APPLICATIONS IN THE UHF BAND <br><br />
* 2009 M.S. "Luca Morandini", DEVICES FOR THE MONITORING OF ELECTROMAGNETIC INTERFERENCES DURING TIMING IN SPORT RACES, THROUGHOUT RFID SYSTEMS<br><br />
* 2009 M.S. "Erio Gandini", ANALYSIS OF BACKSCATTERING FROM PLANAR FRESNEL LENSES<br><br><br />
<br />
===ATTENDED SPECIALIZED PHD COURSES===<br />
* 2000, at University of Siena <br><br />
** Functional analysis elements <br><br />
** Interpolation and approximation of curves and surfaces <br> <br />
** Optimization Methods <br><br />
** Wavelets <br><br />
** Object Oriented Programming <br><br />
* 2002, at Chalmers University, Gotheborg, Sweden <br><br />
** Artificial Magnetic Conductors and Soft and Hard surfaces and their Use in Antenna Analysis and Design <br><br />
* 2002, at University of Ancona, PhD School <br><br />
** Ground Penetrating Radar <br><br />
*2005, at Denmark Technical University - Ticra, European School of Antennas (ACE - Antenna Center of Excellence) <br><br />
** Reflector antennas: analysis and design <br><br />
* 2005, at Politecnico of Turin, European School of Antennas (ACE - Antenna Center of Excellence) <br><br />
** Computational EM for antenna analysis <br><br />
* 2005, at University of Siena, European School of Antennas (ACE - Antenna Center of Excellence) <br><br />
** High Frequency Methods and Travelling Wave Antennas <br><br />
* 2006, at University of Dubrovnik, European School of Antennas (ACE - Antenna Center of Excellence) <br><br />
** Advanced Mathematics for Antenna Analysis <br><br><br />
<br />
===NATIONAL RESEARCH PROGRAMS===<br />
* 2000-2002. PAR (Piano d’Ateneo per la Ricerca) “Antenna installation for wireless communication systems”<br><br />
* 2000-2002. ASI (Italian Space Agency): “Reflectarrays for satellite applications” <br><br />
* 2003-2005. PRIN (Progetto di ricerca di interesse nazionale) “Electromagnetic models for analysis of passive reflectarrays”<br><br />
* 2005-2007. PRIN (Progetto di ricerca di interesse nazionale) “Microwave Radiometer for fire monitoring” <br><br><br />
<br />
===INTERNATIONAL RESEARCH PROGRAMS===<br />
* 2004-2005. ACE Antenna Centre of Excellence, V Framework Program, WP. 1.1.1 Integration, WP. 3.1.1 European School of Antennas<br><br />
* 2005-2006. ACE Antennas Centre of Excellence, VI Framework Program, WP. 3.1.1 European School of Antennas<br><br />
* 2005-2007. EAML European Antenna Modeling Library, contract with ESA-ESTEC n.18802/04/NL/JD, WP. 1.6.1.0 5S Green’s Function for stratified environment<br><br />
* 2009-ongoing. EAML European Antenna Modeling Library, TT&C Coverage in Complex Environments <br><br />
* 2009-ongoing. EuroStar Project, New production process for medical bags based on RadioFrequency sterilization and ICT<br><br><br />
<br />
===RESEARCH CONTRACTS===<br />
* 2000-2001. Research contract between Department of Information Engineering (University of Siena) - IDS spa, in the framework of the agreement with Italian Navy for "Electromagnetic models for prediction of scattering objects" <br><br />
* 2000-2002. Research contract Department of Information Engineering (University of Siena) - IDS spa, in the framework of the agreement with IDS spa for "Green’s function for multilayered materials"<br><br />
* 2002-2003. Research contract Department of Information Engineering (University of Siena) - IDS spa, in the framework of the agreement with IDS spa for "Incremental Theory of Diffraction for dielectric screens"<br> <br />
* 2003-2004. Research contract with Consorzio Etruria ed Innovazione scpa, entitled "Feasibility and design of an automatic identification system on controlled areas based on the standard ISO/IEC 15693" <br><br />
* 2004-2005. Research contract with Consorzio Etruria ed Innovazione scpa, entitled "Electromagnetic scattering from non perfectly conducting half-planes and junctions between planes: UTD and ITD formulation" <br><br />
* 2005-2006. Research contract Department of Information Engineering (University of Siena) - IDS spa, in the framework of the agreement with IDS spa for "Green’s functions for dielectric multilayers; extension to magnetic sources" <br><br />
* 2007-2008. Research contract Department of Information Engineering (University of Modena and Reggio Emilia) -Politecnico di Torino, entitled "Evolution and evolutionary maintenance of European Antenna Modeling Library Components" <br><br />
* 2008. Research contract Department of Information Engineering (University of Modena and Reggio Emilia) –MD-Microdetectors (protected by NDA) <br> <br><br />
<br />
===PUBLICATIONS===<br />
[http://www.dii.unimo.it/wiki/index.php/My_publications Publications]<br />
<br />
<br />
<br><br><br><br />
[[Image:home.gif|30px|left]] <br><br />
[[User:Apolemi | Home]]</div>Apolemihttps://web.ing.unimo.it/wiki/index.php?title=My_Curriculum_Vitae&diff=7405My Curriculum Vitae2010-06-18T23:22:08Z<p>Apolemi: /* PRESENT EMPLOYMENT */</p>
<hr />
<div>'''(LAST UPDATE: 07/12/2009)'''<br><br />
<br />
===PERSONAL INFORMATION===<br />
[[Office address:]] <br><br />
Department of Information Engineering <br><br />
University of Modena and Reggio Emilia <br><br />
Via Vignolese 905<br><br />
41100 Modena, ITALY<br><br />
Tel. +39 059 2056326<br><br />
Fax. +39 059 2056129<br><br />
Mobile: +39 335 7181823<br><br />
E-mail: [mailto:alessia.polemi@unimore.it alessia.polemi@unimore.it]<br><br />
web-site: http://www.dii.unimore.it/polemi<br><br />
<br />
===EDUCATION===<br />
* July 1999: M.S. (cum laude) in Telecommunication Engineering at University of Siena. Thesis dissertation: "Green’s Functions for phased arrays of dipoles on dielectric slab" (supervisors: Prof. S. Maci, Prof. R. Tiberio, Prof. A. Toccafondi). <br><br><br />
* January 2000: national qualification for engineers at the University of Florence. <br><br><br />
* March 2003: PhD in Information Engineering (curriculum: electromagnetic waves) at the University of Siena. Thesis dissertation: "Frequency Domain Green's Function for Periodic Large Phased Arrays in Multilayered Dielectric Regions " (tutor: Prof. R. Tiberio). <br><br><br />
* January 2003-October 2006: post-doc researcher at the Department of Information Engineering, University of Siena<br><br><br />
<br />
===PRESENT EMPLOYMENT===<br />
* November 2006: Assistant Professor at the School of Engineering of University of Modena and Reggio Emilia (scientific area: ELECTROMAGNETIC FIELDS)<br />
<br />
* November 2009: tenure track as Assistant Professor at the School of Engineering of University of Modena and Reggio Emilia (scientific area: ELECTROMAGNETIC FIELDS)<br />
<br />
* January 2010: Research Scientist at Drexel University, Department of Chemistry<br />
<br />
===RESEARCH INTERESTS===<br />
* High frequency scattering theories<br><br />
* Asymptotics electromagnetic methods<br><br />
* Numerical electromagnetic methods<br><br />
* Periodic structures<br><br />
* Bandgap structures<br><br />
* Antenna design<br><br />
* Antenna miniaturization<br><br />
* Wideband and ultrawideband antennas<br><br />
* RFID systems<br><br />
* Printed devices at microwave frequencies<br><br />
* New emerging waveguides<br><br />
* Metamaterials <br><br />
* Polaritons at optical frequency<br><br />
Further details in [[Research Activity]] section. <br><br><br />
<br />
===PROFESSIONAL SOCIETIES===<br />
* 1999, appointed to the profession of Engineer <br><br><br />
* 2000, Member of the Institute of Electrical and Electronic Engineers (IEEE) <br><br><br />
* September 2003-December 2005, president of the academic spin-off company WaveComm srl.<br><br><br />
* 2006, Italian Student Adviser for the Institution of Engineering and Technology (IET) <br><br><br />
<br><br><br />
<br />
===SOFTWARE SKILLS AND COMPETENCE===<br />
* Operating systems MS Windows 98/NT/2k/XP/Vista <br><br />
* MS Office<br><br />
* Maltlab<br><br />
* CorelDraw<br><br />
* Latex<br><br />
* Fortran<br><br />
* C<br><br />
* Mathematica<br><br />
* Electromagnetic simulation software<br><br />
** Ansoft Designer<br><br />
** HFSS<br><br />
** CST Microwave Studio<br><br />
** Grasp<br><br />
** FEKO<br><br />
** MicroWave Office<br><br />
** Wipl-d<br><br><br />
<br />
===TEACHING ACTIVITY===<br />
* 1999/2000, seminars in the Electromagnetic Field course at the School of Engineering of University of Siena <br><br />
* 2000/2001, seminars in the Microwave course at the School of Engineering of University of Siena <br><br />
* 2001/2002, seminars in the Antennas course at the School of Engineering of University of Siena <br><br />
* 2002/2003, course of Design of Microwave Circuits at the School of Engineering of University of Siena <br><br />
* 2003, course of Numerical Methods for Electromagnetics at the Master on Microwave Systems on Technologies for Telecommunications, Messina (Italy) <br><br />
* 2003/2004 and 2004/2005, course of Electromagnetic Modelling at the School of Engineering of University of Siena <br><br />
* 2005, seminars into the school “High Frequency Methods and Travelling Wave Antennas”, European School of Antennas (ACE – Antenna Centre of Excellence), at University of Siena, about:<br><br />
** Green’s function of the dielectric slab<br> <br />
** Scattering from a perfectly conducting half-plane<br><br><br />
* Since 2005: <br><br />
** course of Radio Propagation class at the School of Engineering of University of Modena and Reggio Emilia<br><br />
** assisting in the Electromagnetic Field class at the School of Engineering of University of Modena and Reggio Emilia<br><br />
** Microwave Lab class at the School of Engineering of University of Modena and Reggio Emilia<br><br><br />
<br />
Visit the page [[Teaching Activity]] for Teaching Statement . <br><br><br />
<br />
===STUDENT SUPERVISED===<br />
* 2001 M.S. "Giacomo Donzelli", GENERALIZED PENCIL OF FUNCTION TECHNIQUE FOR MULTILAYERED PRINTED STRUCTURES<br><br />
* 2002 M.S. "Alberto Nencini", ASYMPTOTIC GREEN'S FUNCTION FOR A SECTORAL ARRAY OF ELEMENTARY SOURCES ON A DIELECTRIC SLAB<br> <br />
* 2005 M.S. "Giorgio Carluccio", EXTENSION OF THE INCREMENTAL THEORY OF DIFFRACTION TO COMPLEX SOURCES <br><br />
* 2006 M.S. "Michele Gravina", ANTENNA FOR BIOMEDICAL RFID APPLICATION<br><br />
* 2006 M.S. "Daniele Ciccarese", WIMAX: MAN WIRELESS TECHNOLOGY <br><br />
* 2007 M.S. "Guido Santamaria", ELECTROMAGNETIC CHARACTERIZATION OF TRANSITIONS BETWEEN COAXIAL CABLE AND MICROSTRIP<br><br />
* 2007 M.S. "Lorenzo Santunione", DESIGN AND CHARACTERIZATION OF A PRINTED DIPOLE ANTENNA WITH UNBALNCED FEEDING<br><br />
* 2007 Laurea Degree. "Enrico Busi", ANALYSIS AND DESIGN OF A PLANAR ANTENNA FOR UWB APPLICATIONS<br><br />
* 2008 M.S. "Marcello di Clemente", SAW SENSORS<br><br />
* 2008 Laurea Degree. "Gagliardi Giuseppina", WIDE BAND PATCH ANTENNAS DESIGN<br><br />
* 2008 M.S. "Javier Molejón Asenjo", DESIGN OF A DUAL BAND ANTENNA FOR RFID APPLICATIONS IN THE UHF BAND <br><br />
* 2009 M.S. "Luca Morandini", DEVICES FOR THE MONITORING OF ELECTROMAGNETIC INTERFERENCES DURING TIMING IN SPORT RACES, THROUGHOUT RFID SYSTEMS<br><br />
* 2009 M.S. "Erio Gandini", ANALYSIS OF BACKSCATTERING FROM PLANAR FRESNEL LENSES<br><br><br />
<br />
===ATTENDED SPECIALIZED PHD COURSES===<br />
* 2000, at University of Siena <br><br />
** Functional analysis elements <br><br />
** Interpolation and approximation of curves and surfaces <br> <br />
** Optimization Methods <br><br />
** Wavelets <br><br />
** Object Oriented Programming <br><br />
* 2002, at Chalmers University, Gotheborg, Sweden <br><br />
** Artificial Magnetic Conductors and Soft and Hard surfaces and their Use in Antenna Analysis and Design <br><br />
* 2002, at University of Ancona, PhD School <br><br />
** Ground Penetrating Radar <br><br />
*2005, at Denmark Technical University - Ticra, European School of Antennas (ACE - Antenna Center of Excellence) <br><br />
** Reflector antennas: analysis and design <br><br />
* 2005, at Politecnico of Turin, European School of Antennas (ACE - Antenna Center of Excellence) <br><br />
** Computational EM for antenna analysis <br><br />
* 2005, at University of Siena, European School of Antennas (ACE - Antenna Center of Excellence) <br><br />
** High Frequency Methods and Travelling Wave Antennas <br><br />
* 2006, at University of Dubrovnik, European School of Antennas (ACE - Antenna Center of Excellence) <br><br />
** Advanced Mathematics for Antenna Analysis <br><br><br />
<br />
===NATIONAL RESEARCH PROGRAMS===<br />
* 2000-2002. PAR (Piano d’Ateneo per la Ricerca) “Antenna installation for wireless communication systems”<br><br />
* 2000-2002. ASI (Italian Space Agency): “Reflectarrays for satellite applications” <br><br />
* 2003-2005. PRIN (Progetto di ricerca di interesse nazionale) “Electromagnetic models for analysis of passive reflectarrays”<br><br />
* 2005-2007. PRIN (Progetto di ricerca di interesse nazionale) “Microwave Radiometer for fire monitoring” <br><br><br />
<br />
===INTERNATIONAL RESEARCH PROGRAMS===<br />
* 2004-2005. ACE Antenna Centre of Excellence, V Framework Program, WP. 1.1.1 Integration, WP. 3.1.1 European School of Antennas<br><br />
* 2005-2006. ACE Antennas Centre of Excellence, VI Framework Program, WP. 3.1.1 European School of Antennas<br><br />
* 2005-2007. EAML European Antenna Modeling Library, contract with ESA-ESTEC n.18802/04/NL/JD, WP. 1.6.1.0 5S Green’s Function for stratified environment<br><br />
* 2009-ongoing. EAML European Antenna Modeling Library, TT&C Coverage in Complex Environments <br><br />
* 2009-ongoing. EuroStar Project, New production process for medical bags based on RadioFrequency sterilization and ICT<br><br><br />
<br />
===RESEARCH CONTRACTS===<br />
* 2000-2001. Research contract between Department of Information Engineering (University of Siena) - IDS spa, in the framework of the agreement with Italian Navy for "Electromagnetic models for prediction of scattering objects" <br><br />
* 2000-2002. Research contract Department of Information Engineering (University of Siena) - IDS spa, in the framework of the agreement with IDS spa for "Green’s function for multilayered materials"<br><br />
* 2002-2003. Research contract Department of Information Engineering (University of Siena) - IDS spa, in the framework of the agreement with IDS spa for "Incremental Theory of Diffraction for dielectric screens"<br> <br />
* 2003-2004. Research contract with Consorzio Etruria ed Innovazione scpa, entitled "Feasibility and design of an automatic identification system on controlled areas based on the standard ISO/IEC 15693" <br><br />
* 2004-2005. Research contract with Consorzio Etruria ed Innovazione scpa, entitled "Electromagnetic scattering from non perfectly conducting half-planes and junctions between planes: UTD and ITD formulation" <br><br />
* 2005-2006. Research contract Department of Information Engineering (University of Siena) - IDS spa, in the framework of the agreement with IDS spa for "Green’s functions for dielectric multilayers; extension to magnetic sources" <br><br />
* 2007-2008. Research contract Department of Information Engineering (University of Modena and Reggio Emilia) -Politecnico di Torino, entitled "Evolution and evolutionary maintenance of European Antenna Modeling Library Components" <br><br />
* 2008. Research contract Department of Information Engineering (University of Modena and Reggio Emilia) –MD-Microdetectors (protected by NDA) <br> <br><br />
<br />
===PUBLICATIONS===<br />
[http://www.dii.unimo.it/wiki/index.php/My_publications Publications]<br />
<br />
<br />
<br><br><br><br />
[[Image:home.gif|30px|left]] <br><br />
[[User:Apolemi | Home]]</div>Apolemihttps://web.ing.unimo.it/wiki/index.php?title=My_Curriculum_Vitae&diff=7404My Curriculum Vitae2010-06-18T23:20:37Z<p>Apolemi: /* PERSONAL INFORMATION */</p>
<hr />
<div>'''(LAST UPDATE: 07/12/2009)'''<br><br />
<br />
===PERSONAL INFORMATION===<br />
[[Office address:]] <br><br />
Department of Information Engineering <br><br />
University of Modena and Reggio Emilia <br><br />
Via Vignolese 905<br><br />
41100 Modena, ITALY<br><br />
Tel. +39 059 2056326<br><br />
Fax. +39 059 2056129<br><br />
Mobile: +39 335 7181823<br><br />
E-mail: [mailto:alessia.polemi@unimore.it alessia.polemi@unimore.it]<br><br />
web-site: http://www.dii.unimore.it/polemi<br><br />
<br />
===EDUCATION===<br />
* July 1999: M.S. (cum laude) in Telecommunication Engineering at University of Siena. Thesis dissertation: "Green’s Functions for phased arrays of dipoles on dielectric slab" (supervisors: Prof. S. Maci, Prof. R. Tiberio, Prof. A. Toccafondi). <br><br><br />
* January 2000: national qualification for engineers at the University of Florence. <br><br><br />
* March 2003: PhD in Information Engineering (curriculum: electromagnetic waves) at the University of Siena. Thesis dissertation: "Frequency Domain Green's Function for Periodic Large Phased Arrays in Multilayered Dielectric Regions " (tutor: Prof. R. Tiberio). <br><br><br />
* January 2003-October 2006: post-doc researcher at the Department of Information Engineering, University of Siena<br><br><br />
<br />
===PRESENT EMPLOYMENT===<br />
* November 2006: Assistant Professor at the School of Engineering of University of Modena and Reggio Emilia (scientific area: ELECTROMAGNETIC FIELDS)<br />
<br />
* November 2009: tenure track as Assistant Professor at the School of Engineering of University of Modena and Reggio Emilia (scientific area: ELECTROMAGNETIC FIELDS)<br />
<br />
===RESEARCH INTERESTS===<br />
* High frequency scattering theories<br><br />
* Asymptotics electromagnetic methods<br><br />
* Numerical electromagnetic methods<br><br />
* Periodic structures<br><br />
* Bandgap structures<br><br />
* Antenna design<br><br />
* Antenna miniaturization<br><br />
* Wideband and ultrawideband antennas<br><br />
* RFID systems<br><br />
* Printed devices at microwave frequencies<br><br />
* New emerging waveguides<br><br />
* Metamaterials <br><br />
* Polaritons at optical frequency<br><br />
Further details in [[Research Activity]] section. <br><br><br />
<br />
===PROFESSIONAL SOCIETIES===<br />
* 1999, appointed to the profession of Engineer <br><br><br />
* 2000, Member of the Institute of Electrical and Electronic Engineers (IEEE) <br><br><br />
* September 2003-December 2005, president of the academic spin-off company WaveComm srl.<br><br><br />
* 2006, Italian Student Adviser for the Institution of Engineering and Technology (IET) <br><br><br />
<br><br><br />
<br />
===SOFTWARE SKILLS AND COMPETENCE===<br />
* Operating systems MS Windows 98/NT/2k/XP/Vista <br><br />
* MS Office<br><br />
* Maltlab<br><br />
* CorelDraw<br><br />
* Latex<br><br />
* Fortran<br><br />
* C<br><br />
* Mathematica<br><br />
* Electromagnetic simulation software<br><br />
** Ansoft Designer<br><br />
** HFSS<br><br />
** CST Microwave Studio<br><br />
** Grasp<br><br />
** FEKO<br><br />
** MicroWave Office<br><br />
** Wipl-d<br><br><br />
<br />
===TEACHING ACTIVITY===<br />
* 1999/2000, seminars in the Electromagnetic Field course at the School of Engineering of University of Siena <br><br />
* 2000/2001, seminars in the Microwave course at the School of Engineering of University of Siena <br><br />
* 2001/2002, seminars in the Antennas course at the School of Engineering of University of Siena <br><br />
* 2002/2003, course of Design of Microwave Circuits at the School of Engineering of University of Siena <br><br />
* 2003, course of Numerical Methods for Electromagnetics at the Master on Microwave Systems on Technologies for Telecommunications, Messina (Italy) <br><br />
* 2003/2004 and 2004/2005, course of Electromagnetic Modelling at the School of Engineering of University of Siena <br><br />
* 2005, seminars into the school “High Frequency Methods and Travelling Wave Antennas”, European School of Antennas (ACE – Antenna Centre of Excellence), at University of Siena, about:<br><br />
** Green’s function of the dielectric slab<br> <br />
** Scattering from a perfectly conducting half-plane<br><br><br />
* Since 2005: <br><br />
** course of Radio Propagation class at the School of Engineering of University of Modena and Reggio Emilia<br><br />
** assisting in the Electromagnetic Field class at the School of Engineering of University of Modena and Reggio Emilia<br><br />
** Microwave Lab class at the School of Engineering of University of Modena and Reggio Emilia<br><br><br />
<br />
Visit the page [[Teaching Activity]] for Teaching Statement . <br><br><br />
<br />
===STUDENT SUPERVISED===<br />
* 2001 M.S. "Giacomo Donzelli", GENERALIZED PENCIL OF FUNCTION TECHNIQUE FOR MULTILAYERED PRINTED STRUCTURES<br><br />
* 2002 M.S. "Alberto Nencini", ASYMPTOTIC GREEN'S FUNCTION FOR A SECTORAL ARRAY OF ELEMENTARY SOURCES ON A DIELECTRIC SLAB<br> <br />
* 2005 M.S. "Giorgio Carluccio", EXTENSION OF THE INCREMENTAL THEORY OF DIFFRACTION TO COMPLEX SOURCES <br><br />
* 2006 M.S. "Michele Gravina", ANTENNA FOR BIOMEDICAL RFID APPLICATION<br><br />
* 2006 M.S. "Daniele Ciccarese", WIMAX: MAN WIRELESS TECHNOLOGY <br><br />
* 2007 M.S. "Guido Santamaria", ELECTROMAGNETIC CHARACTERIZATION OF TRANSITIONS BETWEEN COAXIAL CABLE AND MICROSTRIP<br><br />
* 2007 M.S. "Lorenzo Santunione", DESIGN AND CHARACTERIZATION OF A PRINTED DIPOLE ANTENNA WITH UNBALNCED FEEDING<br><br />
* 2007 Laurea Degree. "Enrico Busi", ANALYSIS AND DESIGN OF A PLANAR ANTENNA FOR UWB APPLICATIONS<br><br />
* 2008 M.S. "Marcello di Clemente", SAW SENSORS<br><br />
* 2008 Laurea Degree. "Gagliardi Giuseppina", WIDE BAND PATCH ANTENNAS DESIGN<br><br />
* 2008 M.S. "Javier Molejón Asenjo", DESIGN OF A DUAL BAND ANTENNA FOR RFID APPLICATIONS IN THE UHF BAND <br><br />
* 2009 M.S. "Luca Morandini", DEVICES FOR THE MONITORING OF ELECTROMAGNETIC INTERFERENCES DURING TIMING IN SPORT RACES, THROUGHOUT RFID SYSTEMS<br><br />
* 2009 M.S. "Erio Gandini", ANALYSIS OF BACKSCATTERING FROM PLANAR FRESNEL LENSES<br><br><br />
<br />
===ATTENDED SPECIALIZED PHD COURSES===<br />
* 2000, at University of Siena <br><br />
** Functional analysis elements <br><br />
** Interpolation and approximation of curves and surfaces <br> <br />
** Optimization Methods <br><br />
** Wavelets <br><br />
** Object Oriented Programming <br><br />
* 2002, at Chalmers University, Gotheborg, Sweden <br><br />
** Artificial Magnetic Conductors and Soft and Hard surfaces and their Use in Antenna Analysis and Design <br><br />
* 2002, at University of Ancona, PhD School <br><br />
** Ground Penetrating Radar <br><br />
*2005, at Denmark Technical University - Ticra, European School of Antennas (ACE - Antenna Center of Excellence) <br><br />
** Reflector antennas: analysis and design <br><br />
* 2005, at Politecnico of Turin, European School of Antennas (ACE - Antenna Center of Excellence) <br><br />
** Computational EM for antenna analysis <br><br />
* 2005, at University of Siena, European School of Antennas (ACE - Antenna Center of Excellence) <br><br />
** High Frequency Methods and Travelling Wave Antennas <br><br />
* 2006, at University of Dubrovnik, European School of Antennas (ACE - Antenna Center of Excellence) <br><br />
** Advanced Mathematics for Antenna Analysis <br><br><br />
<br />
===NATIONAL RESEARCH PROGRAMS===<br />
* 2000-2002. PAR (Piano d’Ateneo per la Ricerca) “Antenna installation for wireless communication systems”<br><br />
* 2000-2002. ASI (Italian Space Agency): “Reflectarrays for satellite applications” <br><br />
* 2003-2005. PRIN (Progetto di ricerca di interesse nazionale) “Electromagnetic models for analysis of passive reflectarrays”<br><br />
* 2005-2007. PRIN (Progetto di ricerca di interesse nazionale) “Microwave Radiometer for fire monitoring” <br><br><br />
<br />
===INTERNATIONAL RESEARCH PROGRAMS===<br />
* 2004-2005. ACE Antenna Centre of Excellence, V Framework Program, WP. 1.1.1 Integration, WP. 3.1.1 European School of Antennas<br><br />
* 2005-2006. ACE Antennas Centre of Excellence, VI Framework Program, WP. 3.1.1 European School of Antennas<br><br />
* 2005-2007. EAML European Antenna Modeling Library, contract with ESA-ESTEC n.18802/04/NL/JD, WP. 1.6.1.0 5S Green’s Function for stratified environment<br><br />
* 2009-ongoing. EAML European Antenna Modeling Library, TT&C Coverage in Complex Environments <br><br />
* 2009-ongoing. EuroStar Project, New production process for medical bags based on RadioFrequency sterilization and ICT<br><br><br />
<br />
===RESEARCH CONTRACTS===<br />
* 2000-2001. Research contract between Department of Information Engineering (University of Siena) - IDS spa, in the framework of the agreement with Italian Navy for "Electromagnetic models for prediction of scattering objects" <br><br />
* 2000-2002. Research contract Department of Information Engineering (University of Siena) - IDS spa, in the framework of the agreement with IDS spa for "Green’s function for multilayered materials"<br><br />
* 2002-2003. Research contract Department of Information Engineering (University of Siena) - IDS spa, in the framework of the agreement with IDS spa for "Incremental Theory of Diffraction for dielectric screens"<br> <br />
* 2003-2004. Research contract with Consorzio Etruria ed Innovazione scpa, entitled "Feasibility and design of an automatic identification system on controlled areas based on the standard ISO/IEC 15693" <br><br />
* 2004-2005. Research contract with Consorzio Etruria ed Innovazione scpa, entitled "Electromagnetic scattering from non perfectly conducting half-planes and junctions between planes: UTD and ITD formulation" <br><br />
* 2005-2006. Research contract Department of Information Engineering (University of Siena) - IDS spa, in the framework of the agreement with IDS spa for "Green’s functions for dielectric multilayers; extension to magnetic sources" <br><br />
* 2007-2008. Research contract Department of Information Engineering (University of Modena and Reggio Emilia) -Politecnico di Torino, entitled "Evolution and evolutionary maintenance of European Antenna Modeling Library Components" <br><br />
* 2008. Research contract Department of Information Engineering (University of Modena and Reggio Emilia) –MD-Microdetectors (protected by NDA) <br> <br><br />
<br />
===PUBLICATIONS===<br />
[http://www.dii.unimo.it/wiki/index.php/My_publications Publications]<br />
<br />
<br />
<br><br><br><br />
[[Image:home.gif|30px|left]] <br><br />
[[User:Apolemi | Home]]</div>Apolemihttps://web.ing.unimo.it/wiki/index.php?title=My_Curriculum_Vitae&diff=7403My Curriculum Vitae2010-06-18T23:20:22Z<p>Apolemi: /* PERSONAL INFORMATION */</p>
<hr />
<div>'''(LAST UPDATE: 07/12/2009)'''<br><br />
<br />
===PERSONAL INFORMATION===<br />
[[Office address:]] <br><br />
Department of Information Engineering <br><br />
University of Modena and Reggio Emilia <br><br />
Via Vignolese 905<br><br />
41100 Modena, ITALY<br><br />
Tel. +39 059 2056326<br><br />
Fax. +39 059 2056129<br><br />
Mobile: +39 335 7181823<br><br />
E-mail: [mailto:alessia.polemi@unimore.it alessia.polemi@unimore.it]<br><br />
web-site: http://www.dii.unimore.it/polemi<br><br />
[[Home address:]] <br><br />
Via San Faustino 123/10<br><br />
41100 Modena,ITALY<br><br><br />
<br />
===EDUCATION===<br />
* July 1999: M.S. (cum laude) in Telecommunication Engineering at University of Siena. Thesis dissertation: "Green’s Functions for phased arrays of dipoles on dielectric slab" (supervisors: Prof. S. Maci, Prof. R. Tiberio, Prof. A. Toccafondi). <br><br><br />
* January 2000: national qualification for engineers at the University of Florence. <br><br><br />
* March 2003: PhD in Information Engineering (curriculum: electromagnetic waves) at the University of Siena. Thesis dissertation: "Frequency Domain Green's Function for Periodic Large Phased Arrays in Multilayered Dielectric Regions " (tutor: Prof. R. Tiberio). <br><br><br />
* January 2003-October 2006: post-doc researcher at the Department of Information Engineering, University of Siena<br><br><br />
<br />
===PRESENT EMPLOYMENT===<br />
* November 2006: Assistant Professor at the School of Engineering of University of Modena and Reggio Emilia (scientific area: ELECTROMAGNETIC FIELDS)<br />
<br />
* November 2009: tenure track as Assistant Professor at the School of Engineering of University of Modena and Reggio Emilia (scientific area: ELECTROMAGNETIC FIELDS)<br />
<br />
===RESEARCH INTERESTS===<br />
* High frequency scattering theories<br><br />
* Asymptotics electromagnetic methods<br><br />
* Numerical electromagnetic methods<br><br />
* Periodic structures<br><br />
* Bandgap structures<br><br />
* Antenna design<br><br />
* Antenna miniaturization<br><br />
* Wideband and ultrawideband antennas<br><br />
* RFID systems<br><br />
* Printed devices at microwave frequencies<br><br />
* New emerging waveguides<br><br />
* Metamaterials <br><br />
* Polaritons at optical frequency<br><br />
Further details in [[Research Activity]] section. <br><br><br />
<br />
===PROFESSIONAL SOCIETIES===<br />
* 1999, appointed to the profession of Engineer <br><br><br />
* 2000, Member of the Institute of Electrical and Electronic Engineers (IEEE) <br><br><br />
* September 2003-December 2005, president of the academic spin-off company WaveComm srl.<br><br><br />
* 2006, Italian Student Adviser for the Institution of Engineering and Technology (IET) <br><br><br />
<br><br><br />
<br />
===SOFTWARE SKILLS AND COMPETENCE===<br />
* Operating systems MS Windows 98/NT/2k/XP/Vista <br><br />
* MS Office<br><br />
* Maltlab<br><br />
* CorelDraw<br><br />
* Latex<br><br />
* Fortran<br><br />
* C<br><br />
* Mathematica<br><br />
* Electromagnetic simulation software<br><br />
** Ansoft Designer<br><br />
** HFSS<br><br />
** CST Microwave Studio<br><br />
** Grasp<br><br />
** FEKO<br><br />
** MicroWave Office<br><br />
** Wipl-d<br><br><br />
<br />
===TEACHING ACTIVITY===<br />
* 1999/2000, seminars in the Electromagnetic Field course at the School of Engineering of University of Siena <br><br />
* 2000/2001, seminars in the Microwave course at the School of Engineering of University of Siena <br><br />
* 2001/2002, seminars in the Antennas course at the School of Engineering of University of Siena <br><br />
* 2002/2003, course of Design of Microwave Circuits at the School of Engineering of University of Siena <br><br />
* 2003, course of Numerical Methods for Electromagnetics at the Master on Microwave Systems on Technologies for Telecommunications, Messina (Italy) <br><br />
* 2003/2004 and 2004/2005, course of Electromagnetic Modelling at the School of Engineering of University of Siena <br><br />
* 2005, seminars into the school “High Frequency Methods and Travelling Wave Antennas”, European School of Antennas (ACE – Antenna Centre of Excellence), at University of Siena, about:<br><br />
** Green’s function of the dielectric slab<br> <br />
** Scattering from a perfectly conducting half-plane<br><br><br />
* Since 2005: <br><br />
** course of Radio Propagation class at the School of Engineering of University of Modena and Reggio Emilia<br><br />
** assisting in the Electromagnetic Field class at the School of Engineering of University of Modena and Reggio Emilia<br><br />
** Microwave Lab class at the School of Engineering of University of Modena and Reggio Emilia<br><br><br />
<br />
Visit the page [[Teaching Activity]] for Teaching Statement . <br><br><br />
<br />
===STUDENT SUPERVISED===<br />
* 2001 M.S. "Giacomo Donzelli", GENERALIZED PENCIL OF FUNCTION TECHNIQUE FOR MULTILAYERED PRINTED STRUCTURES<br><br />
* 2002 M.S. "Alberto Nencini", ASYMPTOTIC GREEN'S FUNCTION FOR A SECTORAL ARRAY OF ELEMENTARY SOURCES ON A DIELECTRIC SLAB<br> <br />
* 2005 M.S. "Giorgio Carluccio", EXTENSION OF THE INCREMENTAL THEORY OF DIFFRACTION TO COMPLEX SOURCES <br><br />
* 2006 M.S. "Michele Gravina", ANTENNA FOR BIOMEDICAL RFID APPLICATION<br><br />
* 2006 M.S. "Daniele Ciccarese", WIMAX: MAN WIRELESS TECHNOLOGY <br><br />
* 2007 M.S. "Guido Santamaria", ELECTROMAGNETIC CHARACTERIZATION OF TRANSITIONS BETWEEN COAXIAL CABLE AND MICROSTRIP<br><br />
* 2007 M.S. "Lorenzo Santunione", DESIGN AND CHARACTERIZATION OF A PRINTED DIPOLE ANTENNA WITH UNBALNCED FEEDING<br><br />
* 2007 Laurea Degree. "Enrico Busi", ANALYSIS AND DESIGN OF A PLANAR ANTENNA FOR UWB APPLICATIONS<br><br />
* 2008 M.S. "Marcello di Clemente", SAW SENSORS<br><br />
* 2008 Laurea Degree. "Gagliardi Giuseppina", WIDE BAND PATCH ANTENNAS DESIGN<br><br />
* 2008 M.S. "Javier Molejón Asenjo", DESIGN OF A DUAL BAND ANTENNA FOR RFID APPLICATIONS IN THE UHF BAND <br><br />
* 2009 M.S. "Luca Morandini", DEVICES FOR THE MONITORING OF ELECTROMAGNETIC INTERFERENCES DURING TIMING IN SPORT RACES, THROUGHOUT RFID SYSTEMS<br><br />
* 2009 M.S. "Erio Gandini", ANALYSIS OF BACKSCATTERING FROM PLANAR FRESNEL LENSES<br><br><br />
<br />
===ATTENDED SPECIALIZED PHD COURSES===<br />
* 2000, at University of Siena <br><br />
** Functional analysis elements <br><br />
** Interpolation and approximation of curves and surfaces <br> <br />
** Optimization Methods <br><br />
** Wavelets <br><br />
** Object Oriented Programming <br><br />
* 2002, at Chalmers University, Gotheborg, Sweden <br><br />
** Artificial Magnetic Conductors and Soft and Hard surfaces and their Use in Antenna Analysis and Design <br><br />
* 2002, at University of Ancona, PhD School <br><br />
** Ground Penetrating Radar <br><br />
*2005, at Denmark Technical University - Ticra, European School of Antennas (ACE - Antenna Center of Excellence) <br><br />
** Reflector antennas: analysis and design <br><br />
* 2005, at Politecnico of Turin, European School of Antennas (ACE - Antenna Center of Excellence) <br><br />
** Computational EM for antenna analysis <br><br />
* 2005, at University of Siena, European School of Antennas (ACE - Antenna Center of Excellence) <br><br />
** High Frequency Methods and Travelling Wave Antennas <br><br />
* 2006, at University of Dubrovnik, European School of Antennas (ACE - Antenna Center of Excellence) <br><br />
** Advanced Mathematics for Antenna Analysis <br><br><br />
<br />
===NATIONAL RESEARCH PROGRAMS===<br />
* 2000-2002. PAR (Piano d’Ateneo per la Ricerca) “Antenna installation for wireless communication systems”<br><br />
* 2000-2002. ASI (Italian Space Agency): “Reflectarrays for satellite applications” <br><br />
* 2003-2005. PRIN (Progetto di ricerca di interesse nazionale) “Electromagnetic models for analysis of passive reflectarrays”<br><br />
* 2005-2007. PRIN (Progetto di ricerca di interesse nazionale) “Microwave Radiometer for fire monitoring” <br><br><br />
<br />
===INTERNATIONAL RESEARCH PROGRAMS===<br />
* 2004-2005. ACE Antenna Centre of Excellence, V Framework Program, WP. 1.1.1 Integration, WP. 3.1.1 European School of Antennas<br><br />
* 2005-2006. ACE Antennas Centre of Excellence, VI Framework Program, WP. 3.1.1 European School of Antennas<br><br />
* 2005-2007. EAML European Antenna Modeling Library, contract with ESA-ESTEC n.18802/04/NL/JD, WP. 1.6.1.0 5S Green’s Function for stratified environment<br><br />
* 2009-ongoing. EAML European Antenna Modeling Library, TT&C Coverage in Complex Environments <br><br />
* 2009-ongoing. EuroStar Project, New production process for medical bags based on RadioFrequency sterilization and ICT<br><br><br />
<br />
===RESEARCH CONTRACTS===<br />
* 2000-2001. Research contract between Department of Information Engineering (University of Siena) - IDS spa, in the framework of the agreement with Italian Navy for "Electromagnetic models for prediction of scattering objects" <br><br />
* 2000-2002. Research contract Department of Information Engineering (University of Siena) - IDS spa, in the framework of the agreement with IDS spa for "Green’s function for multilayered materials"<br><br />
* 2002-2003. Research contract Department of Information Engineering (University of Siena) - IDS spa, in the framework of the agreement with IDS spa for "Incremental Theory of Diffraction for dielectric screens"<br> <br />
* 2003-2004. Research contract with Consorzio Etruria ed Innovazione scpa, entitled "Feasibility and design of an automatic identification system on controlled areas based on the standard ISO/IEC 15693" <br><br />
* 2004-2005. Research contract with Consorzio Etruria ed Innovazione scpa, entitled "Electromagnetic scattering from non perfectly conducting half-planes and junctions between planes: UTD and ITD formulation" <br><br />
* 2005-2006. Research contract Department of Information Engineering (University of Siena) - IDS spa, in the framework of the agreement with IDS spa for "Green’s functions for dielectric multilayers; extension to magnetic sources" <br><br />
* 2007-2008. Research contract Department of Information Engineering (University of Modena and Reggio Emilia) -Politecnico di Torino, entitled "Evolution and evolutionary maintenance of European Antenna Modeling Library Components" <br><br />
* 2008. Research contract Department of Information Engineering (University of Modena and Reggio Emilia) –MD-Microdetectors (protected by NDA) <br> <br><br />
<br />
===PUBLICATIONS===<br />
[http://www.dii.unimo.it/wiki/index.php/My_publications Publications]<br />
<br />
<br />
<br><br><br><br />
[[Image:home.gif|30px|left]] <br><br />
[[User:Apolemi | Home]]</div>Apolemihttps://web.ing.unimo.it/wiki/index.php?title=User:Apolemi&diff=7339User:Apolemi2010-04-29T20:40:56Z<p>Apolemi: </p>
<hr />
<div>[[Image:Alessia polemi.jpg|250px|left]] <br />
address: Dipartimento di Ingegneria dell'Informazione, via Vignolese 905, Modena, Italy, I-41125<br> <br />
tel: +39-059-2056326<br> <br />
fax: +39-059-2056129<br> <br />
email: [mailto:alessia.polemi@unimore.it alessia.polemi@unimore.it] <br> <br />
<br> <br />
Alessia Polemi was born in Casteldelpiano, Grosseto, Italy, on July 10, 1973. She received her Doctor of Engineering degree in Telecommunications Engineering(cum laude) from the [http://www.unisi.it University of Siena] in July 1999 discussing a thesis about the [http://lipari.ing.unimo.it/polemi/tesi.pdf Array Green's Function for a Semi-Infinite Array of Dipoles on a Grounded Slab.] <br />
<br />
From November 1999 to October 2002 she was a Ph.D student at the [http://www.dii.unisi.it Department of Information Engineering (DII)] of the University of Siena. She received a Ph.D. degree in Information Engineering in March 2003 with a thesis entitled [http://lipari.ing.unimo.it/polemi/phd_thesis.pdf Frequency-Domain Green’s Function for Planar Periodic Large Phased Arrays in Multilayered Dielectric Regions.]<br />
<br />
From January 2003 to October 2006 she was a post doctorate researcher at the Department of Information Engineering of the University of Siena. During the PhD and post-doc period she attended several different international PhD classes and European schools. <br />
<br />
She serves as a reviewer for important international journals on electrical engineering and electromagnetics such as IEEE, IET, Elsevier Journals and Transactions. <br />
<br />
Since November 2006 she has been an Assistant Professor of Electromagnetic Fields at the [http://www.ing.unimo.it School of Engineering,] within the [http://www.dii.unimo.it Department of Information Engineering] of the [http://www.unimo.it University of Modena and Reggio Emilia,] where she is teaching Radiopropagation and she is the assistant at the course on Electromagnetic Fields. <br />
<br />
Since 2008, she has been frequently a visiting professor at the [http://www.upenn.edu University of Pennsylvania], in Philadelphia, working on plasmonic structures with [http://www.ese.upenn.edu/~engheta Prof. Nader Engheta] and his group. <br />
<br />
Since 2000 she is member of the [http://www.ieee.org Institute of Electrical and Electronic Engineers (IEEE)] and since November 2006 she has been the Italian Student Adviser for the [http://www.iet.org Institution of Engineering and Technology (IET)]. <br />
<br />
In November 2009, she has obtained the tenure track as Assistant Professor at the [http://www.ing.unimo.it School of Engineering,] within the [http://www.dii.unimo.it Department of Information Engineering] of the [http://www.unimo.it University of Modena and Reggio Emilia].<br />
<br />
She is currently Research Scientist at Drexel University, Department of Chemistry, in the framework of a research program on local surface plasmon enhancement at optical frequency, with Prof. Kevin Shuford.<br />
<br />
Her current research includes high frequency scattering theories, asymptotics electromagnetic methods, numerical electromagnetic methods, periodic structures, bandgap structures, antenna design, antenna miniaturization, wideband and ultrawideband antennas, RFID systems, printed devices at microwave frequencies, new emerging waveguides, metamaterials and polaritons at optical frequency. For further details, see [[Research Activity]] section<br />
<br><br><br />
----<br />
* [[My Curriculum Vitae]] (and [[Media:CV_ALESSIA_POLEMI.pdf|pdf]] version) <br> <br> <br />
* [[Research Activity]] <br> <br><br />
* [[My publications]] <br> <br><br />
* [[Teaching Activity]] <br> <br><br />
* [[MATERIALE DIDATTICO]] <br><br><br />
----<br />
;[[Image:news.gif|120px]] [[News and Events]]<br />
----</div>Apolemihttps://web.ing.unimo.it/wiki/index.php?title=User:Apolemi&diff=7203User:Apolemi2010-02-04T03:12:56Z<p>Apolemi: </p>
<hr />
<div>[[Image:Alessia polemi.jpg|250px|left]] <br />
address: Dipartimento di Ingegneria dell'Informazione, via Vignolese 905, Modena, Italy, I-41125<br> <br />
tel: +39-059-2056326<br> <br />
fax: +39-059-2056129<br> <br />
email: [mailto:alessia.polemi@unimore.it alessia.polemi@unimore.it] <br> <br />
<br> <br />
Alessia Polemi was born in Casteldelpiano, Grosseto, Italy, on July 10, 1973. She received her Doctor of Engineering degree in Telecommunications Engineering(cum laude) from the [http://www.unisi.it University of Siena] in July 1999 discussing a thesis about the [http://lipari.ing.unimo.it/polemi/tesi.pdf Array Green's Function for a Semi-Infinite Array of Dipoles on a Grounded Slab.] <br />
<br />
From November 1999 to October 2002 she was a Ph.D student at the [http://www.dii.unisi.it Department of Information Engineering (DII)] of the University of Siena. She received a Ph.D. degree in Information Engineering in March 2003 with a thesis entitled [http://lipari.ing.unimo.it/polemi/phd_thesis.pdf Frequency-Domain Green’s Function for Planar Periodic Large Phased Arrays in Multilayered Dielectric Regions.]<br />
<br />
From January 2003 to October 2006 she was a post doctorate researcher at the Department of Information Engineering of the University of Siena. During the PhD and post-doc period she attended several different international PhD classes and European schools. <br />
<br />
She serves as a reviewer for important international journals on electrical engineering and electromagnetics such as IEEE, IET, Elsevier Journals and Transactions. <br />
<br />
Since November 2006 she has been an Assistant Professor of Electromagnetic Fields at the [http://www.ing.unimo.it School of Engineering,] within the [http://www.dii.unimo.it Department of Information Engineering] of the [http://www.unimo.it University of Modena and Reggio Emilia,] where she is teaching Radiopropagation and she is the assistant at the course on Electromagnetic Fields. <br />
<br />
Since 2008, she has been frequently a visiting professor at the [http://www.upenn.edu University of Pennsylvania], in Philadelphia, working on plasmonic structures with [http://www.ese.upenn.edu/~engheta Prof. Nader Engheta] and his group. <br />
<br />
Since 2000 she is member of the [http://www.ieee.org Institute of Electrical and Electronic Engineers (IEEE)] and since November 2006 she has been the Italian Student Adviser for the [http://www.iet.org Institution of Engineering and Technology (IET)]. <br />
<br />
In November 2009, she has obtained the tenure track as Assistant Professor at the [http://www.ing.unimo.it School of Engineering,] within the [http://www.dii.unimo.it Department of Information Engineering] of the [http://www.unimo.it University of Modena and Reggio Emilia].<br />
<br />
Her current research includes high frequency scattering theories, asymptotics electromagnetic methods, numerical electromagnetic methods, periodic structures, bandgap structures, antenna design, antenna miniaturization, wideband and ultrawideband antennas, RFID systems, printed devices at microwave frequencies, new emerging waveguides, metamaterials and polaritons at optical frequency. For further details, see [[Research Activity]] section<br />
<br><br><br />
----<br />
* [[My Curriculum Vitae]] (and [[Media:CV_ALESSIA_POLEMI.pdf|pdf]] version) <br> <br> <br />
* [[Research Activity]] <br> <br><br />
* [[My publications]] <br> <br><br />
* [[Teaching Activity]] <br> <br><br />
* [[MATERIALE DIDATTICO]] <br><br><br />
----<br />
;[[Image:news.gif|120px]] [[News and Events]]<br />
----</div>Apolemihttps://web.ing.unimo.it/wiki/index.php?title=User:Apolemi&diff=7202User:Apolemi2010-02-04T03:12:47Z<p>Apolemi: </p>
<hr />
<div>[[Image:Alessia polemi.jpg|200px|left]] <br />
address: Dipartimento di Ingegneria dell'Informazione, via Vignolese 905, Modena, Italy, I-41125<br> <br />
tel: +39-059-2056326<br> <br />
fax: +39-059-2056129<br> <br />
email: [mailto:alessia.polemi@unimore.it alessia.polemi@unimore.it] <br> <br />
<br> <br />
Alessia Polemi was born in Casteldelpiano, Grosseto, Italy, on July 10, 1973. She received her Doctor of Engineering degree in Telecommunications Engineering(cum laude) from the [http://www.unisi.it University of Siena] in July 1999 discussing a thesis about the [http://lipari.ing.unimo.it/polemi/tesi.pdf Array Green's Function for a Semi-Infinite Array of Dipoles on a Grounded Slab.] <br />
<br />
From November 1999 to October 2002 she was a Ph.D student at the [http://www.dii.unisi.it Department of Information Engineering (DII)] of the University of Siena. She received a Ph.D. degree in Information Engineering in March 2003 with a thesis entitled [http://lipari.ing.unimo.it/polemi/phd_thesis.pdf Frequency-Domain Green’s Function for Planar Periodic Large Phased Arrays in Multilayered Dielectric Regions.]<br />
<br />
From January 2003 to October 2006 she was a post doctorate researcher at the Department of Information Engineering of the University of Siena. During the PhD and post-doc period she attended several different international PhD classes and European schools. <br />
<br />
She serves as a reviewer for important international journals on electrical engineering and electromagnetics such as IEEE, IET, Elsevier Journals and Transactions. <br />
<br />
Since November 2006 she has been an Assistant Professor of Electromagnetic Fields at the [http://www.ing.unimo.it School of Engineering,] within the [http://www.dii.unimo.it Department of Information Engineering] of the [http://www.unimo.it University of Modena and Reggio Emilia,] where she is teaching Radiopropagation and she is the assistant at the course on Electromagnetic Fields. <br />
<br />
Since 2008, she has been frequently a visiting professor at the [http://www.upenn.edu University of Pennsylvania], in Philadelphia, working on plasmonic structures with [http://www.ese.upenn.edu/~engheta Prof. Nader Engheta] and his group. <br />
<br />
Since 2000 she is member of the [http://www.ieee.org Institute of Electrical and Electronic Engineers (IEEE)] and since November 2006 she has been the Italian Student Adviser for the [http://www.iet.org Institution of Engineering and Technology (IET)]. <br />
<br />
In November 2009, she has obtained the tenure track as Assistant Professor at the [http://www.ing.unimo.it School of Engineering,] within the [http://www.dii.unimo.it Department of Information Engineering] of the [http://www.unimo.it University of Modena and Reggio Emilia].<br />
<br />
Her current research includes high frequency scattering theories, asymptotics electromagnetic methods, numerical electromagnetic methods, periodic structures, bandgap structures, antenna design, antenna miniaturization, wideband and ultrawideband antennas, RFID systems, printed devices at microwave frequencies, new emerging waveguides, metamaterials and polaritons at optical frequency. For further details, see [[Research Activity]] section<br />
<br><br><br />
----<br />
* [[My Curriculum Vitae]] (and [[Media:CV_ALESSIA_POLEMI.pdf|pdf]] version) <br> <br> <br />
* [[Research Activity]] <br> <br><br />
* [[My publications]] <br> <br><br />
* [[Teaching Activity]] <br> <br><br />
* [[MATERIALE DIDATTICO]] <br><br><br />
----<br />
;[[Image:news.gif|120px]] [[News and Events]]<br />
----</div>Apolemihttps://web.ing.unimo.it/wiki/index.php?title=User:Apolemi&diff=7201User:Apolemi2010-02-04T03:11:45Z<p>Apolemi: </p>
<hr />
<div>[[Image:Alessia polemi.jpg|180px|left]] <br />
address: Dipartimento di Ingegneria dell'Informazione, via Vignolese 905, Modena, Italy, I-41125<br> <br />
tel: +39-059-2056326<br> <br />
fax: +39-059-2056129<br> <br />
email: [mailto:alessia.polemi@unimore.it alessia.polemi@unimore.it] <br> <br />
<br> <br />
Alessia Polemi was born in Casteldelpiano, Grosseto, Italy, on July 10, 1973. She received her Doctor of Engineering degree in Telecommunications Engineering(cum laude) from the [http://www.unisi.it University of Siena] in July 1999 discussing a thesis about the [http://lipari.ing.unimo.it/polemi/tesi.pdf Array Green's Function for a Semi-Infinite Array of Dipoles on a Grounded Slab.] <br />
<br />
From November 1999 to October 2002 she was a Ph.D student at the [http://www.dii.unisi.it Department of Information Engineering (DII)] of the University of Siena. She received a Ph.D. degree in Information Engineering in March 2003 with a thesis entitled [http://lipari.ing.unimo.it/polemi/phd_thesis.pdf Frequency-Domain Green’s Function for Planar Periodic Large Phased Arrays in Multilayered Dielectric Regions.]<br />
<br />
From January 2003 to October 2006 she was a post doctorate researcher at the Department of Information Engineering of the University of Siena. During the PhD and post-doc period she attended several different international PhD classes and European schools. <br />
<br />
She serves as a reviewer for important international journals on electrical engineering and electromagnetics such as IEEE, IET, Elsevier Journals and Transactions. <br />
<br />
Since November 2006 she has been an Assistant Professor of Electromagnetic Fields at the [http://www.ing.unimo.it School of Engineering,] within the [http://www.dii.unimo.it Department of Information Engineering] of the [http://www.unimo.it University of Modena and Reggio Emilia,] where she is teaching Radiopropagation and she is the assistant at the course on Electromagnetic Fields. <br />
<br />
Since 2008, she has been frequently a visiting professor at the [http://www.upenn.edu University of Pennsylvania], in Philadelphia, working on plasmonic structures with [http://www.ese.upenn.edu/~engheta Prof. Nader Engheta] and his group. <br />
<br />
Since 2000 she is member of the [http://www.ieee.org Institute of Electrical and Electronic Engineers (IEEE)] and since November 2006 she has been the Italian Student Adviser for the [http://www.iet.org Institution of Engineering and Technology (IET)]. <br />
<br />
In November 2009, she has obtained the tenure track as Assistant Professor at the [http://www.ing.unimo.it School of Engineering,] within the [http://www.dii.unimo.it Department of Information Engineering] of the [http://www.unimo.it University of Modena and Reggio Emilia].<br />
<br />
Her current research includes high frequency scattering theories, asymptotics electromagnetic methods, numerical electromagnetic methods, periodic structures, bandgap structures, antenna design, antenna miniaturization, wideband and ultrawideband antennas, RFID systems, printed devices at microwave frequencies, new emerging waveguides, metamaterials and polaritons at optical frequency. For further details, see [[Research Activity]] section<br />
<br><br><br />
----<br />
* [[My Curriculum Vitae]] (and [[Media:CV_ALESSIA_POLEMI.pdf|pdf]] version) <br> <br> <br />
* [[Research Activity]] <br> <br><br />
* [[My publications]] <br> <br><br />
* [[Teaching Activity]] <br> <br><br />
* [[MATERIALE DIDATTICO]] <br><br><br />
----<br />
;[[Image:news.gif|120px]] [[News and Events]]<br />
----</div>Apolemihttps://web.ing.unimo.it/wiki/index.php?title=File:Alessia_polemi.jpg&diff=7200File:Alessia polemi.jpg2010-02-04T03:10:36Z<p>Apolemi: </p>
<hr />
<div></div>Apolemihttps://web.ing.unimo.it/wiki/index.php?title=News_and_Events&diff=7098News and Events2010-01-09T17:23:34Z<p>Apolemi: </p>
<hr />
<div>== EVENTS ==<br />
<br />
<br />
== NEWS ==<br />
<br />
- I will be working as Research Scientist at the Department of Chemistry (Drexel University - Philadelphia) in 2010. For any communication, please contact me at my email address.<br><br />
<br />
== PAST ANNOUNCEMENTS ==<br />
<br />
- Seminario '''Tecnologia RFID: introduzione e applicazioni''' nell'ambito del corso Sistemi Radio e a Microonde e del corso di Radiopropagazione. Partecipazione dei gruppi di ricerca di informatica ed elettronica. '''Venerdì 4 Dicembre, ore 14.30-17.00, Facoltà di Ingegneria, Modena, aula FA-2G'''. Scarica la locandina [[Media:RFID_UniMoRe_v2.0.pdf| flyer]]. Le presentazioni relative all'evento sono disponibili:<br><br />
<br />
[[Media: LA_TECNOLOGIA_RFID.pdf| Introduzione alla tecnologia RFID]] Prof. Alessia Polemi, Courtesy of Prof. Gaetano Marrocco, University of Roma, Tor Vergata<br><br><br />
[[Media:Rfid041209.pdf| RFID nel monitoraggio di cantieri]], Prof. Andrea Prati<br><br><br />
[[Media:EHRF@INGREshort.pdf| Tecniche di Energy Harvesting]], Prof. Alessandro Bertacchini<br><br><br />
<br />
- LE LEZIONI DI RADIOPROPAGAZIONE INIZIERANNO IL GIORNO MARTEDì 17 NOVEMBRE P.V.<br />
<br><br />
<br />
- The student Erio Gandini has been selected for the Phd program at the [http://www.univ-rennes1.fr/ University of Rennes], starting from October 2009, in the framework of a joint project between IETr and Thalès Alenia Space (TAS).<br><br />
<br />
<br />
- Collaboration with [http://www.ese.upenn.edu/ Electric and System Engineering Department] at [http://www.upenn.edu/ University of Pennsylvania] with Prof. Nader Engheta, within metamaterials and nanotechnologies at optical frequencies.<br><br><br />
<br />
- Collaboration with [http://www.esa.int/ European Space Agency] for the realization of an electromagnetic tool for beam tracing in complex environments, such as satellite platforms.<br><br><br />
<br />
- Collaboration with [http://www.univ-rennes1.fr/ University of Rennes] in the framework of an european Research Network Program (RNP) on "New frontiers in millimetre / sub-millimetre waves integrated dielectric focusing systems".<br><br><br />
<br />
<br />
<br><br><br><br />
[[Image:home.gif|30px|left]] <br><br />
[[User:Apolemi | Home]]</div>Apolemihttps://web.ing.unimo.it/wiki/index.php?title=News_and_Events&diff=7074News and Events2009-12-27T21:05:43Z<p>Apolemi: /* NEWS */</p>
<hr />
<div>== EVENTS ==<br />
<br />
<br />
== NEWS ==<br />
<br />
- Seminario '''Tecnologia RFID: introduzione e applicazioni''' nell'ambito del corso Sistemi Radio e a Microonde e del corso di Radiopropagazione. Partecipazione dei gruppi di ricerca di informatica ed elettronica. '''Venerdì 4 Dicembre, ore 14.30-17.00, Facoltà di Ingegneria, Modena, aula FA-2G'''. Scarica la locandina [[Media:RFID_UniMoRe_v2.0.pdf| flyer]]. Le presentazioni relative all'evento sono disponibili:<br><br />
<br />
[[Media: LA_TECNOLOGIA_RFID.pdf| Introduzione alla tecnologia RFID]] Prof. Alessia Polemi, Courtesy of Prof. Gaetano Marrocco, University of Roma, Tor Vergata<br><br><br />
[[Media:Rfid041209.pdf| RFID nel monitoraggio di cantieri]], Prof. Andrea Prati<br><br><br />
[[Media:EHRF@INGREshort.pdf| Tecniche di Energy Harvesting]], Prof. Alessandro Bertacchini<br><br><br />
<br />
- LE LEZIONI DI RADIOPROPAGAZIONE INIZIERANNO IL GIORNO MARTEDì 17 NOVEMBRE P.V.<br />
<br><br />
<br />
- I will be visiting the Department of Electric and System Engineering at University of Pennsylvania from Oct 1st to Nov 6th. For any communication, please contact me at my email address.<br><br />
<br />
- The student Erio Gandini has been selected for the Phd program at the [http://www.univ-rennes1.fr/ University of Rennes], starting from October 2009, in the framework of a joint project between IETr and Thalès Alenia Space (TAS).<br><br />
<br />
<br />
- Collaboration with [http://www.ese.upenn.edu/ Electric and System Engineering Department] at [http://www.upenn.edu/ University of Pennsylvania] with Prof. Nader Engheta, within metamaterials and nanotechnologies at optical frequencies.<br><br><br />
<br />
- Collaboration with [http://www.esa.int/ European Space Agency] for the realization of an electromagnetic tool for beam tracing in complex environments, such as satellite platforms.<br><br><br />
<br />
- Collaboration with [http://www.univ-rennes1.fr/ University of Rennes] in the framework of an european Research Network Program (RNP) on "New frontiers in millimetre / sub-millimetre waves integrated dielectric focusing systems".<br><br><br />
<br />
<br />
<br><br><br><br />
[[Image:home.gif|30px|left]] <br><br />
[[User:Apolemi | Home]]</div>Apolemihttps://web.ing.unimo.it/wiki/index.php?title=MATERIALE_DIDATTICO&diff=7073MATERIALE DIDATTICO2009-12-27T21:05:23Z<p>Apolemi: /* RADIOPROPAGAZIONE e SISTEMI RADIO E A MICROONDE */</p>
<hr />
<div>== RADIOPROPAGAZIONE e SISTEMI RADIO E A MICROONDE<br>==<br />
Il corso RADIOPROPAGAZIONE si ripropone di offrire allo studente tutto il bagaglio di conoscenze e informazioni connesse con il collegamento radio tra due o più utenti in un ambiente reale. A tal fine vengono ampiamente descritti i parametri fondamentali delle antenne, con particolare attenzione a quelle grandezze necessarie per caratterizzare il collegamento radio tra due punti. Con riferimento alle antenne usate nelle applicazioni wireless, vengono descritti i principi fondamentali per l'analisi ed il design delle antenna a microstriscia. A questo argomento è collegata una attività di laboratorio, che permette allo studente di imparare le principale tecniche di progetto delle antenne a microstriscia attraverso softwares commerciali. Mentre, con riferimento alle antenne usate nelle moderne applicazioni contactless, vengono descritti i principi fondamentali di funzionamento dei sistemi di identificazione a radiofrequenza (RFID). Infine il corso offre una ampia e dettagliata panoramica sulla caratterizzazione del canale radio, con riferimento sia al canale urbano (descrizione di modelli empirici, statistici e deterministici) sia alla propagazione Line-Of-Sight e ionosferica. <br>Il programma del corso è il seguente<br><br />
*Introduzione al corso<br />
*Richiami alle grandezze fondamentali delle antenne<br />
**Antenne in trasmissione: diagramma di radiazione, direttività e guadagno, impedenza di radiazione, efficienza <br />
**Antenne in ricezione: area efficace, formula di Friis del collegamento, rapporto segnale rumore <br />
*Antenne ad apertura <br />
**Richiami sulla trasformata di Fourier<br />
**Radiazione da aperture planari: l'apertura rettangolare e circolare, aperture con distribuzione di campo uniforme e non uniforme, radiazione di una slot <br />
*Antenne per applicazioni wireless <br />
**Antenne a patch <br />
***Caratteristiche generali <br />
***Tecniche di alimentazione <br />
***Tecniche di allargamento della banda <br />
***Uso di software CAD di simulazione elettromagnetica per il design di antenne a patch<br />
**Antenne ad array<br />
***Principi generali<br />
***Array broadside<br />
***Array endfire<br />
***Tecniche di alimentazione<br />
**Antenna a riflettore<br />
***Generalità<br />
***Riflettori parabolici (prime focus)<br />
***Riflettori offset e Cassegrain: cenni<br />
**Antenne horn<br />
***Principi di funzionamento<br />
***Distribuzione di apertura<br />
**Antenne e sistemi contactless short distance e very short distance: cenni sui sistemi di Radio Identificazione a Radio Frequenza (RFID) <br />
*Propagazione <br />
**Il canale urbano<br />
***Cenni sui metodi di descrizione dei meccanismi di propagazione: modelli empirici, statistici, e deterministici <br />
**Propagazione Line-of-Sight e interferenza per onda riflessa <br />
**Propagazione per onda di superficiale<br />
**Propagazione ionosferica <br><br><br />
I contenuti di questo corso sono gli stessi della seconda parte di SISTEMI RADIO E A MICROONDE. Per quanto riguarda la prima parte, rivolgersi al Prof. Luca Vincetti.<br><br><br />
<br />
<br />
TESTI CONSIGLIATI:<br><br><br />
<br />
Constantine A. Balanis, "Antenna Theory: Analysis and Design," John Wiley & Sons Inc., 1982 (1st ed.), 1997(2nd ed.)<br />
<br />
Constantine A. Balanis, "Advanced Engineering Electromagnetics", John Wiley & Sons Inc., 1989<br />
<br />
Robert E. Collin, "Antennas and RadioWave Propagation," McGraw-Hill Series in Electrical Engineering, 1985<br />
<br />
Sergei Alexander Schelkunoff, "Advanced antenna theory," 1952<br />
<br />
Lal C. Godara, "Handbook of Antennas in Wireless Communication," CRC Press, 2002<br />
<br />
R. Garg, P. Bhartia, I. Bahal, A. Ittipiboon , "Microstrip Antenna Design Handbook," Artech House, 2000<br />
<br />
Stutzman, Thiele, "Antenna Theory and Design," John Wiley & Sons Inc., 1981<br />
<br />
<br />
[[Image:logo148x154.gif|50 px]] [http://lipari.ing.unimo.it/polemi/radio/frequencies.pdf Spettro frequenze onde radio]<br><br><br />
[[Image:chip.jpg|90 px]] [http://lipari.ing.unimo.it/polemi/radio/dielettrici.pdf Materiali dielettrici]<br><br><br />
;[[Image:patch.gif|150 px]] Introduzione al software CST MicroWave Studio<br><br><br />
:[http://lipari.ing.unimo.it/polemi/Radio/introCST1.pdf Introduzione Laboratorio 1]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/Radio/introCST2.pdf Introduzione Laboratorio 2]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/Radio/introCST4.pdf Introduzione Laboratorio 3]<br><br><br />
;[[Image:rfid.jpg|50 px]] Tecnologie emergenti...<br><br><br />
[[Media: LA_TECNOLOGIA_RFID.pdf| Introduzione alla tecnologia RFID]] Prof. Alessia Polemi, Courtesy of Prof. Gaetano Marrocco, University of Roma, Tor Vergata<br><br><br />
<br />
== MICROONDE<br> ==<br />
Per informazioni sul corso rivolgersi al titolare Prof. Vincetti<br><br><br />
;[[Image:microonde.jpg|90 px]] Introduzione al software CST MicroWave Studio<br><br><br />
:[http://lipari.ing.unimo.it/polemi/Micro/introCST1.pdf Intro CST 1]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/Micro/introCST2.pdf Intro CST 2]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/Micro/introCST3.pdf Intro CST 3]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/Micro/esempiodirelazione.pdf Esempio di relazione]<br><br><br />
<br />
<br />
== CAMPI ELETTROMAGNETICI B <br>==<br />
Per informazioni sul corso rivolgersi al titolare Prof. Zoboli<br><br><br />
;[[Image:dipoletto.jpg|30 px]] Radiazione<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_B/antennas1.pdf Antenna1]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_B/dipoleAnt.html Antenna2]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_B/dipoleAnt2.html Antenna3]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_B/laboratorio2008/CEMB.ppt Concetti di base sulle antenne filari]<br><br><br />
<br />
<br />
;[[Image:ospiti.gif|50px]] Testi d'esame<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_B/CB070626.pdf 26 giugno 2007]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_B/CB070717.pdf 17 luglio 2007]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_B/CB070911.pdf 11 settembre 2007]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_B/CB070928.pdf 28 settembre 2007]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_B/CB071219.pdf 19 dicembre 2007]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_B/CB080328.pdf 28 marzo 2008]<br><br><br />
:[[Media:CB080620.pdf|20 giugno 2008]];<br><br><br />
:[[Media:CB080717.pdf|17 luglio 2008]];<br><br><br />
:[[Media:CB_08-09-09.pdf|9 settembre 2008]];<br><br><br />
:[[Media:CB_09-03-18.pdf|18 marzo 2009]];<br><br><br />
:[[Media:CB090624.pdf|24 giugno 2009]];<br><br><br />
:[[Media:CB090715.pdf|15 luglio 2009]];<br><br><br />
:[[Media:CB090916.pdf|16 settembre 2009]];<br><br><br />
<br />
:[http://lipari.ing.unimo.it/vincetti/es_campi_B.html Precedenti Anni Accademici]<br />
<br />
== CAMPI ELETTROMAGNETICI A <br>==<br />
Per informazioni sul corso rivolgersi al titolare Prof. Zoboli<br><br><br />
;[[Image:dipoletto.jpg|30 px]] Linee di Trasmissione<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_A/smithchart.pdf Carta di Smith]<br><br><br />
<br />
<br />
;[[Image:ospiti.gif|50px]] Testi d'esame<br><br>:<br />
:[http://lipari.ing.unimo.it/polemi/CEM_A/20070321CEMA1.pdf 21 marzo 2007 (A)];[http://lipari.ing.unimo.it/polemi/CEM_A/20070321CEMA2.pdf 21 marzo 2007 (B)]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_A/20070412CEMA1.pdf 12 aprile 2007 (A)];[http://lipari.ing.unimo.it/polemi/CEM_A/20070412CEMA2.pdf 12 aprile 2007 (B)]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_A/20070626CEMA.pdf 26 giugno 2007]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_A/20070911CEMA.pdf 11 settembre 2007]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_A/20070928CEMA.pdf 28 settembre 2007]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_A/20071219CEMA.pdf 19 dicembre 2007]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_A/20080314CEMA.pdf 14 marzo 2008];<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_A/20080328CEMA.pdf 28 marzo 2008];<br><br><br />
:[[Media:20080620CEMA.pdf|20 giugno 2008]];<br><br><br />
:[[Media:2008_09_09_CEM_A.pdf|9 settembre 2008]];<br><br><br />
:[[Media:2009_03_18_CEM_A.pdf|18 marzo 2009]];<br><br><br />
:[[Media:20090624CEM_A.pdf|24 giugno 2009]];<br><br><br />
:[[Media:20090916CEM_A.pdf|16 settembre 2009]];<br><br><br />
<br />
:[http://lipari.ing.unimo.it/vincetti/es_campi_A.html Precedenti Anni Accademici]<br />
<br />
<br />
<br />
<br><br><br><br />
[[Image:home.gif|30px|left]] <br><br />
[[User:Apolemi | Home]]</div>Apolemihttps://web.ing.unimo.it/wiki/index.php?title=MATERIALE_DIDATTICO&diff=7072MATERIALE DIDATTICO2009-12-27T21:04:35Z<p>Apolemi: /* RADIOPROPAGAZIONE e SISTEMI RADIO E A MICROONDE */</p>
<hr />
<div>== RADIOPROPAGAZIONE e SISTEMI RADIO E A MICROONDE<br>==<br />
Il corso RADIOPROPAGAZIONE si ripropone di offrire allo studente tutto il bagaglio di conoscenze e informazioni connesse con il collegamento radio tra due o più utenti in un ambiente reale. A tal fine vengono ampiamente descritti i parametri fondamentali delle antenne, con particolare attenzione a quelle grandezze necessarie per caratterizzare il collegamento radio tra due punti. Con riferimento alle antenne usate nelle applicazioni wireless, vengono descritti i principi fondamentali per l'analisi ed il design delle antenna a microstriscia. A questo argomento è collegata una attività di laboratorio, che permette allo studente di imparare le principale tecniche di progetto delle antenne a microstriscia attraverso softwares commerciali. Mentre, con riferimento alle antenne usate nelle moderne applicazioni contactless, vengono descritti i principi fondamentali di funzionamento dei sistemi di identificazione a radiofrequenza (RFID). Infine il corso offre una ampia e dettagliata panoramica sulla caratterizzazione del canale radio, con riferimento sia al canale urbano (descrizione di modelli empirici, statistici e deterministici) sia alla propagazione Line-Of-Sight e ionosferica. <br>Il programma del corso è il seguente<br><br />
*Introduzione al corso<br />
*Richiami alle grandezze fondamentali delle antenne<br />
**Antenne in trasmissione: diagramma di radiazione, direttività e guadagno, impedenza di radiazione, efficienza <br />
**Antenne in ricezione: area efficace, formula di Friis del collegamento, rapporto segnale rumore <br />
*Antenne ad apertura <br />
**Richiami sulla trasformata di Fourier<br />
**Radiazione da aperture planari: l'apertura rettangolare e circolare, aperture con distribuzione di campo uniforme e non uniforme, radiazione di una slot <br />
*Antenne per applicazioni wireless <br />
**Antenne a patch <br />
***Caratteristiche generali <br />
***Tecniche di alimentazione <br />
***Tecniche di allargamento della banda <br />
***Uso di software CAD di simulazione elettromagnetica per il design di antenne a patch<br />
**Antenne ad array<br />
***Principi generali<br />
***Array broadside<br />
***Array endfire<br />
***Tecniche di alimentazione<br />
**Antenna a riflettore<br />
***Generalità<br />
***Riflettori parabolici (prime focus)<br />
***Riflettori offset e Cassegrain: cenni<br />
**Antenne horn<br />
***Principi di funzionamento<br />
***Distribuzione di apertura<br />
**Antenne e sistemi contactless short distance e very short distance: cenni sui sistemi di Radio Identificazione a Radio Frequenza (RFID) <br />
*Propagazione <br />
**Il canale urbano<br />
***Cenni sui metodi di descrizione dei meccanismi di propagazione: modelli empirici, statistici, e deterministici <br />
**Propagazione Line-of-Sight e interferenza per onda riflessa <br />
**Propagazione per onda di superficiale<br />
**Propagazione ionosferica <br><br><br />
I contenuti di questo corso sono gli stessi della seconda parte di SISTEMI RADIO E A MICROONDE. Per quanto riguarda la prima parte, rivolgersi al Prof. Luca Vincetti.<br><br><br />
<br />
<br />
TESTI CONSIGLIATI:<br><br><br />
<br />
Constantine A. Balanis, "Antenna Theory: Analysis and Design," John Wiley & Sons Inc., 1982 (1st ed.), 1997(2nd ed.)<br />
<br />
Constantine A. Balanis, "Advanced Engineering Electromagnetics", John Wiley & Sons Inc., 1989<br />
<br />
Robert E. Collin, "Antennas and RadioWave Propagation," McGraw-Hill Series in Electrical Engineering, 1985<br />
<br />
Sergei Alexander Schelkunoff, "Advanced antenna theory," 1952<br />
<br />
Lal C. Godara, "Handbook of Antennas in Wireless Communication," CRC Press, 2002<br />
<br />
R. Garg, P. Bhartia, I. Bahal, A. Ittipiboon , "Microstrip Antenna Design Handbook," Artech House, 2000<br />
<br />
Stutzman, Thiele, "Antenna Theory and Design," John Wiley & Sons Inc., 1981<br />
<br />
<br />
[[Image:logo148x154.gif|50 px]] [http://lipari.ing.unimo.it/polemi/radio/frequencies.pdf Spettro frequenze onde radio]<br><br><br />
[[Image:chip.jpg|90 px]] [http://lipari.ing.unimo.it/polemi/radio/dielettrici.pdf Materiali dielettrici]<br><br><br />
;[[Image:patch.gif|150 px]] Introduzione al software CST MicroWave Studio<br><br><br />
:[http://lipari.ing.unimo.it/polemi/Radio/introCST1.pdf Introduzione Laboratorio 1]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/Radio/introCST2.pdf Introduzione Laboratorio 2]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/Radio/introCST4.pdf Introduzione Laboratorio 3]<br><br><br />
;[[Image:rfid.jpg|50 px]] Tecnologie emergenti...<br><br><br />
[[Media: LA_TECNOLOGIA_RFID.pdf| Introduzione alla tecnologia RFID]] Prof. Alessia Polemi, Courtesy of Prof. Gaetano Marrocco, University of Roma, Tor Vergata<br><br><br />
[[Media:Rfid041209.pdf| RFID nel monitoraggio di cantieri]], Prof. Andrea Prati<br><br><br />
[[Media:EHRF@INGREshort.pdf| Tecniche di Energy Harvesting]], Prof. Alessandro Bertacchini<br><br><br />
<br />
== MICROONDE<br> ==<br />
Per informazioni sul corso rivolgersi al titolare Prof. Vincetti<br><br><br />
;[[Image:microonde.jpg|90 px]] Introduzione al software CST MicroWave Studio<br><br><br />
:[http://lipari.ing.unimo.it/polemi/Micro/introCST1.pdf Intro CST 1]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/Micro/introCST2.pdf Intro CST 2]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/Micro/introCST3.pdf Intro CST 3]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/Micro/esempiodirelazione.pdf Esempio di relazione]<br><br><br />
<br />
<br />
== CAMPI ELETTROMAGNETICI B <br>==<br />
Per informazioni sul corso rivolgersi al titolare Prof. Zoboli<br><br><br />
;[[Image:dipoletto.jpg|30 px]] Radiazione<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_B/antennas1.pdf Antenna1]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_B/dipoleAnt.html Antenna2]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_B/dipoleAnt2.html Antenna3]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_B/laboratorio2008/CEMB.ppt Concetti di base sulle antenne filari]<br><br><br />
<br />
<br />
;[[Image:ospiti.gif|50px]] Testi d'esame<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_B/CB070626.pdf 26 giugno 2007]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_B/CB070717.pdf 17 luglio 2007]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_B/CB070911.pdf 11 settembre 2007]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_B/CB070928.pdf 28 settembre 2007]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_B/CB071219.pdf 19 dicembre 2007]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_B/CB080328.pdf 28 marzo 2008]<br><br><br />
:[[Media:CB080620.pdf|20 giugno 2008]];<br><br><br />
:[[Media:CB080717.pdf|17 luglio 2008]];<br><br><br />
:[[Media:CB_08-09-09.pdf|9 settembre 2008]];<br><br><br />
:[[Media:CB_09-03-18.pdf|18 marzo 2009]];<br><br><br />
:[[Media:CB090624.pdf|24 giugno 2009]];<br><br><br />
:[[Media:CB090715.pdf|15 luglio 2009]];<br><br><br />
:[[Media:CB090916.pdf|16 settembre 2009]];<br><br><br />
<br />
:[http://lipari.ing.unimo.it/vincetti/es_campi_B.html Precedenti Anni Accademici]<br />
<br />
== CAMPI ELETTROMAGNETICI A <br>==<br />
Per informazioni sul corso rivolgersi al titolare Prof. Zoboli<br><br><br />
;[[Image:dipoletto.jpg|30 px]] Linee di Trasmissione<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_A/smithchart.pdf Carta di Smith]<br><br><br />
<br />
<br />
;[[Image:ospiti.gif|50px]] Testi d'esame<br><br>:<br />
:[http://lipari.ing.unimo.it/polemi/CEM_A/20070321CEMA1.pdf 21 marzo 2007 (A)];[http://lipari.ing.unimo.it/polemi/CEM_A/20070321CEMA2.pdf 21 marzo 2007 (B)]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_A/20070412CEMA1.pdf 12 aprile 2007 (A)];[http://lipari.ing.unimo.it/polemi/CEM_A/20070412CEMA2.pdf 12 aprile 2007 (B)]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_A/20070626CEMA.pdf 26 giugno 2007]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_A/20070911CEMA.pdf 11 settembre 2007]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_A/20070928CEMA.pdf 28 settembre 2007]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_A/20071219CEMA.pdf 19 dicembre 2007]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_A/20080314CEMA.pdf 14 marzo 2008];<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_A/20080328CEMA.pdf 28 marzo 2008];<br><br><br />
:[[Media:20080620CEMA.pdf|20 giugno 2008]];<br><br><br />
:[[Media:2008_09_09_CEM_A.pdf|9 settembre 2008]];<br><br><br />
:[[Media:2009_03_18_CEM_A.pdf|18 marzo 2009]];<br><br><br />
:[[Media:20090624CEM_A.pdf|24 giugno 2009]];<br><br><br />
:[[Media:20090916CEM_A.pdf|16 settembre 2009]];<br><br><br />
<br />
:[http://lipari.ing.unimo.it/vincetti/es_campi_A.html Precedenti Anni Accademici]<br />
<br />
<br />
<br />
<br><br><br><br />
[[Image:home.gif|30px|left]] <br><br />
[[User:Apolemi | Home]]</div>Apolemihttps://web.ing.unimo.it/wiki/index.php?title=File:LA_TECNOLOGIA_RFID.pdf&diff=7071File:LA TECNOLOGIA RFID.pdf2009-12-27T21:04:25Z<p>Apolemi: </p>
<hr />
<div></div>Apolemihttps://web.ing.unimo.it/wiki/index.php?title=MATERIALE_DIDATTICO&diff=7070MATERIALE DIDATTICO2009-12-27T20:42:19Z<p>Apolemi: /* RADIOPROPAGAZIONE e SISTEMI RADIO E A MICROONDE */</p>
<hr />
<div>== RADIOPROPAGAZIONE e SISTEMI RADIO E A MICROONDE<br>==<br />
Il corso RADIOPROPAGAZIONE si ripropone di offrire allo studente tutto il bagaglio di conoscenze e informazioni connesse con il collegamento radio tra due o più utenti in un ambiente reale. A tal fine vengono ampiamente descritti i parametri fondamentali delle antenne, con particolare attenzione a quelle grandezze necessarie per caratterizzare il collegamento radio tra due punti. Con riferimento alle antenne usate nelle applicazioni wireless, vengono descritti i principi fondamentali per l'analisi ed il design delle antenna a microstriscia. A questo argomento è collegata una attività di laboratorio, che permette allo studente di imparare le principale tecniche di progetto delle antenne a microstriscia attraverso softwares commerciali. Mentre, con riferimento alle antenne usate nelle moderne applicazioni contactless, vengono descritti i principi fondamentali di funzionamento dei sistemi di identificazione a radiofrequenza (RFID). Infine il corso offre una ampia e dettagliata panoramica sulla caratterizzazione del canale radio, con riferimento sia al canale urbano (descrizione di modelli empirici, statistici e deterministici) sia alla propagazione Line-Of-Sight e ionosferica. <br>Il programma del corso è il seguente<br><br />
*Introduzione al corso<br />
*Richiami alle grandezze fondamentali delle antenne<br />
**Antenne in trasmissione: diagramma di radiazione, direttività e guadagno, impedenza di radiazione, efficienza <br />
**Antenne in ricezione: area efficace, formula di Friis del collegamento, rapporto segnale rumore <br />
*Antenne ad apertura <br />
**Richiami sulla trasformata di Fourier<br />
**Radiazione da aperture planari: l'apertura rettangolare e circolare, aperture con distribuzione di campo uniforme e non uniforme, radiazione di una slot <br />
*Antenne per applicazioni wireless <br />
**Antenne a patch <br />
***Caratteristiche generali <br />
***Tecniche di alimentazione <br />
***Tecniche di allargamento della banda <br />
***Uso di software CAD di simulazione elettromagnetica per il design di antenne a patch<br />
**Antenne ad array<br />
***Principi generali<br />
***Array broadside<br />
***Array endfire<br />
***Tecniche di alimentazione<br />
**Antenna a riflettore<br />
***Generalità<br />
***Riflettori parabolici (prime focus)<br />
***Riflettori offset e Cassegrain: cenni<br />
**Antenne horn<br />
***Principi di funzionamento<br />
***Distribuzione di apertura<br />
**Antenne e sistemi contactless short distance e very short distance: cenni sui sistemi di Radio Identificazione a Radio Frequenza (RFID) <br />
*Propagazione <br />
**Il canale urbano<br />
***Cenni sui metodi di descrizione dei meccanismi di propagazione: modelli empirici, statistici, e deterministici <br />
**Propagazione Line-of-Sight e interferenza per onda riflessa <br />
**Propagazione per onda di superficiale<br />
**Propagazione ionosferica <br><br><br />
I contenuti di questo corso sono gli stessi della seconda parte di SISTEMI RADIO E A MICROONDE. Per quanto riguarda la prima parte, rivolgersi al Prof. Luca Vincetti.<br><br><br />
<br />
<br />
TESTI CONSIGLIATI:<br><br><br />
<br />
Constantine A. Balanis, "Antenna Theory: Analysis and Design," John Wiley & Sons Inc., 1982 (1st ed.), 1997(2nd ed.)<br />
<br />
Constantine A. Balanis, "Advanced Engineering Electromagnetics", John Wiley & Sons Inc., 1989<br />
<br />
Robert E. Collin, "Antennas and RadioWave Propagation," McGraw-Hill Series in Electrical Engineering, 1985<br />
<br />
Sergei Alexander Schelkunoff, "Advanced antenna theory," 1952<br />
<br />
Lal C. Godara, "Handbook of Antennas in Wireless Communication," CRC Press, 2002<br />
<br />
R. Garg, P. Bhartia, I. Bahal, A. Ittipiboon , "Microstrip Antenna Design Handbook," Artech House, 2000<br />
<br />
Stutzman, Thiele, "Antenna Theory and Design," John Wiley & Sons Inc., 1981<br />
<br />
<br />
[[Image:logo148x154.gif|50 px]] [http://lipari.ing.unimo.it/polemi/radio/frequencies.pdf Spettro frequenze onde radio]<br><br><br />
[[Image:chip.jpg|90 px]] [http://lipari.ing.unimo.it/polemi/radio/dielettrici.pdf Materiali dielettrici]<br><br><br />
;[[Image:patch.gif|150 px]] Introduzione al software CST MicroWave Studio<br><br><br />
:[http://lipari.ing.unimo.it/polemi/Radio/introCST1.pdf Introduzione Laboratorio 1]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/Radio/introCST2.pdf Introduzione Laboratorio 2]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/Radio/introCST4.pdf Introduzione Laboratorio 3]<br><br><br />
;[[Image:rfid.jpg|50 px]] Tecnologie emergenti...<br><br><br />
[[Media: Intro_To_RFID_POLEMI_v1.pdf| Introduzione alla tecnologia RFID]] Prof. Alessia Polemi, Courtesy of Prof. Gaetano Marrocco, University of Roma, Tor Vergata<br><br><br />
[[Media:Rfid041209.pdf| RFID nel monitoraggio di cantieri]], Prof. Andrea Prati<br><br><br />
[[Media:EHRF@INGREshort.pdf| Tecniche di Energy Harvesting]], Prof. Alessandro Bertacchini<br><br><br />
<br />
== MICROONDE<br> ==<br />
Per informazioni sul corso rivolgersi al titolare Prof. Vincetti<br><br><br />
;[[Image:microonde.jpg|90 px]] Introduzione al software CST MicroWave Studio<br><br><br />
:[http://lipari.ing.unimo.it/polemi/Micro/introCST1.pdf Intro CST 1]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/Micro/introCST2.pdf Intro CST 2]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/Micro/introCST3.pdf Intro CST 3]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/Micro/esempiodirelazione.pdf Esempio di relazione]<br><br><br />
<br />
<br />
== CAMPI ELETTROMAGNETICI B <br>==<br />
Per informazioni sul corso rivolgersi al titolare Prof. Zoboli<br><br><br />
;[[Image:dipoletto.jpg|30 px]] Radiazione<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_B/antennas1.pdf Antenna1]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_B/dipoleAnt.html Antenna2]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_B/dipoleAnt2.html Antenna3]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_B/laboratorio2008/CEMB.ppt Concetti di base sulle antenne filari]<br><br><br />
<br />
<br />
;[[Image:ospiti.gif|50px]] Testi d'esame<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_B/CB070626.pdf 26 giugno 2007]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_B/CB070717.pdf 17 luglio 2007]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_B/CB070911.pdf 11 settembre 2007]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_B/CB070928.pdf 28 settembre 2007]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_B/CB071219.pdf 19 dicembre 2007]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_B/CB080328.pdf 28 marzo 2008]<br><br><br />
:[[Media:CB080620.pdf|20 giugno 2008]];<br><br><br />
:[[Media:CB080717.pdf|17 luglio 2008]];<br><br><br />
:[[Media:CB_08-09-09.pdf|9 settembre 2008]];<br><br><br />
:[[Media:CB_09-03-18.pdf|18 marzo 2009]];<br><br><br />
:[[Media:CB090624.pdf|24 giugno 2009]];<br><br><br />
:[[Media:CB090715.pdf|15 luglio 2009]];<br><br><br />
:[[Media:CB090916.pdf|16 settembre 2009]];<br><br><br />
<br />
:[http://lipari.ing.unimo.it/vincetti/es_campi_B.html Precedenti Anni Accademici]<br />
<br />
== CAMPI ELETTROMAGNETICI A <br>==<br />
Per informazioni sul corso rivolgersi al titolare Prof. Zoboli<br><br><br />
;[[Image:dipoletto.jpg|30 px]] Linee di Trasmissione<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_A/smithchart.pdf Carta di Smith]<br><br><br />
<br />
<br />
;[[Image:ospiti.gif|50px]] Testi d'esame<br><br>:<br />
:[http://lipari.ing.unimo.it/polemi/CEM_A/20070321CEMA1.pdf 21 marzo 2007 (A)];[http://lipari.ing.unimo.it/polemi/CEM_A/20070321CEMA2.pdf 21 marzo 2007 (B)]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_A/20070412CEMA1.pdf 12 aprile 2007 (A)];[http://lipari.ing.unimo.it/polemi/CEM_A/20070412CEMA2.pdf 12 aprile 2007 (B)]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_A/20070626CEMA.pdf 26 giugno 2007]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_A/20070911CEMA.pdf 11 settembre 2007]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_A/20070928CEMA.pdf 28 settembre 2007]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_A/20071219CEMA.pdf 19 dicembre 2007]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_A/20080314CEMA.pdf 14 marzo 2008];<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_A/20080328CEMA.pdf 28 marzo 2008];<br><br><br />
:[[Media:20080620CEMA.pdf|20 giugno 2008]];<br><br><br />
:[[Media:2008_09_09_CEM_A.pdf|9 settembre 2008]];<br><br><br />
:[[Media:2009_03_18_CEM_A.pdf|18 marzo 2009]];<br><br><br />
:[[Media:20090624CEM_A.pdf|24 giugno 2009]];<br><br><br />
:[[Media:20090916CEM_A.pdf|16 settembre 2009]];<br><br><br />
<br />
:[http://lipari.ing.unimo.it/vincetti/es_campi_A.html Precedenti Anni Accademici]<br />
<br />
<br />
<br />
<br><br><br><br />
[[Image:home.gif|30px|left]] <br><br />
[[User:Apolemi | Home]]</div>Apolemihttps://web.ing.unimo.it/wiki/index.php?title=MATERIALE_DIDATTICO&diff=7069MATERIALE DIDATTICO2009-12-27T20:39:09Z<p>Apolemi: /* RADIOPROPAGAZIONE e SISTEMI RADIO E A MICROONDE */</p>
<hr />
<div>== RADIOPROPAGAZIONE e SISTEMI RADIO E A MICROONDE<br>==<br />
Il corso RADIOPROPAGAZIONE si ripropone di offrire allo studente tutto il bagaglio di conoscenze e informazioni connesse con il collegamento radio tra due o più utenti in un ambiente reale. A tal fine vengono ampiamente descritti i parametri fondamentali delle antenne, con particolare attenzione a quelle grandezze necessarie per caratterizzare il collegamento radio tra due punti. Con riferimento alle antenne usate nelle applicazioni wireless, vengono descritti i principi fondamentali per l'analisi ed il design delle antenna a microstriscia. A questo argomento è collegata una attività di laboratorio, che permette allo studente di imparare le principale tecniche di progetto delle antenne a microstriscia attraverso softwares commerciali. Mentre, con riferimento alle antenne usate nelle moderne applicazioni contactless, vengono descritti i principi fondamentali di funzionamento dei sistemi di identificazione a radiofrequenza (RFID). Infine il corso offre una ampia e dettagliata panoramica sulla caratterizzazione del canale radio, con riferimento sia al canale urbano (descrizione di modelli empirici, statistici e deterministici) sia alla propagazione Line-Of-Sight e ionosferica. <br>Il programma del corso è il seguente<br><br />
*Introduzione al corso<br />
*Richiami alle grandezze fondamentali delle antenne<br />
**Antenne in trasmissione: diagramma di radiazione, direttività e guadagno, impedenza di radiazione, efficienza <br />
**Antenne in ricezione: area efficace, formula di Friis del collegamento, rapporto segnale rumore <br />
*Antenne ad apertura <br />
**Richiami sulla trasformata di Fourier<br />
**Radiazione da aperture planari: l'apertura rettangolare e circolare, aperture con distribuzione di campo uniforme e non uniforme, radiazione di una slot <br />
*Antenne per applicazioni wireless <br />
**Antenne a patch <br />
***Caratteristiche generali <br />
***Tecniche di alimentazione <br />
***Tecniche di allargamento della banda <br />
***Uso di software CAD di simulazione elettromagnetica per il design di antenne a patch<br />
**Antenne ad array<br />
***Principi generali<br />
***Array broadside<br />
***Array endfire<br />
***Tecniche di alimentazione<br />
**Antenna a riflettore<br />
***Generalità<br />
***Riflettori parabolici (prime focus)<br />
***Riflettori offset e Cassegrain: cenni<br />
**Antenne horn<br />
***Principi di funzionamento<br />
***Distribuzione di apertura<br />
**Antenne e sistemi contactless short distance e very short distance: cenni sui sistemi di Radio Identificazione a Radio Frequenza (RFID) <br />
*Propagazione <br />
**Il canale urbano<br />
***Cenni sui metodi di descrizione dei meccanismi di propagazione: modelli empirici, statistici, e deterministici <br />
**Propagazione Line-of-Sight e interferenza per onda riflessa <br />
**Propagazione per onda di superficiale<br />
**Propagazione ionosferica <br><br><br />
<br />
TESTI CONSIGLIATI:<br><br><br />
<br />
Constantine A. Balanis, "Antenna Theory: Analysis and Design," John Wiley & Sons Inc., 1982 (1st ed.), 1997(2nd ed.)<br />
<br />
Constantine A. Balanis, "Advanced Engineering Electromagnetics", John Wiley & Sons Inc., 1989<br />
<br />
Robert E. Collin, "Antennas and RadioWave Propagation," McGraw-Hill Series in Electrical Engineering, 1985<br />
<br />
Sergei Alexander Schelkunoff, "Advanced antenna theory," 1952<br />
<br />
Lal C. Godara, "Handbook of Antennas in Wireless Communication," CRC Press, 2002<br />
<br />
R. Garg, P. Bhartia, I. Bahal, A. Ittipiboon , "Microstrip Antenna Design Handbook," Artech House, 2000<br />
<br />
Stutzman, Thiele, "Antenna Theory and Design," John Wiley & Sons Inc., 1981<br />
<br />
<br />
[[Image:logo148x154.gif|50 px]] [http://lipari.ing.unimo.it/polemi/radio/frequencies.pdf Spettro frequenze onde radio]<br><br><br />
[[Image:chip.jpg|90 px]] [http://lipari.ing.unimo.it/polemi/radio/dielettrici.pdf Materiali dielettrici]<br><br><br />
;[[Image:patch.gif|150 px]] Introduzione al software CST MicroWave Studio<br><br><br />
:[http://lipari.ing.unimo.it/polemi/Radio/introCST1.pdf Introduzione Laboratorio 1]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/Radio/introCST2.pdf Introduzione Laboratorio 2]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/Radio/introCST4.pdf Introduzione Laboratorio 3]<br><br><br />
;[[Image:rfid.jpg|50 px]] Tecnologie emergenti...<br><br><br />
[[Media: Intro_To_RFID_POLEMI_v1.pdf| Introduzione alla tecnologia RFID]] Prof. Alessia Polemi, Courtesy of Prof. Gaetano Marrocco, University of Roma, Tor Vergata<br><br><br />
[[Media:Rfid041209.pdf| RFID nel monitoraggio di cantieri]], Prof. Andrea Prati<br><br><br />
[[Media:EHRF@INGREshort.pdf| Tecniche di Energy Harvesting]], Prof. Alessandro Bertacchini<br><br><br />
<br />
== MICROONDE<br> ==<br />
Per informazioni sul corso rivolgersi al titolare Prof. Vincetti<br><br><br />
;[[Image:microonde.jpg|90 px]] Introduzione al software CST MicroWave Studio<br><br><br />
:[http://lipari.ing.unimo.it/polemi/Micro/introCST1.pdf Intro CST 1]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/Micro/introCST2.pdf Intro CST 2]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/Micro/introCST3.pdf Intro CST 3]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/Micro/esempiodirelazione.pdf Esempio di relazione]<br><br><br />
<br />
<br />
== CAMPI ELETTROMAGNETICI B <br>==<br />
Per informazioni sul corso rivolgersi al titolare Prof. Zoboli<br><br><br />
;[[Image:dipoletto.jpg|30 px]] Radiazione<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_B/antennas1.pdf Antenna1]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_B/dipoleAnt.html Antenna2]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_B/dipoleAnt2.html Antenna3]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_B/laboratorio2008/CEMB.ppt Concetti di base sulle antenne filari]<br><br><br />
<br />
<br />
;[[Image:ospiti.gif|50px]] Testi d'esame<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_B/CB070626.pdf 26 giugno 2007]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_B/CB070717.pdf 17 luglio 2007]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_B/CB070911.pdf 11 settembre 2007]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_B/CB070928.pdf 28 settembre 2007]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_B/CB071219.pdf 19 dicembre 2007]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_B/CB080328.pdf 28 marzo 2008]<br><br><br />
:[[Media:CB080620.pdf|20 giugno 2008]];<br><br><br />
:[[Media:CB080717.pdf|17 luglio 2008]];<br><br><br />
:[[Media:CB_08-09-09.pdf|9 settembre 2008]];<br><br><br />
:[[Media:CB_09-03-18.pdf|18 marzo 2009]];<br><br><br />
:[[Media:CB090624.pdf|24 giugno 2009]];<br><br><br />
:[[Media:CB090715.pdf|15 luglio 2009]];<br><br><br />
:[[Media:CB090916.pdf|16 settembre 2009]];<br><br><br />
<br />
:[http://lipari.ing.unimo.it/vincetti/es_campi_B.html Precedenti Anni Accademici]<br />
<br />
== CAMPI ELETTROMAGNETICI A <br>==<br />
Per informazioni sul corso rivolgersi al titolare Prof. Zoboli<br><br><br />
;[[Image:dipoletto.jpg|30 px]] Linee di Trasmissione<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_A/smithchart.pdf Carta di Smith]<br><br><br />
<br />
<br />
;[[Image:ospiti.gif|50px]] Testi d'esame<br><br>:<br />
:[http://lipari.ing.unimo.it/polemi/CEM_A/20070321CEMA1.pdf 21 marzo 2007 (A)];[http://lipari.ing.unimo.it/polemi/CEM_A/20070321CEMA2.pdf 21 marzo 2007 (B)]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_A/20070412CEMA1.pdf 12 aprile 2007 (A)];[http://lipari.ing.unimo.it/polemi/CEM_A/20070412CEMA2.pdf 12 aprile 2007 (B)]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_A/20070626CEMA.pdf 26 giugno 2007]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_A/20070911CEMA.pdf 11 settembre 2007]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_A/20070928CEMA.pdf 28 settembre 2007]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_A/20071219CEMA.pdf 19 dicembre 2007]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_A/20080314CEMA.pdf 14 marzo 2008];<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_A/20080328CEMA.pdf 28 marzo 2008];<br><br><br />
:[[Media:20080620CEMA.pdf|20 giugno 2008]];<br><br><br />
:[[Media:2008_09_09_CEM_A.pdf|9 settembre 2008]];<br><br><br />
:[[Media:2009_03_18_CEM_A.pdf|18 marzo 2009]];<br><br><br />
:[[Media:20090624CEM_A.pdf|24 giugno 2009]];<br><br><br />
:[[Media:20090916CEM_A.pdf|16 settembre 2009]];<br><br><br />
<br />
:[http://lipari.ing.unimo.it/vincetti/es_campi_A.html Precedenti Anni Accademici]<br />
<br />
<br />
<br />
<br><br><br><br />
[[Image:home.gif|30px|left]] <br><br />
[[User:Apolemi | Home]]</div>Apolemihttps://web.ing.unimo.it/wiki/index.php?title=MATERIALE_DIDATTICO&diff=7068MATERIALE DIDATTICO2009-12-27T20:36:28Z<p>Apolemi: /* RADIOPROPAGAZIONE e SISTEMI RADIO E A MICROONDE */</p>
<hr />
<div>== RADIOPROPAGAZIONE e SISTEMI RADIO E A MICROONDE<br>==<br />
Il corso RADIOPROPAGAZIONE si ripropone di offrire allo studente tutto il bagaglio di conoscenze e informazioni connesse con il collegamento radio tra due o più utenti in un ambiente reale. A tal fine vengono ampiamente descritti i parametri fondamentali delle antenne, con particolare attenzione a quelle grandezze necessarie per caratterizzare il collegamento radio tra due punti. Con riferimento alle antenne usate nelle applicazioni wireless, vengono descritti i principi fondamentali per l'analisi ed il design delle antenna a microstriscia. A questo argomento è collegata una attività di laboratorio, che permette allo studente di imparare le principale tecniche di progetto delle antenne a microstriscia attraverso softwares commerciali. Mentre, con riferimento alle antenne usate nelle moderne applicazioni contactless, vengono descritti i principi fondamentali di funzionamento dei sistemi di identificazione a radiofrequenza (RFID). Infine il corso offre una ampia e dettagliata panoramica sulla caratterizzazione del canale radio, con riferimento sia al canale urbano (descrizione di modelli empirici, statistici e deterministici) sia alla propagazione Line-Of-Sight e ionosferica. <br>Il programma del corso è il seguente<br><br />
*Introduzione al corso<br />
*Richiami alle grandezze fondamentali delle antenne<br />
**Antenne in trasmissione: diagramma di radiazione, direttività e guadagno, impedenza di radiazione, efficienza <br />
**Antenne in ricezione: area efficace, formula di Friis del collegamento, rapporto segnale rumore <br />
*Antenne ad apertura <br />
**Richiami sulla trasformata di Fourier<br />
**Radiazione da aperture planari: l'apertura rettangolare e circolare, aperture con distribuzione di campo uniforme e non uniforme, radiazione di una slot <br />
*Antenne per applicazioni wireless <br />
**Antenne a patch <br />
***Caratteristiche generali <br />
***Tecniche di alimentazione <br />
***Tecniche di allargamento della banda <br />
***Uso di software CAD di simulazione elettromagnetica per il design di antenne a patch<br />
**Antenne ad array<br />
***Principi generali<br />
***Array broadside<br />
***Array endfire<br />
***Tecniche di alimentazione<br />
**Antenna a riflettore<br />
***Generalità<br />
***Riflettori parabolici (prime focus)<br />
***Riflettori offset e Cassegrain: cenni<br />
**Antenne horn<br />
***Principi di funzionamento<br />
***Distribuzione di apertura<br />
**Antenne e sistemi contactless short distance e very short distance: cenni sui sistemi di Radio Identificazione a Radio Frequenza (RFID) <br />
*Propagazione <br />
**Il canale urbano<br />
***Cenni sui metodi di descrizione dei meccanismi di propagazione: modelli empirici, statistici, e deterministici <br />
**Propagazione Line-of-Sight e interferenza per onda riflessa <br />
**Propagazione per onda di superficiale<br />
**Propagazione ionosferica <br><br><br />
<br />
TESTI CONSIGLIATI:<br><br><br />
<br />
Constantine A. Balanis, "Antenna Theory: Analysis and Design," John Wiley & Sons Inc., 1982 (1st ed.), 1997(2nd ed.)<br />
<br />
Constantine A. Balanis, "Advanced Engineering Electromagnetics", John Wiley & Sons Inc., 1989<br />
<br />
Robert E. Collin, "Antennas and RadioWave Propagation," McGraw-Hill Series in Electrical Engineering, 1985<br />
<br />
Sergei Alexander Schelkunoff, "Advanced antenna theory," 1952<br />
<br />
Lal C. Godara, "Handbook of Antennas in Wireless Communication," CRC Press, 2002<br />
<br />
R. Garg, P. Bhartia, I. Bahal, A. Ittipiboon , "Microstrip Antenna Design Handbook," Artech House, 2000<br />
<br />
Stutzman, Thiele, "Antenna Theory and Design," John Wiley & Sons Inc., 1981<br />
<br />
<br />
[[Image:logo148x154.gif|50 px]] [http://lipari.ing.unimo.it/polemi/radio/frequencies.pdf Spettro frequenze onde radio]<br><br><br />
[[Image:chip.jpg|90 px]] [http://lipari.ing.unimo.it/polemi/radio/dielettrici.pdf Materiali dielettrici]<br><br><br />
;[[Image:patch.gif|150 px]] Introduzione al software CST MicroWave Studio<br><br><br />
:[http://lipari.ing.unimo.it/polemi/Radio/introCST1.pdf Introduzione Laboratorio 1]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/Radio/introCST2.pdf Introduzione Laboratorio 2]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/Radio/introCST4.pdf Introduzione Laboratorio 3]<br><br><br />
;[[Image:rfid.jpg|50 px]] Tecnologie emergenti...<br><br><br />
[[Media: RFIDUniMo.pdf| Introduzione alla tecnologia RFID]] Prof. Alessia Polemi, Courtesy of Prof. Gaetano Marrocco, University of Roma, Tor Vergata<br><br><br />
[[Media:Rfid041209.pdf| RFID nel monitoraggio di cantieri]], Prof. Andrea Prati<br><br><br />
[[Media:EHRF@INGREshort.pdf| Tecniche di Energy Harvesting]], Prof. Alessandro Bertacchini<br><br><br />
<br />
== MICROONDE<br> ==<br />
Per informazioni sul corso rivolgersi al titolare Prof. Vincetti<br><br><br />
;[[Image:microonde.jpg|90 px]] Introduzione al software CST MicroWave Studio<br><br><br />
:[http://lipari.ing.unimo.it/polemi/Micro/introCST1.pdf Intro CST 1]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/Micro/introCST2.pdf Intro CST 2]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/Micro/introCST3.pdf Intro CST 3]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/Micro/esempiodirelazione.pdf Esempio di relazione]<br><br><br />
<br />
<br />
== CAMPI ELETTROMAGNETICI B <br>==<br />
Per informazioni sul corso rivolgersi al titolare Prof. Zoboli<br><br><br />
;[[Image:dipoletto.jpg|30 px]] Radiazione<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_B/antennas1.pdf Antenna1]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_B/dipoleAnt.html Antenna2]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_B/dipoleAnt2.html Antenna3]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_B/laboratorio2008/CEMB.ppt Concetti di base sulle antenne filari]<br><br><br />
<br />
<br />
;[[Image:ospiti.gif|50px]] Testi d'esame<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_B/CB070626.pdf 26 giugno 2007]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_B/CB070717.pdf 17 luglio 2007]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_B/CB070911.pdf 11 settembre 2007]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_B/CB070928.pdf 28 settembre 2007]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_B/CB071219.pdf 19 dicembre 2007]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_B/CB080328.pdf 28 marzo 2008]<br><br><br />
:[[Media:CB080620.pdf|20 giugno 2008]];<br><br><br />
:[[Media:CB080717.pdf|17 luglio 2008]];<br><br><br />
:[[Media:CB_08-09-09.pdf|9 settembre 2008]];<br><br><br />
:[[Media:CB_09-03-18.pdf|18 marzo 2009]];<br><br><br />
:[[Media:CB090624.pdf|24 giugno 2009]];<br><br><br />
:[[Media:CB090715.pdf|15 luglio 2009]];<br><br><br />
:[[Media:CB090916.pdf|16 settembre 2009]];<br><br><br />
<br />
:[http://lipari.ing.unimo.it/vincetti/es_campi_B.html Precedenti Anni Accademici]<br />
<br />
== CAMPI ELETTROMAGNETICI A <br>==<br />
Per informazioni sul corso rivolgersi al titolare Prof. Zoboli<br><br><br />
;[[Image:dipoletto.jpg|30 px]] Linee di Trasmissione<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_A/smithchart.pdf Carta di Smith]<br><br><br />
<br />
<br />
;[[Image:ospiti.gif|50px]] Testi d'esame<br><br>:<br />
:[http://lipari.ing.unimo.it/polemi/CEM_A/20070321CEMA1.pdf 21 marzo 2007 (A)];[http://lipari.ing.unimo.it/polemi/CEM_A/20070321CEMA2.pdf 21 marzo 2007 (B)]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_A/20070412CEMA1.pdf 12 aprile 2007 (A)];[http://lipari.ing.unimo.it/polemi/CEM_A/20070412CEMA2.pdf 12 aprile 2007 (B)]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_A/20070626CEMA.pdf 26 giugno 2007]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_A/20070911CEMA.pdf 11 settembre 2007]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_A/20070928CEMA.pdf 28 settembre 2007]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_A/20071219CEMA.pdf 19 dicembre 2007]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_A/20080314CEMA.pdf 14 marzo 2008];<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_A/20080328CEMA.pdf 28 marzo 2008];<br><br><br />
:[[Media:20080620CEMA.pdf|20 giugno 2008]];<br><br><br />
:[[Media:2008_09_09_CEM_A.pdf|9 settembre 2008]];<br><br><br />
:[[Media:2009_03_18_CEM_A.pdf|18 marzo 2009]];<br><br><br />
:[[Media:20090624CEM_A.pdf|24 giugno 2009]];<br><br><br />
:[[Media:20090916CEM_A.pdf|16 settembre 2009]];<br><br><br />
<br />
:[http://lipari.ing.unimo.it/vincetti/es_campi_A.html Precedenti Anni Accademici]<br />
<br />
<br />
<br />
<br><br><br><br />
[[Image:home.gif|30px|left]] <br><br />
[[User:Apolemi | Home]]</div>Apolemihttps://web.ing.unimo.it/wiki/index.php?title=MATERIALE_DIDATTICO&diff=7065MATERIALE DIDATTICO2009-12-27T20:34:55Z<p>Apolemi: /* RADIOPROPAGAZIONE e SISTEMI RADIO E A MICROONDE */</p>
<hr />
<div>== RADIOPROPAGAZIONE e SISTEMI RADIO E A MICROONDE<br>==<br />
Il corso RADIOPROPAGAZIONE si ripropone di offrire allo studente tutto il bagaglio di conoscenze e informazioni connesse con il collegamento radio tra due o più utenti in un ambiente reale. A tal fine vengono ampiamente descritti i parametri fondamentali delle antenne, con particolare attenzione a quelle grandezze necessarie per caratterizzare il collegamento radio tra due punti. Con riferimento alle antenne usate nelle applicazioni wireless, vengono descritti i principi fondamentali per l'analisi ed il design delle antenna a microstriscia. A questo argomento è collegata una attività di laboratorio, che permette allo studente di imparare le principale tecniche di progetto delle antenne a microstriscia attraverso softwares commerciali. Mentre, con riferimento alle antenne usate nelle moderne applicazioni contactless, vengono descritti i principi fondamentali di funzionamento dei sistemi di identificazione a radiofrequenza (RFID). Infine il corso offre una ampia e dettagliata panoramica sulla caratterizzazione del canale radio, con riferimento sia al canale urbano (descrizione di modelli empirici, statistici e deterministici) sia alla propagazione Line-Of-Sight e ionosferica. <br>Il programma del corso è il seguente<br><br />
*Introduzione al corso<br />
*Richiami alle grandezze fondamentali delle antenne<br />
**Antenne in trasmissione: diagramma di radiazione, direttività e guadagno, impedenza di radiazione, efficienza <br />
**Antenne in ricezione: area efficace, formula di Friis del collegamento, rapporto segnale rumore <br />
*Antenne ad apertura <br />
**Richiami sulla trasformata di Fourier<br />
**Radiazione da aperture planari: l'apertura rettangolare e circolare, aperture con distribuzione di campo uniforme e non uniforme, radiazione di una slot <br />
*Antenne per applicazioni wireless <br />
**Antenne a patch <br />
***Caratteristiche generali <br />
***Tecniche di alimentazione <br />
***Tecniche di allargamento della banda <br />
***Uso di software CAD di simulazione elettromagnetica per il design di antenne a patch<br />
**Antenne ad array<br />
***Principi generali<br />
***Array broadside<br />
***Array endfire<br />
***Tecniche di alimentazione<br />
**Antenna a riflettore<br />
***Generalità<br />
***Riflettori parabolici (prime focus)<br />
***Riflettori offset e Cassegrain: cenni<br />
**Antenne horn<br />
***Principi di funzionamento<br />
***Distribuzione di apertura<br />
**Antenne e sistemi contactless short distance e very short distance: cenni sui sistemi di Radio Identificazione a Radio Frequenza (RFID) <br />
*Propagazione <br />
**Il canale urbano<br />
***Cenni sui metodi di descrizione dei meccanismi di propagazione: modelli empirici, statistici, e deterministici <br />
**Propagazione Line-of-Sight e interferenza per onda riflessa <br />
**Propagazione per onda di superficiale<br />
**Propagazione ionosferica <br><br><br />
<br />
TESTI CONSIGLIATI:<br><br><br />
<br />
Constantine A. Balanis, "Antenna Theory: Analysis and Design," John Wiley & Sons Inc., 1982 (1st ed.), 1997(2nd ed.)<br />
<br />
Constantine A. Balanis, "Advanced Engineering Electromagnetics", John Wiley & Sons Inc., 1989<br />
<br />
Robert E. Collin, "Antennas and RadioWave Propagation," McGraw-Hill Series in Electrical Engineering, 1985<br />
<br />
Sergei Alexander Schelkunoff, "Advanced antenna theory," 1952<br />
<br />
Lal C. Godara, "Handbook of Antennas in Wireless Communication," CRC Press, 2002<br />
<br />
R. Garg, P. Bhartia, I. Bahal, A. Ittipiboon , "Microstrip Antenna Design Handbook," Artech House, 2000<br />
<br />
Stutzman, Thiele, "Antenna Theory and Design," John Wiley & Sons Inc., 1981<br />
<br />
<br />
[[Image:logo148x154.gif|50 px]] [http://lipari.ing.unimo.it/polemi/radio/frequencies.pdf Spettro frequenze onde radio]<br><br><br />
[[Image:chip.jpg|90 px]] [http://lipari.ing.unimo.it/polemi/radio/dielettrici.pdf Materiali dielettrici]<br><br><br />
;[[Image:patch.gif|150 px]] Introduzione al software CST MicroWave Studio<br><br><br />
:[http://lipari.ing.unimo.it/polemi/Radio/introCST1.pdf Introduzione Laboratorio 1]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/Radio/introCST2.pdf Introduzione Laboratorio 2]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/Radio/introCST4.pdf Introduzione Laboratorio 3]<br><br><br />
;[[Image:rfid.jpg|50 px]] Tecnologie emergenti...<br><br><br />
[[Media: RFIDUniMoRev2.0.pdf| Introduzione alla tecnologia RFID]] Prof. Alessia Polemi, Courtesy of Prof. Gaetano Marrocco, University of Roma, Tor Vergata<br><br><br />
[[Media:Rfid041209.pdf| RFID nel monitoraggio di cantieri]], Prof. Andrea Prati<br><br><br />
[[Media:EHRF@INGREshort.pdf| Tecniche di Energy Harvesting]], Prof. Alessandro Bertacchini<br><br><br />
<br />
== MICROONDE<br> ==<br />
Per informazioni sul corso rivolgersi al titolare Prof. Vincetti<br><br><br />
;[[Image:microonde.jpg|90 px]] Introduzione al software CST MicroWave Studio<br><br><br />
:[http://lipari.ing.unimo.it/polemi/Micro/introCST1.pdf Intro CST 1]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/Micro/introCST2.pdf Intro CST 2]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/Micro/introCST3.pdf Intro CST 3]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/Micro/esempiodirelazione.pdf Esempio di relazione]<br><br><br />
<br />
<br />
== CAMPI ELETTROMAGNETICI B <br>==<br />
Per informazioni sul corso rivolgersi al titolare Prof. Zoboli<br><br><br />
;[[Image:dipoletto.jpg|30 px]] Radiazione<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_B/antennas1.pdf Antenna1]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_B/dipoleAnt.html Antenna2]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_B/dipoleAnt2.html Antenna3]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_B/laboratorio2008/CEMB.ppt Concetti di base sulle antenne filari]<br><br><br />
<br />
<br />
;[[Image:ospiti.gif|50px]] Testi d'esame<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_B/CB070626.pdf 26 giugno 2007]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_B/CB070717.pdf 17 luglio 2007]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_B/CB070911.pdf 11 settembre 2007]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_B/CB070928.pdf 28 settembre 2007]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_B/CB071219.pdf 19 dicembre 2007]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_B/CB080328.pdf 28 marzo 2008]<br><br><br />
:[[Media:CB080620.pdf|20 giugno 2008]];<br><br><br />
:[[Media:CB080717.pdf|17 luglio 2008]];<br><br><br />
:[[Media:CB_08-09-09.pdf|9 settembre 2008]];<br><br><br />
:[[Media:CB_09-03-18.pdf|18 marzo 2009]];<br><br><br />
:[[Media:CB090624.pdf|24 giugno 2009]];<br><br><br />
:[[Media:CB090715.pdf|15 luglio 2009]];<br><br><br />
:[[Media:CB090916.pdf|16 settembre 2009]];<br><br><br />
<br />
:[http://lipari.ing.unimo.it/vincetti/es_campi_B.html Precedenti Anni Accademici]<br />
<br />
== CAMPI ELETTROMAGNETICI A <br>==<br />
Per informazioni sul corso rivolgersi al titolare Prof. Zoboli<br><br><br />
;[[Image:dipoletto.jpg|30 px]] Linee di Trasmissione<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_A/smithchart.pdf Carta di Smith]<br><br><br />
<br />
<br />
;[[Image:ospiti.gif|50px]] Testi d'esame<br><br>:<br />
:[http://lipari.ing.unimo.it/polemi/CEM_A/20070321CEMA1.pdf 21 marzo 2007 (A)];[http://lipari.ing.unimo.it/polemi/CEM_A/20070321CEMA2.pdf 21 marzo 2007 (B)]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_A/20070412CEMA1.pdf 12 aprile 2007 (A)];[http://lipari.ing.unimo.it/polemi/CEM_A/20070412CEMA2.pdf 12 aprile 2007 (B)]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_A/20070626CEMA.pdf 26 giugno 2007]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_A/20070911CEMA.pdf 11 settembre 2007]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_A/20070928CEMA.pdf 28 settembre 2007]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_A/20071219CEMA.pdf 19 dicembre 2007]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_A/20080314CEMA.pdf 14 marzo 2008];<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_A/20080328CEMA.pdf 28 marzo 2008];<br><br><br />
:[[Media:20080620CEMA.pdf|20 giugno 2008]];<br><br><br />
:[[Media:2008_09_09_CEM_A.pdf|9 settembre 2008]];<br><br><br />
:[[Media:2009_03_18_CEM_A.pdf|18 marzo 2009]];<br><br><br />
:[[Media:20090624CEM_A.pdf|24 giugno 2009]];<br><br><br />
:[[Media:20090916CEM_A.pdf|16 settembre 2009]];<br><br><br />
<br />
:[http://lipari.ing.unimo.it/vincetti/es_campi_A.html Precedenti Anni Accademici]<br />
<br />
<br />
<br />
<br><br><br><br />
[[Image:home.gif|30px|left]] <br><br />
[[User:Apolemi | Home]]</div>Apolemihttps://web.ing.unimo.it/wiki/index.php?title=MATERIALE_DIDATTICO&diff=7064MATERIALE DIDATTICO2009-12-27T20:33:27Z<p>Apolemi: /* RADIOPROPAGAZIONE e SISTEMI RADIO E A MICROONDE */</p>
<hr />
<div>== RADIOPROPAGAZIONE e SISTEMI RADIO E A MICROONDE<br>==<br />
Il corso RADIOPROPAGAZIONE si ripropone di offrire allo studente tutto il bagaglio di conoscenze e informazioni connesse con il collegamento radio tra due o più utenti in un ambiente reale. A tal fine vengono ampiamente descritti i parametri fondamentali delle antenne, con particolare attenzione a quelle grandezze necessarie per caratterizzare il collegamento radio tra due punti. Con riferimento alle antenne usate nelle applicazioni wireless, vengono descritti i principi fondamentali per l'analisi ed il design delle antenna a microstriscia. A questo argomento è collegata una attività di laboratorio, che permette allo studente di imparare le principale tecniche di progetto delle antenne a microstriscia attraverso softwares commerciali. Mentre, con riferimento alle antenne usate nelle moderne applicazioni contactless, vengono descritti i principi fondamentali di funzionamento dei sistemi di identificazione a radiofrequenza (RFID). Infine il corso offre una ampia e dettagliata panoramica sulla caratterizzazione del canale radio, con riferimento sia al canale urbano (descrizione di modelli empirici, statistici e deterministici) sia alla propagazione Line-Of-Sight e ionosferica. <br>Il programma del corso è il seguente<br><br />
*Introduzione al corso<br />
*Richiami alle grandezze fondamentali delle antenne<br />
**Antenne in trasmissione: diagramma di radiazione, direttività e guadagno, impedenza di radiazione, efficienza <br />
**Antenne in ricezione: area efficace, formula di Friis del collegamento, rapporto segnale rumore <br />
*Antenne ad apertura <br />
**Richiami sulla trasformata di Fourier<br />
**Radiazione da aperture planari: l'apertura rettangolare e circolare, aperture con distribuzione di campo uniforme e non uniforme, radiazione di una slot <br />
*Antenne per applicazioni wireless <br />
**Antenne a patch <br />
***Caratteristiche generali <br />
***Tecniche di alimentazione <br />
***Tecniche di allargamento della banda <br />
***Uso di software CAD di simulazione elettromagnetica per il design di antenne a patch<br />
**Antenne ad array<br />
***Principi generali<br />
***Array broadside<br />
***Array endfire<br />
***Tecniche di alimentazione<br />
**Antenna a riflettore<br />
***Generalità<br />
***Riflettori parabolici (prime focus)<br />
***Riflettori offset e Cassegrain: cenni<br />
**Antenne horn<br />
***Principi di funzionamento<br />
***Distribuzione di apertura<br />
**Antenne e sistemi contactless short distance e very short distance: cenni sui sistemi di Radio Identificazione a Radio Frequenza (RFID) <br />
*Propagazione <br />
**Il canale urbano<br />
***Cenni sui metodi di descrizione dei meccanismi di propagazione: modelli empirici, statistici, e deterministici <br />
**Propagazione Line-of-Sight e interferenza per onda riflessa <br />
**Propagazione per onda di superficiale<br />
**Propagazione ionosferica <br><br><br />
<br />
TESTI CONSIGLIATI:<br><br><br />
<br />
Constantine A. Balanis, "Antenna Theory: Analysis and Design," John Wiley & Sons Inc., 1982 (1st ed.), 1997(2nd ed.)<br />
<br />
Constantine A. Balanis, "Advanced Engineering Electromagnetics", John Wiley & Sons Inc., 1989<br />
<br />
Robert E. Collin, "Antennas and RadioWave Propagation," McGraw-Hill Series in Electrical Engineering, 1985<br />
<br />
Sergei Alexander Schelkunoff, "Advanced antenna theory," 1952<br />
<br />
Lal C. Godara, "Handbook of Antennas in Wireless Communication," CRC Press, 2002<br />
<br />
R. Garg, P. Bhartia, I. Bahal, A. Ittipiboon , "Microstrip Antenna Design Handbook," Artech House, 2000<br />
<br />
Stutzman, Thiele, "Antenna Theory and Design," John Wiley & Sons Inc., 1981<br />
<br />
<br />
[[Image:logo148x154.gif|50 px]] [http://lipari.ing.unimo.it/polemi/radio/frequencies.pdf Spettro frequenze onde radio]<br><br><br />
[[Image:chip.jpg|90 px]] [http://lipari.ing.unimo.it/polemi/radio/dielettrici.pdf Materiali dielettrici]<br><br><br />
;[[Image:patch.gif|150 px]] Introduzione al software CST MicroWave Studio<br><br><br />
:[http://lipari.ing.unimo.it/polemi/Radio/introCST1.pdf Introduzione Laboratorio 1]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/Radio/introCST2.pdf Introduzione Laboratorio 2]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/Radio/introCST4.pdf Introduzione Laboratorio 3]<br><br><br />
;[[Image:rfid.jpg|50 px]] Tecnologie emergenti...<br><br><br />
[[Media: RFIDUniMoRev2.0.pdf| Introduzione alla tecnologia RFID]] Courtesy of Prof. Gaetano Marrocco, University of Roma, Tor Vergata<br><br><br />
[[Media:Rfid041209.pdf| RFID per monitoraggio di cantieri, Prof. Andrea Prati]]<br><br><br />
[[Media:EHRF@INGREshort.pdf| ecniche di Energy Saving, Prof. Alessandro Bertacchini]]<br><br><br />
<br />
== MICROONDE<br> ==<br />
Per informazioni sul corso rivolgersi al titolare Prof. Vincetti<br><br><br />
;[[Image:microonde.jpg|90 px]] Introduzione al software CST MicroWave Studio<br><br><br />
:[http://lipari.ing.unimo.it/polemi/Micro/introCST1.pdf Intro CST 1]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/Micro/introCST2.pdf Intro CST 2]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/Micro/introCST3.pdf Intro CST 3]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/Micro/esempiodirelazione.pdf Esempio di relazione]<br><br><br />
<br />
<br />
== CAMPI ELETTROMAGNETICI B <br>==<br />
Per informazioni sul corso rivolgersi al titolare Prof. Zoboli<br><br><br />
;[[Image:dipoletto.jpg|30 px]] Radiazione<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_B/antennas1.pdf Antenna1]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_B/dipoleAnt.html Antenna2]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_B/dipoleAnt2.html Antenna3]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_B/laboratorio2008/CEMB.ppt Concetti di base sulle antenne filari]<br><br><br />
<br />
<br />
;[[Image:ospiti.gif|50px]] Testi d'esame<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_B/CB070626.pdf 26 giugno 2007]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_B/CB070717.pdf 17 luglio 2007]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_B/CB070911.pdf 11 settembre 2007]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_B/CB070928.pdf 28 settembre 2007]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_B/CB071219.pdf 19 dicembre 2007]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_B/CB080328.pdf 28 marzo 2008]<br><br><br />
:[[Media:CB080620.pdf|20 giugno 2008]];<br><br><br />
:[[Media:CB080717.pdf|17 luglio 2008]];<br><br><br />
:[[Media:CB_08-09-09.pdf|9 settembre 2008]];<br><br><br />
:[[Media:CB_09-03-18.pdf|18 marzo 2009]];<br><br><br />
:[[Media:CB090624.pdf|24 giugno 2009]];<br><br><br />
:[[Media:CB090715.pdf|15 luglio 2009]];<br><br><br />
:[[Media:CB090916.pdf|16 settembre 2009]];<br><br><br />
<br />
:[http://lipari.ing.unimo.it/vincetti/es_campi_B.html Precedenti Anni Accademici]<br />
<br />
== CAMPI ELETTROMAGNETICI A <br>==<br />
Per informazioni sul corso rivolgersi al titolare Prof. Zoboli<br><br><br />
;[[Image:dipoletto.jpg|30 px]] Linee di Trasmissione<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_A/smithchart.pdf Carta di Smith]<br><br><br />
<br />
<br />
;[[Image:ospiti.gif|50px]] Testi d'esame<br><br>:<br />
:[http://lipari.ing.unimo.it/polemi/CEM_A/20070321CEMA1.pdf 21 marzo 2007 (A)];[http://lipari.ing.unimo.it/polemi/CEM_A/20070321CEMA2.pdf 21 marzo 2007 (B)]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_A/20070412CEMA1.pdf 12 aprile 2007 (A)];[http://lipari.ing.unimo.it/polemi/CEM_A/20070412CEMA2.pdf 12 aprile 2007 (B)]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_A/20070626CEMA.pdf 26 giugno 2007]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_A/20070911CEMA.pdf 11 settembre 2007]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_A/20070928CEMA.pdf 28 settembre 2007]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_A/20071219CEMA.pdf 19 dicembre 2007]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_A/20080314CEMA.pdf 14 marzo 2008];<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_A/20080328CEMA.pdf 28 marzo 2008];<br><br><br />
:[[Media:20080620CEMA.pdf|20 giugno 2008]];<br><br><br />
:[[Media:2008_09_09_CEM_A.pdf|9 settembre 2008]];<br><br><br />
:[[Media:2009_03_18_CEM_A.pdf|18 marzo 2009]];<br><br><br />
:[[Media:20090624CEM_A.pdf|24 giugno 2009]];<br><br><br />
:[[Media:20090916CEM_A.pdf|16 settembre 2009]];<br><br><br />
<br />
:[http://lipari.ing.unimo.it/vincetti/es_campi_A.html Precedenti Anni Accademici]<br />
<br />
<br />
<br />
<br><br><br><br />
[[Image:home.gif|30px|left]] <br><br />
[[User:Apolemi | Home]]</div>Apolemihttps://web.ing.unimo.it/wiki/index.php?title=File:Rfid041209.pdf&diff=7063File:Rfid041209.pdf2009-12-27T20:32:01Z<p>Apolemi: </p>
<hr />
<div></div>Apolemihttps://web.ing.unimo.it/wiki/index.php?title=File:EHRF@INGREshort.pdf&diff=7062File:EHRF@INGREshort.pdf2009-12-27T20:28:07Z<p>Apolemi: </p>
<hr />
<div></div>Apolemihttps://web.ing.unimo.it/wiki/index.php?title=MATERIALE_DIDATTICO&diff=7061MATERIALE DIDATTICO2009-12-27T20:27:44Z<p>Apolemi: /* RADIOPROPAGAZIONE e SISTEMI RADIO E A MICROONDE */</p>
<hr />
<div>== RADIOPROPAGAZIONE e SISTEMI RADIO E A MICROONDE<br>==<br />
Il corso RADIOPROPAGAZIONE si ripropone di offrire allo studente tutto il bagaglio di conoscenze e informazioni connesse con il collegamento radio tra due o più utenti in un ambiente reale. A tal fine vengono ampiamente descritti i parametri fondamentali delle antenne, con particolare attenzione a quelle grandezze necessarie per caratterizzare il collegamento radio tra due punti. Con riferimento alle antenne usate nelle applicazioni wireless, vengono descritti i principi fondamentali per l'analisi ed il design delle antenna a microstriscia. A questo argomento è collegata una attività di laboratorio, che permette allo studente di imparare le principale tecniche di progetto delle antenne a microstriscia attraverso softwares commerciali. Mentre, con riferimento alle antenne usate nelle moderne applicazioni contactless, vengono descritti i principi fondamentali di funzionamento dei sistemi di identificazione a radiofrequenza (RFID). Infine il corso offre una ampia e dettagliata panoramica sulla caratterizzazione del canale radio, con riferimento sia al canale urbano (descrizione di modelli empirici, statistici e deterministici) sia alla propagazione Line-Of-Sight e ionosferica. <br>Il programma del corso è il seguente<br><br />
*Introduzione al corso<br />
*Richiami alle grandezze fondamentali delle antenne<br />
**Antenne in trasmissione: diagramma di radiazione, direttività e guadagno, impedenza di radiazione, efficienza <br />
**Antenne in ricezione: area efficace, formula di Friis del collegamento, rapporto segnale rumore <br />
*Antenne ad apertura <br />
**Richiami sulla trasformata di Fourier<br />
**Radiazione da aperture planari: l'apertura rettangolare e circolare, aperture con distribuzione di campo uniforme e non uniforme, radiazione di una slot <br />
*Antenne per applicazioni wireless <br />
**Antenne a patch <br />
***Caratteristiche generali <br />
***Tecniche di alimentazione <br />
***Tecniche di allargamento della banda <br />
***Uso di software CAD di simulazione elettromagnetica per il design di antenne a patch<br />
**Antenne ad array<br />
***Principi generali<br />
***Array broadside<br />
***Array endfire<br />
***Tecniche di alimentazione<br />
**Antenna a riflettore<br />
***Generalità<br />
***Riflettori parabolici (prime focus)<br />
***Riflettori offset e Cassegrain: cenni<br />
**Antenne horn<br />
***Principi di funzionamento<br />
***Distribuzione di apertura<br />
**Antenne e sistemi contactless short distance e very short distance: cenni sui sistemi di Radio Identificazione a Radio Frequenza (RFID) <br />
*Propagazione <br />
**Il canale urbano<br />
***Cenni sui metodi di descrizione dei meccanismi di propagazione: modelli empirici, statistici, e deterministici <br />
**Propagazione Line-of-Sight e interferenza per onda riflessa <br />
**Propagazione per onda di superficiale<br />
**Propagazione ionosferica <br><br><br />
<br />
TESTI CONSIGLIATI:<br><br><br />
<br />
Constantine A. Balanis, "Antenna Theory: Analysis and Design," John Wiley & Sons Inc., 1982 (1st ed.), 1997(2nd ed.)<br />
<br />
Constantine A. Balanis, "Advanced Engineering Electromagnetics", John Wiley & Sons Inc., 1989<br />
<br />
Robert E. Collin, "Antennas and RadioWave Propagation," McGraw-Hill Series in Electrical Engineering, 1985<br />
<br />
Sergei Alexander Schelkunoff, "Advanced antenna theory," 1952<br />
<br />
Lal C. Godara, "Handbook of Antennas in Wireless Communication," CRC Press, 2002<br />
<br />
R. Garg, P. Bhartia, I. Bahal, A. Ittipiboon , "Microstrip Antenna Design Handbook," Artech House, 2000<br />
<br />
Stutzman, Thiele, "Antenna Theory and Design," John Wiley & Sons Inc., 1981<br />
<br />
<br />
[[Image:logo148x154.gif|50 px]] [http://lipari.ing.unimo.it/polemi/radio/frequencies.pdf Spettro frequenze onde radio]<br><br><br />
[[Image:chip.jpg|90 px]] [http://lipari.ing.unimo.it/polemi/radio/dielettrici.pdf Materiali dielettrici]<br><br><br />
;[[Image:patch.gif|150 px]] Introduzione al software CST MicroWave Studio<br><br><br />
:[http://lipari.ing.unimo.it/polemi/Radio/introCST1.pdf Introduzione Laboratorio 1]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/Radio/introCST2.pdf Introduzione Laboratorio 2]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/Radio/introCST4.pdf Introduzione Laboratorio 3]<br><br><br />
;[[Image:rfid.jpg|50 px]] Tecnologie emergenti...<br><br><br />
:[http://lipari.ing.unimo.it/polemi/Radio/LA_TECNOLOGIA_RFID.pdf La tecnologia RFID] Courtesy of Prof. Gaetano Marrocco, University of Roma, Tor Vergata <br><br><br />
:[http://lipari.ing.unimo.it/polemi/Radio/Rfid 041209.pdf La tecnologia RFID] Courtesy of Prof. Gaetano Marrocco, University of Roma, Tor Vergata <br><br><br />
:[http://lipari.ing.unimo.it/polemi/Radio/EHRF@INGREshort.pdf Tecniche di Energy Saving] Prof. Alessandro Bertacchini <br><br><br />
<br />
== MICROONDE<br> ==<br />
Per informazioni sul corso rivolgersi al titolare Prof. Vincetti<br><br><br />
;[[Image:microonde.jpg|90 px]] Introduzione al software CST MicroWave Studio<br><br><br />
:[http://lipari.ing.unimo.it/polemi/Micro/introCST1.pdf Intro CST 1]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/Micro/introCST2.pdf Intro CST 2]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/Micro/introCST3.pdf Intro CST 3]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/Micro/esempiodirelazione.pdf Esempio di relazione]<br><br><br />
<br />
<br />
== CAMPI ELETTROMAGNETICI B <br>==<br />
Per informazioni sul corso rivolgersi al titolare Prof. Zoboli<br><br><br />
;[[Image:dipoletto.jpg|30 px]] Radiazione<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_B/antennas1.pdf Antenna1]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_B/dipoleAnt.html Antenna2]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_B/dipoleAnt2.html Antenna3]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_B/laboratorio2008/CEMB.ppt Concetti di base sulle antenne filari]<br><br><br />
<br />
<br />
;[[Image:ospiti.gif|50px]] Testi d'esame<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_B/CB070626.pdf 26 giugno 2007]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_B/CB070717.pdf 17 luglio 2007]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_B/CB070911.pdf 11 settembre 2007]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_B/CB070928.pdf 28 settembre 2007]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_B/CB071219.pdf 19 dicembre 2007]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_B/CB080328.pdf 28 marzo 2008]<br><br><br />
:[[Media:CB080620.pdf|20 giugno 2008]];<br><br><br />
:[[Media:CB080717.pdf|17 luglio 2008]];<br><br><br />
:[[Media:CB_08-09-09.pdf|9 settembre 2008]];<br><br><br />
:[[Media:CB_09-03-18.pdf|18 marzo 2009]];<br><br><br />
:[[Media:CB090624.pdf|24 giugno 2009]];<br><br><br />
:[[Media:CB090715.pdf|15 luglio 2009]];<br><br><br />
:[[Media:CB090916.pdf|16 settembre 2009]];<br><br><br />
<br />
:[http://lipari.ing.unimo.it/vincetti/es_campi_B.html Precedenti Anni Accademici]<br />
<br />
== CAMPI ELETTROMAGNETICI A <br>==<br />
Per informazioni sul corso rivolgersi al titolare Prof. Zoboli<br><br><br />
;[[Image:dipoletto.jpg|30 px]] Linee di Trasmissione<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_A/smithchart.pdf Carta di Smith]<br><br><br />
<br />
<br />
;[[Image:ospiti.gif|50px]] Testi d'esame<br><br>:<br />
:[http://lipari.ing.unimo.it/polemi/CEM_A/20070321CEMA1.pdf 21 marzo 2007 (A)];[http://lipari.ing.unimo.it/polemi/CEM_A/20070321CEMA2.pdf 21 marzo 2007 (B)]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_A/20070412CEMA1.pdf 12 aprile 2007 (A)];[http://lipari.ing.unimo.it/polemi/CEM_A/20070412CEMA2.pdf 12 aprile 2007 (B)]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_A/20070626CEMA.pdf 26 giugno 2007]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_A/20070911CEMA.pdf 11 settembre 2007]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_A/20070928CEMA.pdf 28 settembre 2007]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_A/20071219CEMA.pdf 19 dicembre 2007]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_A/20080314CEMA.pdf 14 marzo 2008];<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_A/20080328CEMA.pdf 28 marzo 2008];<br><br><br />
:[[Media:20080620CEMA.pdf|20 giugno 2008]];<br><br><br />
:[[Media:2008_09_09_CEM_A.pdf|9 settembre 2008]];<br><br><br />
:[[Media:2009_03_18_CEM_A.pdf|18 marzo 2009]];<br><br><br />
:[[Media:20090624CEM_A.pdf|24 giugno 2009]];<br><br><br />
:[[Media:20090916CEM_A.pdf|16 settembre 2009]];<br><br><br />
<br />
:[http://lipari.ing.unimo.it/vincetti/es_campi_A.html Precedenti Anni Accademici]<br />
<br />
<br />
<br />
<br><br><br><br />
[[Image:home.gif|30px|left]] <br><br />
[[User:Apolemi | Home]]</div>Apolemihttps://web.ing.unimo.it/wiki/index.php?title=MATERIALE_DIDATTICO&diff=7060MATERIALE DIDATTICO2009-12-27T20:25:21Z<p>Apolemi: /* RADIOPROPAGAZIONE e SISTEMI RADIO E A MICROONDE */</p>
<hr />
<div>== RADIOPROPAGAZIONE e SISTEMI RADIO E A MICROONDE<br>==<br />
Il corso RADIOPROPAGAZIONE si ripropone di offrire allo studente tutto il bagaglio di conoscenze e informazioni connesse con il collegamento radio tra due o più utenti in un ambiente reale. A tal fine vengono ampiamente descritti i parametri fondamentali delle antenne, con particolare attenzione a quelle grandezze necessarie per caratterizzare il collegamento radio tra due punti. Con riferimento alle antenne usate nelle applicazioni wireless, vengono descritti i principi fondamentali per l'analisi ed il design delle antenna a microstriscia. A questo argomento è collegata una attività di laboratorio, che permette allo studente di imparare le principale tecniche di progetto delle antenne a microstriscia attraverso softwares commerciali. Mentre, con riferimento alle antenne usate nelle moderne applicazioni contactless, vengono descritti i principi fondamentali di funzionamento dei sistemi di identificazione a radiofrequenza (RFID). Infine il corso offre una ampia e dettagliata panoramica sulla caratterizzazione del canale radio, con riferimento sia al canale urbano (descrizione di modelli empirici, statistici e deterministici) sia alla propagazione Line-Of-Sight e ionosferica. <br>Il programma del corso è il seguente<br><br />
*Introduzione al corso<br />
*Richiami alle grandezze fondamentali delle antenne<br />
**Antenne in trasmissione: diagramma di radiazione, direttività e guadagno, impedenza di radiazione, efficienza <br />
**Antenne in ricezione: area efficace, formula di Friis del collegamento, rapporto segnale rumore <br />
*Antenne ad apertura <br />
**Richiami sulla trasformata di Fourier<br />
**Radiazione da aperture planari: l'apertura rettangolare e circolare, aperture con distribuzione di campo uniforme e non uniforme, radiazione di una slot <br />
*Antenne per applicazioni wireless <br />
**Antenne a patch <br />
***Caratteristiche generali <br />
***Tecniche di alimentazione <br />
***Tecniche di allargamento della banda <br />
***Uso di software CAD di simulazione elettromagnetica per il design di antenne a patch<br />
**Antenne ad array<br />
***Principi generali<br />
***Array broadside<br />
***Array endfire<br />
***Tecniche di alimentazione<br />
**Antenna a riflettore<br />
***Generalità<br />
***Riflettori parabolici (prime focus)<br />
***Riflettori offset e Cassegrain: cenni<br />
**Antenne horn<br />
***Principi di funzionamento<br />
***Distribuzione di apertura<br />
**Antenne e sistemi contactless short distance e very short distance: cenni sui sistemi di Radio Identificazione a Radio Frequenza (RFID) <br />
*Propagazione <br />
**Il canale urbano<br />
***Cenni sui metodi di descrizione dei meccanismi di propagazione: modelli empirici, statistici, e deterministici <br />
**Propagazione Line-of-Sight e interferenza per onda riflessa <br />
**Propagazione per onda di superficiale<br />
**Propagazione ionosferica <br><br><br />
<br />
TESTI CONSIGLIATI:<br><br><br />
<br />
Constantine A. Balanis, "Antenna Theory: Analysis and Design," John Wiley & Sons Inc., 1982 (1st ed.), 1997(2nd ed.)<br />
<br />
Constantine A. Balanis, "Advanced Engineering Electromagnetics", John Wiley & Sons Inc., 1989<br />
<br />
Robert E. Collin, "Antennas and RadioWave Propagation," McGraw-Hill Series in Electrical Engineering, 1985<br />
<br />
Sergei Alexander Schelkunoff, "Advanced antenna theory," 1952<br />
<br />
Lal C. Godara, "Handbook of Antennas in Wireless Communication," CRC Press, 2002<br />
<br />
R. Garg, P. Bhartia, I. Bahal, A. Ittipiboon , "Microstrip Antenna Design Handbook," Artech House, 2000<br />
<br />
Stutzman, Thiele, "Antenna Theory and Design," John Wiley & Sons Inc., 1981<br />
<br />
<br />
[[Image:logo148x154.gif|50 px]] [http://lipari.ing.unimo.it/polemi/radio/frequencies.pdf Spettro frequenze onde radio]<br><br><br />
[[Image:chip.jpg|90 px]] [http://lipari.ing.unimo.it/polemi/radio/dielettrici.pdf Materiali dielettrici]<br><br><br />
;[[Image:patch.gif|150 px]] Introduzione al software CST MicroWave Studio<br><br><br />
:[http://lipari.ing.unimo.it/polemi/Radio/introCST1.pdf Introduzione Laboratorio 1]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/Radio/introCST2.pdf Introduzione Laboratorio 2]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/Radio/introCST4.pdf Introduzione Laboratorio 3]<br><br><br />
;[[Image:rfid.jpg|50 px]] Tecnologie emergenti...<br><br><br />
:[http://lipari.ing.unimo.it/polemi/Radio/LA_TECNOLOGIA_RFID.pdf La tecnologia RFID] Courtesy of Prof. Gaetano Marrocco, University of Roma, Tor Vergata <br><br><br />
:[http://lipari.ing.unimo.it/polemi/Radio/Rfid 041209.pdf La tecnologia RFID] Courtesy of Prof. Gaetano Marrocco, University of Roma, Tor Vergata <br><br><br />
:[http://lipari.ing.unimo.it/polemi/Radio/EH_RF_@INGRE_short.pdf La tecnologia RFID] Courtesy of Prof. Gaetano Marrocco, University of Roma, Tor Vergata <br><br><br />
<br />
== MICROONDE<br> ==<br />
Per informazioni sul corso rivolgersi al titolare Prof. Vincetti<br><br><br />
;[[Image:microonde.jpg|90 px]] Introduzione al software CST MicroWave Studio<br><br><br />
:[http://lipari.ing.unimo.it/polemi/Micro/introCST1.pdf Intro CST 1]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/Micro/introCST2.pdf Intro CST 2]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/Micro/introCST3.pdf Intro CST 3]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/Micro/esempiodirelazione.pdf Esempio di relazione]<br><br><br />
<br />
<br />
== CAMPI ELETTROMAGNETICI B <br>==<br />
Per informazioni sul corso rivolgersi al titolare Prof. Zoboli<br><br><br />
;[[Image:dipoletto.jpg|30 px]] Radiazione<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_B/antennas1.pdf Antenna1]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_B/dipoleAnt.html Antenna2]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_B/dipoleAnt2.html Antenna3]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_B/laboratorio2008/CEMB.ppt Concetti di base sulle antenne filari]<br><br><br />
<br />
<br />
;[[Image:ospiti.gif|50px]] Testi d'esame<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_B/CB070626.pdf 26 giugno 2007]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_B/CB070717.pdf 17 luglio 2007]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_B/CB070911.pdf 11 settembre 2007]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_B/CB070928.pdf 28 settembre 2007]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_B/CB071219.pdf 19 dicembre 2007]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_B/CB080328.pdf 28 marzo 2008]<br><br><br />
:[[Media:CB080620.pdf|20 giugno 2008]];<br><br><br />
:[[Media:CB080717.pdf|17 luglio 2008]];<br><br><br />
:[[Media:CB_08-09-09.pdf|9 settembre 2008]];<br><br><br />
:[[Media:CB_09-03-18.pdf|18 marzo 2009]];<br><br><br />
:[[Media:CB090624.pdf|24 giugno 2009]];<br><br><br />
:[[Media:CB090715.pdf|15 luglio 2009]];<br><br><br />
:[[Media:CB090916.pdf|16 settembre 2009]];<br><br><br />
<br />
:[http://lipari.ing.unimo.it/vincetti/es_campi_B.html Precedenti Anni Accademici]<br />
<br />
== CAMPI ELETTROMAGNETICI A <br>==<br />
Per informazioni sul corso rivolgersi al titolare Prof. Zoboli<br><br><br />
;[[Image:dipoletto.jpg|30 px]] Linee di Trasmissione<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_A/smithchart.pdf Carta di Smith]<br><br><br />
<br />
<br />
;[[Image:ospiti.gif|50px]] Testi d'esame<br><br>:<br />
:[http://lipari.ing.unimo.it/polemi/CEM_A/20070321CEMA1.pdf 21 marzo 2007 (A)];[http://lipari.ing.unimo.it/polemi/CEM_A/20070321CEMA2.pdf 21 marzo 2007 (B)]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_A/20070412CEMA1.pdf 12 aprile 2007 (A)];[http://lipari.ing.unimo.it/polemi/CEM_A/20070412CEMA2.pdf 12 aprile 2007 (B)]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_A/20070626CEMA.pdf 26 giugno 2007]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_A/20070911CEMA.pdf 11 settembre 2007]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_A/20070928CEMA.pdf 28 settembre 2007]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_A/20071219CEMA.pdf 19 dicembre 2007]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_A/20080314CEMA.pdf 14 marzo 2008];<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_A/20080328CEMA.pdf 28 marzo 2008];<br><br><br />
:[[Media:20080620CEMA.pdf|20 giugno 2008]];<br><br><br />
:[[Media:2008_09_09_CEM_A.pdf|9 settembre 2008]];<br><br><br />
:[[Media:2009_03_18_CEM_A.pdf|18 marzo 2009]];<br><br><br />
:[[Media:20090624CEM_A.pdf|24 giugno 2009]];<br><br><br />
:[[Media:20090916CEM_A.pdf|16 settembre 2009]];<br><br><br />
<br />
:[http://lipari.ing.unimo.it/vincetti/es_campi_A.html Precedenti Anni Accademici]<br />
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[[User:Apolemi | Home]]</div>Apolemihttps://web.ing.unimo.it/wiki/index.php?title=MATERIALE_DIDATTICO&diff=7059MATERIALE DIDATTICO2009-12-27T20:24:59Z<p>Apolemi: /* RADIOPROPAGAZIONE */</p>
<hr />
<div>== RADIOPROPAGAZIONE e SISTEMI RADIO E A MICROONDE<br>==<br />
Il corso RADIOPROPAGAZIONE si ripropone di offrire allo studente tutto il bagaglio di conoscenze e informazioni connesse con il collegamento radio tra due o più utenti in un ambiente reale. A tal fine vengono ampiamente descritti i parametri fondamentali delle antenne, con particolare attenzione a quelle grandezze necessarie per caratterizzare il collegamento radio tra due punti. Con riferimento alle antenne usate nelle applicazioni wireless, vengono descritti i principi fondamentali per l'analisi ed il design delle antenna a microstriscia. A questo argomento è collegata una attività di laboratorio, che permette allo studente di imparare le principale tecniche di progetto delle antenne a microstriscia attraverso softwares commerciali. Mentre, con riferimento alle antenne usate nelle moderne applicazioni contactless, vengono descritti i principi fondamentali di funzionamento dei sistemi di identificazione a radiofrequenza (RFID). Infine il corso offre una ampia e dettagliata panoramica sulla caratterizzazione del canale radio, con riferimento sia al canale urbano (descrizione di modelli empirici, statistici e deterministici) sia alla propagazione Line-Of-Sight e ionosferica. <br>Il programma del corso è il seguente<br><br />
*Introduzione al corso<br />
*Richiami alle grandezze fondamentali delle antenne<br />
**Antenne in trasmissione: diagramma di radiazione, direttività e guadagno, impedenza di radiazione, efficienza <br />
**Antenne in ricezione: area efficace, formula di Friis del collegamento, rapporto segnale rumore <br />
*Antenne ad apertura <br />
**Richiami sulla trasformata di Fourier<br />
**Radiazione da aperture planari: l'apertura rettangolare e circolare, aperture con distribuzione di campo uniforme e non uniforme, radiazione di una slot <br />
*Antenne per applicazioni wireless <br />
**Antenne a patch <br />
***Caratteristiche generali <br />
***Tecniche di alimentazione <br />
***Tecniche di allargamento della banda <br />
***Uso di software CAD di simulazione elettromagnetica per il design di antenne a patch<br />
**Antenne ad array<br />
***Principi generali<br />
***Array broadside<br />
***Array endfire<br />
***Tecniche di alimentazione<br />
**Antenna a riflettore<br />
***Generalità<br />
***Riflettori parabolici (prime focus)<br />
***Riflettori offset e Cassegrain: cenni<br />
**Antenne horn<br />
***Principi di funzionamento<br />
***Distribuzione di apertura<br />
**Antenne e sistemi contactless short distance e very short distance: cenni sui sistemi di Radio Identificazione a Radio Frequenza (RFID) <br />
*Propagazione <br />
**Il canale urbano<br />
***Cenni sui metodi di descrizione dei meccanismi di propagazione: modelli empirici, statistici, e deterministici <br />
**Propagazione Line-of-Sight e interferenza per onda riflessa <br />
**Propagazione per onda di superficiale<br />
**Propagazione ionosferica <br><br><br />
<br />
TESTI CONSIGLIATI:<br><br><br />
<br />
Constantine A. Balanis, "Antenna Theory: Analysis and Design," John Wiley & Sons Inc., 1982 (1st ed.), 1997(2nd ed.)<br />
<br />
Constantine A. Balanis, "Advanced Engineering Electromagnetics", John Wiley & Sons Inc., 1989<br />
<br />
Robert E. Collin, "Antennas and RadioWave Propagation," McGraw-Hill Series in Electrical Engineering, 1985<br />
<br />
Sergei Alexander Schelkunoff, "Advanced antenna theory," 1952<br />
<br />
Lal C. Godara, "Handbook of Antennas in Wireless Communication," CRC Press, 2002<br />
<br />
R. Garg, P. Bhartia, I. Bahal, A. Ittipiboon , "Microstrip Antenna Design Handbook," Artech House, 2000<br />
<br />
Stutzman, Thiele, "Antenna Theory and Design," John Wiley & Sons Inc., 1981<br />
<br />
<br />
[[Image:logo148x154.gif|50 px]] [http://lipari.ing.unimo.it/polemi/radio/frequencies.pdf Spettro frequenze onde radio]<br><br><br />
[[Image:chip.jpg|90 px]] [http://lipari.ing.unimo.it/polemi/radio/dielettrici.pdf Materiali dielettrici]<br><br><br />
;[[Image:patch.gif|150 px]] Introduzione al software CST MicroWave Studio<br><br><br />
:[http://lipari.ing.unimo.it/polemi/Radio/introCST1.pdf Introduzione Laboratorio 1]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/Radio/introCST2.pdf Introduzione Laboratorio 2]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/Radio/introCST4.pdf Introduzione Laboratorio 3]<br><br><br />
;[[Image:rfid.jpg|50 px]] Tecnologie emergenti...<br><br><br />
:[http://lipari.ing.unimo.it/polemi/Radio/LA_TECNOLOGIA_RFID.pdf La tecnologia RFID] Courtesy of Prof. Gaetano Marrocco, University of Roma, Tor Vergata <br><br><br />
:[http://lipari.ing.unimo.it/polemi/Radio/Rfid_041209.pdf La tecnologia RFID] Courtesy of Prof. Gaetano Marrocco, University of Roma, Tor Vergata <br><br><br />
:[http://lipari.ing.unimo.it/polemi/Radio/EH_RF_@INGRE_short.pdf La tecnologia RFID] Courtesy of Prof. Gaetano Marrocco, University of Roma, Tor Vergata <br><br><br />
<br />
== MICROONDE<br> ==<br />
Per informazioni sul corso rivolgersi al titolare Prof. Vincetti<br><br><br />
;[[Image:microonde.jpg|90 px]] Introduzione al software CST MicroWave Studio<br><br><br />
:[http://lipari.ing.unimo.it/polemi/Micro/introCST1.pdf Intro CST 1]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/Micro/introCST2.pdf Intro CST 2]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/Micro/introCST3.pdf Intro CST 3]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/Micro/esempiodirelazione.pdf Esempio di relazione]<br><br><br />
<br />
<br />
== CAMPI ELETTROMAGNETICI B <br>==<br />
Per informazioni sul corso rivolgersi al titolare Prof. Zoboli<br><br><br />
;[[Image:dipoletto.jpg|30 px]] Radiazione<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_B/antennas1.pdf Antenna1]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_B/dipoleAnt.html Antenna2]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_B/dipoleAnt2.html Antenna3]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_B/laboratorio2008/CEMB.ppt Concetti di base sulle antenne filari]<br><br><br />
<br />
<br />
;[[Image:ospiti.gif|50px]] Testi d'esame<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_B/CB070626.pdf 26 giugno 2007]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_B/CB070717.pdf 17 luglio 2007]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_B/CB070911.pdf 11 settembre 2007]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_B/CB070928.pdf 28 settembre 2007]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_B/CB071219.pdf 19 dicembre 2007]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_B/CB080328.pdf 28 marzo 2008]<br><br><br />
:[[Media:CB080620.pdf|20 giugno 2008]];<br><br><br />
:[[Media:CB080717.pdf|17 luglio 2008]];<br><br><br />
:[[Media:CB_08-09-09.pdf|9 settembre 2008]];<br><br><br />
:[[Media:CB_09-03-18.pdf|18 marzo 2009]];<br><br><br />
:[[Media:CB090624.pdf|24 giugno 2009]];<br><br><br />
:[[Media:CB090715.pdf|15 luglio 2009]];<br><br><br />
:[[Media:CB090916.pdf|16 settembre 2009]];<br><br><br />
<br />
:[http://lipari.ing.unimo.it/vincetti/es_campi_B.html Precedenti Anni Accademici]<br />
<br />
== CAMPI ELETTROMAGNETICI A <br>==<br />
Per informazioni sul corso rivolgersi al titolare Prof. Zoboli<br><br><br />
;[[Image:dipoletto.jpg|30 px]] Linee di Trasmissione<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_A/smithchart.pdf Carta di Smith]<br><br><br />
<br />
<br />
;[[Image:ospiti.gif|50px]] Testi d'esame<br><br>:<br />
:[http://lipari.ing.unimo.it/polemi/CEM_A/20070321CEMA1.pdf 21 marzo 2007 (A)];[http://lipari.ing.unimo.it/polemi/CEM_A/20070321CEMA2.pdf 21 marzo 2007 (B)]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_A/20070412CEMA1.pdf 12 aprile 2007 (A)];[http://lipari.ing.unimo.it/polemi/CEM_A/20070412CEMA2.pdf 12 aprile 2007 (B)]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_A/20070626CEMA.pdf 26 giugno 2007]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_A/20070911CEMA.pdf 11 settembre 2007]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_A/20070928CEMA.pdf 28 settembre 2007]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_A/20071219CEMA.pdf 19 dicembre 2007]<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_A/20080314CEMA.pdf 14 marzo 2008];<br><br><br />
:[http://lipari.ing.unimo.it/polemi/CEM_A/20080328CEMA.pdf 28 marzo 2008];<br><br><br />
:[[Media:20080620CEMA.pdf|20 giugno 2008]];<br><br><br />
:[[Media:2008_09_09_CEM_A.pdf|9 settembre 2008]];<br><br><br />
:[[Media:2009_03_18_CEM_A.pdf|18 marzo 2009]];<br><br><br />
:[[Media:20090624CEM_A.pdf|24 giugno 2009]];<br><br><br />
:[[Media:20090916CEM_A.pdf|16 settembre 2009]];<br><br><br />
<br />
:[http://lipari.ing.unimo.it/vincetti/es_campi_A.html Precedenti Anni Accademici]<br />
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[[User:Apolemi | Home]]</div>Apolemihttps://web.ing.unimo.it/wiki/index.php?title=News_and_Events&diff=7055News and Events2009-12-27T20:17:49Z<p>Apolemi: /* NEWS */</p>
<hr />
<div>== EVENTS ==<br />
<br />
<br />
== NEWS ==<br />
<br />
- Seminario '''Tecnologia RFID: introduzione e applicazioni''' nell'ambito del corso Sistemi Radio e a Microonde e del corso di Radiopropagazione. Partecipazione dei gruppi di ricerca di informatica ed elettronica. '''Venerdì 4 Dicembre, ore 14.30-17.00, Facoltà di Ingegneria, Modena, aula FA-2G'''. Scarica la locandina [[Media:RFID_UniMoRe_v2.0.pdf| flyer]]. Le presentazioni relative all'evento sono disponibili.<br><br />
<br />
- LE LEZIONI DI RADIOPROPAGAZIONE INIZIERANNO IL GIORNO MARTEDì 17 NOVEMBRE P.V.<br />
<br><br />
<br />
- I will be visiting the Department of Electric and System Engineering at University of Pennsylvania from Oct 1st to Nov 6th. For any communication, please contact me at my email address.<br><br />
<br />
- The student Erio Gandini has been selected for the Phd program at the [http://www.univ-rennes1.fr/ University of Rennes], starting from October 2009, in the framework of a joint project between IETr and Thalès Alenia Space (TAS).<br><br />
<br />
<br />
- Collaboration with [http://www.ese.upenn.edu/ Electric and System Engineering Department] at [http://www.upenn.edu/ University of Pennsylvania] with Prof. Nader Engheta, within metamaterials and nanotechnologies at optical frequencies.<br><br><br />
<br />
- Collaboration with [http://www.esa.int/ European Space Agency] for the realization of an electromagnetic tool for beam tracing in complex environments, such as satellite platforms.<br><br><br />
<br />
- Collaboration with [http://www.univ-rennes1.fr/ University of Rennes] in the framework of an european Research Network Program (RNP) on "New frontiers in millimetre / sub-millimetre waves integrated dielectric focusing systems".<br><br><br />
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[[Image:home.gif|30px|left]] <br><br />
[[User:Apolemi | Home]]</div>Apolemihttps://web.ing.unimo.it/wiki/index.php?title=My_Curriculum_Vitae&diff=7043My Curriculum Vitae2009-12-09T14:28:16Z<p>Apolemi: /* PRESENT EMPLOYMENT */</p>
<hr />
<div>'''(LAST UPDATE: 07/12/2009)'''<br><br />
<br />
===PERSONAL INFORMATION===<br />
[[Office address:]] <br><br />
Department of Information Engineering <br><br />
University of Modena and Reggio Emilia <br><br />
Via Vignolese 905<br><br />
41100 Modena, ITALY<br><br />
Tel. +39 059 2056326<br><br />
Fax. +39 059 2056129<br><br />
Mobile: +39 335 7181823<br><br />
E-mail: [mailto:alessia.polemi@unimore.it alessia.polemi@unimore.it]<br><br />
E-mail: [mailto:apolemi@seas.upenn.edu apolemi@seas.upenn.edu]<br><br />
web-site: http://www.dii.unimore.it/polemi<br><br />
[[Home address:]] <br><br />
Via San Faustino 123/10<br><br />
41100 Modena,ITALY<br><br><br />
<br />
===EDUCATION===<br />
* July 1999: M.S. (cum laude) in Telecommunication Engineering at University of Siena. Thesis dissertation: "Green’s Functions for phased arrays of dipoles on dielectric slab" (supervisors: Prof. S. Maci, Prof. R. Tiberio, Prof. A. Toccafondi). <br><br><br />
* January 2000: national qualification for engineers at the University of Florence. <br><br><br />
* March 2003: PhD in Information Engineering (curriculum: electromagnetic waves) at the University of Siena. Thesis dissertation: "Frequency Domain Green's Function for Periodic Large Phased Arrays in Multilayered Dielectric Regions " (tutor: Prof. R. Tiberio). <br><br><br />
* January 2003-October 2006: post-doc researcher at the Department of Information Engineering, University of Siena<br><br><br />
<br />
===PRESENT EMPLOYMENT===<br />
* November 2006: Assistant Professor at the School of Engineering of University of Modena and Reggio Emilia (scientific area: ELECTROMAGNETIC FIELDS)<br />
<br />
* November 2009: tenure track as Assistant Professor at the School of Engineering of University of Modena and Reggio Emilia (scientific area: ELECTROMAGNETIC FIELDS)<br />
<br />
===RESEARCH INTERESTS===<br />
* High frequency scattering theories<br><br />
* Asymptotics electromagnetic methods<br><br />
* Numerical electromagnetic methods<br><br />
* Periodic structures<br><br />
* Bandgap structures<br><br />
* Antenna design<br><br />
* Antenna miniaturization<br><br />
* Wideband and ultrawideband antennas<br><br />
* RFID systems<br><br />
* Printed devices at microwave frequencies<br><br />
* New emerging waveguides<br><br />
* Metamaterials <br><br />
* Polaritons at optical frequency<br><br />
Further details in [[Research Activity]] section. <br><br><br />
<br />
===PROFESSIONAL SOCIETIES===<br />
* 1999, appointed to the profession of Engineer <br><br><br />
* 2000, Member of the Institute of Electrical and Electronic Engineers (IEEE) <br><br><br />
* September 2003-December 2005, president of the academic spin-off company WaveComm srl.<br><br><br />
* 2006, Italian Student Adviser for the Institution of Engineering and Technology (IET) <br><br><br />
<br><br><br />
<br />
===SOFTWARE SKILLS AND COMPETENCE===<br />
* Operating systems MS Windows 98/NT/2k/XP/Vista <br><br />
* MS Office<br><br />
* Maltlab<br><br />
* CorelDraw<br><br />
* Latex<br><br />
* Fortran<br><br />
* C<br><br />
* Mathematica<br><br />
* Electromagnetic simulation software<br><br />
** Ansoft Designer<br><br />
** HFSS<br><br />
** CST Microwave Studio<br><br />
** Grasp<br><br />
** FEKO<br><br />
** MicroWave Office<br><br />
** Wipl-d<br><br><br />
<br />
===TEACHING ACTIVITY===<br />
* 1999/2000, seminars in the Electromagnetic Field course at the School of Engineering of University of Siena <br><br />
* 2000/2001, seminars in the Microwave course at the School of Engineering of University of Siena <br><br />
* 2001/2002, seminars in the Antennas course at the School of Engineering of University of Siena <br><br />
* 2002/2003, course of Design of Microwave Circuits at the School of Engineering of University of Siena <br><br />
* 2003, course of Numerical Methods for Electromagnetics at the Master on Microwave Systems on Technologies for Telecommunications, Messina (Italy) <br><br />
* 2003/2004 and 2004/2005, course of Electromagnetic Modelling at the School of Engineering of University of Siena <br><br />
* 2005, seminars into the school “High Frequency Methods and Travelling Wave Antennas”, European School of Antennas (ACE – Antenna Centre of Excellence), at University of Siena, about:<br><br />
** Green’s function of the dielectric slab<br> <br />
** Scattering from a perfectly conducting half-plane<br><br><br />
* Since 2005: <br><br />
** course of Radio Propagation class at the School of Engineering of University of Modena and Reggio Emilia<br><br />
** assisting in the Electromagnetic Field class at the School of Engineering of University of Modena and Reggio Emilia<br><br />
** Microwave Lab class at the School of Engineering of University of Modena and Reggio Emilia<br><br><br />
<br />
Visit the page [[Teaching Activity]] for Teaching Statement . <br><br><br />
<br />
===STUDENT SUPERVISED===<br />
* 2001 M.S. "Giacomo Donzelli", GENERALIZED PENCIL OF FUNCTION TECHNIQUE FOR MULTILAYERED PRINTED STRUCTURES<br><br />
* 2002 M.S. "Alberto Nencini", ASYMPTOTIC GREEN'S FUNCTION FOR A SECTORAL ARRAY OF ELEMENTARY SOURCES ON A DIELECTRIC SLAB<br> <br />
* 2005 M.S. "Giorgio Carluccio", EXTENSION OF THE INCREMENTAL THEORY OF DIFFRACTION TO COMPLEX SOURCES <br><br />
* 2006 M.S. "Michele Gravina", ANTENNA FOR BIOMEDICAL RFID APPLICATION<br><br />
* 2006 M.S. "Daniele Ciccarese", WIMAX: MAN WIRELESS TECHNOLOGY <br><br />
* 2007 M.S. "Guido Santamaria", ELECTROMAGNETIC CHARACTERIZATION OF TRANSITIONS BETWEEN COAXIAL CABLE AND MICROSTRIP<br><br />
* 2007 M.S. "Lorenzo Santunione", DESIGN AND CHARACTERIZATION OF A PRINTED DIPOLE ANTENNA WITH UNBALNCED FEEDING<br><br />
* 2007 Laurea Degree. "Enrico Busi", ANALYSIS AND DESIGN OF A PLANAR ANTENNA FOR UWB APPLICATIONS<br><br />
* 2008 M.S. "Marcello di Clemente", SAW SENSORS<br><br />
* 2008 Laurea Degree. "Gagliardi Giuseppina", WIDE BAND PATCH ANTENNAS DESIGN<br><br />
* 2008 M.S. "Javier Molejón Asenjo", DESIGN OF A DUAL BAND ANTENNA FOR RFID APPLICATIONS IN THE UHF BAND <br><br />
* 2009 M.S. "Luca Morandini", DEVICES FOR THE MONITORING OF ELECTROMAGNETIC INTERFERENCES DURING TIMING IN SPORT RACES, THROUGHOUT RFID SYSTEMS<br><br />
* 2009 M.S. "Erio Gandini", ANALYSIS OF BACKSCATTERING FROM PLANAR FRESNEL LENSES<br><br><br />
<br />
===ATTENDED SPECIALIZED PHD COURSES===<br />
* 2000, at University of Siena <br><br />
** Functional analysis elements <br><br />
** Interpolation and approximation of curves and surfaces <br> <br />
** Optimization Methods <br><br />
** Wavelets <br><br />
** Object Oriented Programming <br><br />
* 2002, at Chalmers University, Gotheborg, Sweden <br><br />
** Artificial Magnetic Conductors and Soft and Hard surfaces and their Use in Antenna Analysis and Design <br><br />
* 2002, at University of Ancona, PhD School <br><br />
** Ground Penetrating Radar <br><br />
*2005, at Denmark Technical University - Ticra, European School of Antennas (ACE - Antenna Center of Excellence) <br><br />
** Reflector antennas: analysis and design <br><br />
* 2005, at Politecnico of Turin, European School of Antennas (ACE - Antenna Center of Excellence) <br><br />
** Computational EM for antenna analysis <br><br />
* 2005, at University of Siena, European School of Antennas (ACE - Antenna Center of Excellence) <br><br />
** High Frequency Methods and Travelling Wave Antennas <br><br />
* 2006, at University of Dubrovnik, European School of Antennas (ACE - Antenna Center of Excellence) <br><br />
** Advanced Mathematics for Antenna Analysis <br><br><br />
<br />
===NATIONAL RESEARCH PROGRAMS===<br />
* 2000-2002. PAR (Piano d’Ateneo per la Ricerca) “Antenna installation for wireless communication systems”<br><br />
* 2000-2002. ASI (Italian Space Agency): “Reflectarrays for satellite applications” <br><br />
* 2003-2005. PRIN (Progetto di ricerca di interesse nazionale) “Electromagnetic models for analysis of passive reflectarrays”<br><br />
* 2005-2007. PRIN (Progetto di ricerca di interesse nazionale) “Microwave Radiometer for fire monitoring” <br><br><br />
<br />
===INTERNATIONAL RESEARCH PROGRAMS===<br />
* 2004-2005. ACE Antenna Centre of Excellence, V Framework Program, WP. 1.1.1 Integration, WP. 3.1.1 European School of Antennas<br><br />
* 2005-2006. ACE Antennas Centre of Excellence, VI Framework Program, WP. 3.1.1 European School of Antennas<br><br />
* 2005-2007. EAML European Antenna Modeling Library, contract with ESA-ESTEC n.18802/04/NL/JD, WP. 1.6.1.0 5S Green’s Function for stratified environment<br><br />
* 2009-ongoing. EAML European Antenna Modeling Library, TT&C Coverage in Complex Environments <br><br />
* 2009-ongoing. EuroStar Project, New production process for medical bags based on RadioFrequency sterilization and ICT<br><br><br />
<br />
===RESEARCH CONTRACTS===<br />
* 2000-2001. Research contract between Department of Information Engineering (University of Siena) - IDS spa, in the framework of the agreement with Italian Navy for "Electromagnetic models for prediction of scattering objects" <br><br />
* 2000-2002. Research contract Department of Information Engineering (University of Siena) - IDS spa, in the framework of the agreement with IDS spa for "Green’s function for multilayered materials"<br><br />
* 2002-2003. Research contract Department of Information Engineering (University of Siena) - IDS spa, in the framework of the agreement with IDS spa for "Incremental Theory of Diffraction for dielectric screens"<br> <br />
* 2003-2004. Research contract with Consorzio Etruria ed Innovazione scpa, entitled "Feasibility and design of an automatic identification system on controlled areas based on the standard ISO/IEC 15693" <br><br />
* 2004-2005. Research contract with Consorzio Etruria ed Innovazione scpa, entitled "Electromagnetic scattering from non perfectly conducting half-planes and junctions between planes: UTD and ITD formulation" <br><br />
* 2005-2006. Research contract Department of Information Engineering (University of Siena) - IDS spa, in the framework of the agreement with IDS spa for "Green’s functions for dielectric multilayers; extension to magnetic sources" <br><br />
* 2007-2008. Research contract Department of Information Engineering (University of Modena and Reggio Emilia) -Politecnico di Torino, entitled "Evolution and evolutionary maintenance of European Antenna Modeling Library Components" <br><br />
* 2008. Research contract Department of Information Engineering (University of Modena and Reggio Emilia) –MD-Microdetectors (protected by NDA) <br> <br><br />
<br />
===PUBLICATIONS===<br />
[http://www.dii.unimo.it/wiki/index.php/My_publications Publications]<br />
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[[Image:home.gif|30px|left]] <br><br />
[[User:Apolemi | Home]]</div>Apolemihttps://web.ing.unimo.it/wiki/index.php?title=User:Apolemi&diff=7042User:Apolemi2009-12-09T14:27:37Z<p>Apolemi: </p>
<hr />
<div>[[Image:Alessia_2009.jpg|180px|left]] <br />
address: Dipartimento di Ingegneria dell'Informazione, via Vignolese 905, Modena, Italy, I-41125<br> <br />
tel: +39-059-2056326<br> <br />
fax: +39-059-2056129<br> <br />
email: [mailto:alessia.polemi@unimore.it alessia.polemi@unimore.it] <br> <br />
<br> <br />
Alessia Polemi was born in Casteldelpiano, Grosseto, Italy, on July 10, 1973. She received her Doctor of Engineering degree in Telecommunications Engineering(cum laude) from the [http://www.unisi.it University of Siena] in July 1999 discussing a thesis about the [http://lipari.ing.unimo.it/polemi/tesi.pdf Array Green's Function for a Semi-Infinite Array of Dipoles on a Grounded Slab.] <br />
<br />
From November 1999 to October 2002 she was a Ph.D student at the [http://www.dii.unisi.it Department of Information Engineering (DII)] of the University of Siena. She received a Ph.D. degree in Information Engineering in March 2003 with a thesis entitled [http://lipari.ing.unimo.it/polemi/phd_thesis.pdf Frequency-Domain Green’s Function for Planar Periodic Large Phased Arrays in Multilayered Dielectric Regions.]<br />
<br />
From January 2003 to October 2006 she was a post doctorate researcher at the Department of Information Engineering of the University of Siena. During the PhD and post-doc period she attended several different international PhD classes and European schools. <br />
<br />
She serves as a reviewer for important international journals on electrical engineering and electromagnetics such as IEEE, IET, Elsevier Journals and Transactions. <br />
<br />
Since November 2006 she has been an Assistant Professor of Electromagnetic Fields at the [http://www.ing.unimo.it School of Engineering,] within the [http://www.dii.unimo.it Department of Information Engineering] of the [http://www.unimo.it University of Modena and Reggio Emilia,] where she is teaching Radiopropagation and she is the assistant at the course on Electromagnetic Fields. <br />
<br />
Since 2008, she has been frequently a visiting professor at the [http://www.upenn.edu University of Pennsylvania], in Philadelphia, working on plasmonic structures with [http://www.ese.upenn.edu/~engheta Prof. Nader Engheta] and his group. <br />
<br />
Since 2000 she is member of the [http://www.ieee.org Institute of Electrical and Electronic Engineers (IEEE)] and since November 2006 she has been the Italian Student Adviser for the [http://www.iet.org Institution of Engineering and Technology (IET)]. <br />
<br />
In November 2009, she has obtained the tenure track as Assistant Professor at the [http://www.ing.unimo.it School of Engineering,] within the [http://www.dii.unimo.it Department of Information Engineering] of the [http://www.unimo.it University of Modena and Reggio Emilia].<br />
<br />
Her current research includes high frequency scattering theories, asymptotics electromagnetic methods, numerical electromagnetic methods, periodic structures, bandgap structures, antenna design, antenna miniaturization, wideband and ultrawideband antennas, RFID systems, printed devices at microwave frequencies, new emerging waveguides, metamaterials and polaritons at optical frequency. For further details, see [[Research Activity]] section<br />
<br><br><br />
----<br />
* [[My Curriculum Vitae]] (and [[Media:CV_ALESSIA_POLEMI.pdf|pdf]] version) <br> <br> <br />
* [[Research Activity]] <br> <br><br />
* [[My publications]] <br> <br><br />
* [[Teaching Activity]] <br> <br><br />
* [[MATERIALE DIDATTICO]] <br><br><br />
----<br />
;[[Image:news.gif|120px]] [[News and Events]]<br />
----</div>Apolemihttps://web.ing.unimo.it/wiki/index.php?title=User:Apolemi&diff=7041User:Apolemi2009-12-09T14:27:18Z<p>Apolemi: </p>
<hr />
<div>[[Image:Alessia_2009.jpg|180px|left]] <br />
address: Dipartimento di Ingegneria dell'Informazione, via Vignolese 905, Modena, Italy, I-41125<br> <br />
tel: +39-059-2056326<br> <br />
fax: +39-059-2056129<br> <br />
email: [mailto:alessia.polemi@unimore.it alessia.polemi@unimore.it] <br> <br />
<br> <br />
Alessia Polemi was born in Casteldelpiano, Grosseto, Italy, on July 10, 1973. She received her Doctor of Engineering degree in Telecommunications Engineering(cum laude) from the [http://www.unisi.it University of Siena] in July 1999 discussing a thesis about the [http://lipari.ing.unimo.it/polemi/tesi.pdf Array Green's Function for a Semi-Infinite Array of Dipoles on a Grounded Slab.] <br />
<br />
From November 1999 to October 2002 she was a Ph.D student at the [http://www.dii.unisi.it Department of Information Engineering (DII)] of the University of Siena. She received a Ph.D. degree in Information Engineering in March 2003 with a thesis entitled [http://lipari.ing.unimo.it/polemi/phd_thesis.pdf Frequency-Domain Green’s Function for Planar Periodic Large Phased Arrays in Multilayered Dielectric Regions.]<br />
<br />
From January 2003 to October 2006 she was a post doctorate researcher at the Department of Information Engineering of the University of Siena. During the PhD and post-doc period she attended several different international PhD classes and European schools. <br />
<br />
She serves as a reviewer for important international journals on electrical engineering and electromagnetics such as IEEE, IET, Elsevier Journals and Transactions. <br />
<br />
Since November 2006 she has been an Assistant Professor of Electromagnetic Fields at the [http://www.ing.unimo.it School of Engineering,] within the [http://www.dii.unimo.it Department of Information Engineering] of the [http://www.unimo.it University of Modena and Reggio Emilia,] where she is teaching Radiopropagation and she is the assistant at the course on Electromagnetic Fields. <br />
<br />
Since 2008, she has been frequently a visiting professor at the [http://www.upenn.edu University of Pennsylvania], in Philadelphia, working on plasmonic structures with [http://www.ese.upenn.edu/~engheta Prof. Nader Engheta] and his group. <br />
<br />
Since 2000 she is member of the [http://www.ieee.org Institute of Electrical and Electronic Engineers (IEEE)] and since November 2006 she has been the Italian Student Adviser for the [http://www.iet.org Institution of Engineering and Technology (IET)]. <br />
<br />
In November 2009, she has abtained the tenure track as Assistant Professor at the [http://www.ing.unimo.it School of Engineering,] within the [http://www.dii.unimo.it Department of Information Engineering] of the [http://www.unimo.it University of Modena and Reggio Emilia].<br />
<br />
Her current research includes high frequency scattering theories, asymptotics electromagnetic methods, numerical electromagnetic methods, periodic structures, bandgap structures, antenna design, antenna miniaturization, wideband and ultrawideband antennas, RFID systems, printed devices at microwave frequencies, new emerging waveguides, metamaterials and polaritons at optical frequency. For further details, see [[Research Activity]] section<br />
<br><br><br />
----<br />
* [[My Curriculum Vitae]] (and [[Media:CV_ALESSIA_POLEMI.pdf|pdf]] version) <br> <br> <br />
* [[Research Activity]] <br> <br><br />
* [[My publications]] <br> <br><br />
* [[Teaching Activity]] <br> <br><br />
* [[MATERIALE DIDATTICO]] <br><br><br />
----<br />
;[[Image:news.gif|120px]] [[News and Events]]<br />
----</div>Apolemihttps://web.ing.unimo.it/wiki/index.php?title=News_and_Events&diff=7040News and Events2009-12-08T19:54:17Z<p>Apolemi: </p>
<hr />
<div>== EVENTS ==<br />
<br />
<br />
== NEWS ==<br />
<br />
- Seminario '''Tecnologia RFID: introduzione e applicazioni''' nell'ambito del corso Sistemi Radio e a Microonde e del corso di Radiopropagazione. Partecipazione dei gruppi di ricerca di informatica ed elettronica. '''Venerdì 4 Dicembre, ore 14.30-17.00, Facoltà di Ingegneria, Modena, aula FA-2G'''. Scarica la locandina [[Media:RFID_UniMoRe_v2.0.pdf| flyer]]<br><br />
<br />
- LE LEZIONI DI RADIOPROPAGAZIONE INIZIERANNO IL GIORNO MARTEDì 17 NOVEMBRE P.V.<br />
<br><br />
<br />
- I will be visiting the Department of Electric and System Engineering at University of Pennsylvania from Oct 1st to Nov 6th. For any communication, please contact me at my email address.<br><br />
<br />
- The student Erio Gandini has been selected for the Phd program at the [http://www.univ-rennes1.fr/ University of Rennes], starting from October 2009, in the framework of a joint project between IETr and Thalès Alenia Space (TAS).<br><br />
<br />
<br />
- Collaboration with [http://www.ese.upenn.edu/ Electric and System Engineering Department] at [http://www.upenn.edu/ University of Pennsylvania] with Prof. Nader Engheta, within metamaterials and nanotechnologies at optical frequencies.<br><br><br />
<br />
- Collaboration with [http://www.esa.int/ European Space Agency] for the realization of an electromagnetic tool for beam tracing in complex environments, such as satellite platforms.<br><br><br />
<br />
- Collaboration with [http://www.univ-rennes1.fr/ University of Rennes] in the framework of an european Research Network Program (RNP) on "New frontiers in millimetre / sub-millimetre waves integrated dielectric focusing systems".<br><br><br />
<br />
<br />
<br><br><br><br />
[[Image:home.gif|30px|left]] <br><br />
[[User:Apolemi | Home]]</div>Apolemihttps://web.ing.unimo.it/wiki/index.php?title=User:Apolemi&diff=7035User:Apolemi2009-12-02T07:59:26Z<p>Apolemi: </p>
<hr />
<div>[[Image:Alessia_2009.jpg|180px|left]] <br />
address: Dipartimento di Ingegneria dell'Informazione, via Vignolese 905, Modena, Italy, I-41125<br> <br />
tel: +39-059-2056326<br> <br />
fax: +39-059-2056129<br> <br />
email: [mailto:alessia.polemi@unimore.it alessia.polemi@unimore.it] <br> <br />
<br> <br />
Alessia Polemi was born in Casteldelpiano, Grosseto, Italy, on July 10, 1973. She received her Doctor of Engineering degree in Telecommunications Engineering(cum laude) from the [http://www.unisi.it University of Siena] in July 1999 discussing a thesis about the [http://lipari.ing.unimo.it/polemi/tesi.pdf Array Green's Function for a Semi-Infinite Array of Dipoles on a Grounded Slab.] <br />
<br />
From November 1999 to October 2002 she was a Ph.D student at the [http://www.dii.unisi.it Department of Information Engineering (DII)] of the University of Siena. She received a Ph.D. degree in Information Engineering in March 2003 with a thesis entitled [http://lipari.ing.unimo.it/polemi/phd_thesis.pdf Frequency-Domain Green’s Function for Planar Periodic Large Phased Arrays in Multilayered Dielectric Regions.]<br />
<br />
From January 2003 to October 2006 she was a post doctorate researcher at the Department of Information Engineering of the University of Siena. During the PhD and post-doc period she attended several different international PhD classes and European schools. <br />
<br />
She serves as a reviewer for important international journals on electrical engineering and electromagnetics such as IEEE, IET, Elsevier Journals and Transactions. <br />
<br />
Since November 2006 she has been an Assistant Professor of Electromagnetic Fields at the [http://www.ing.unimo.it School of Engineering,] within the [http://www.dii.unimo.it Department of Information Engineering] of the [http://www.unimo.it University of Modena and Reggio Emilia,] where she is teaching Radiopropagation and she is the assistant at the course on Electromagnetic Fields. <br />
<br />
Since 2008, she has been frequently a visiting professor at the [http://www.upenn.edu University of Pennsylvania], in Philadelphia, working on plasmonic structures with [http://www.ese.upenn.edu/~engheta Prof. Nader Engheta] and his group. <br />
<br />
Since 2000 she is member of the [http://www.ieee.org Institute of Electrical and Electronic Engineers (IEEE)] and since November 2006 she has been the Italian Student Adviser for the [http://www.iet.org Institution of Engineering and Technology (IET)]. <br />
<br />
Her current research includes high frequency scattering theories, asymptotics electromagnetic methods, numerical electromagnetic methods, periodic structures, bandgap structures, antenna design, antenna miniaturization, wideband and ultrawideband antennas, RFID systems, printed devices at microwave frequencies, new emerging waveguides, metamaterials and polaritons at optical frequency. For further details, see [[Research Activity]] section<br />
<br><br><br />
----<br />
* [[My Curriculum Vitae]] (and [[Media:CV_ALESSIA_POLEMI.pdf|pdf]] version) <br> <br> <br />
* [[Research Activity]] <br> <br><br />
* [[My publications]] <br> <br><br />
* [[Teaching Activity]] <br> <br><br />
* [[MATERIALE DIDATTICO]] <br><br><br />
----<br />
;[[Image:news.gif|120px]] [[News and Events]]<br />
----</div>Apolemihttps://web.ing.unimo.it/wiki/index.php?title=User:Apolemi&diff=7033User:Apolemi2009-12-02T07:48:17Z<p>Apolemi: </p>
<hr />
<div>[[Image:ale1.jpg|180px|left]] <br />
address: Dipartimento di Ingegneria dell'Informazione, via Vignolese 905, Modena, Italy, I-41125<br> <br />
tel: +39-059-2056326<br> <br />
fax: +39-059-2056129<br> <br />
email: [mailto:alessia.polemi@unimore.it alessia.polemi@unimore.it] <br> <br />
<br> <br />
Alessia Polemi was born in Casteldelpiano, Grosseto, Italy, on July 10, 1973. She received her Doctor of Engineering degree in Telecommunications Engineering(cum laude) from the [http://www.unisi.it University of Siena] in July 1999 discussing a thesis about the [http://lipari.ing.unimo.it/polemi/tesi.pdf Array Green's Function for a Semi-Infinite Array of Dipoles on a Grounded Slab.] <br />
<br />
From November 1999 to October 2002 she was a Ph.D student at the [http://www.dii.unisi.it Department of Information Engineering (DII)] of the University of Siena. She received a Ph.D. degree in Information Engineering in March 2003 with a thesis entitled [http://lipari.ing.unimo.it/polemi/phd_thesis.pdf Frequency-Domain Green’s Function for Planar Periodic Large Phased Arrays in Multilayered Dielectric Regions.]<br />
<br />
From January 2003 to October 2006 she was a post doctorate researcher at the Department of Information Engineering of the University of Siena. During the PhD and post-doc period she attended several different international PhD classes and European schools. <br />
<br />
She serves as a reviewer for important international journals on electrical engineering and electromagnetics such as IEEE, IET, Elsevier Journals and Transactions. <br />
<br />
Since November 2006 she has been an Assistant Professor of Electromagnetic Fields at the [http://www.ing.unimo.it School of Engineering,] within the [http://www.dii.unimo.it Department of Information Engineering] of the [http://www.unimo.it University of Modena and Reggio Emilia,] where she is teaching Radiopropagation and she is the assistant at the course on Electromagnetic Fields. <br />
<br />
Since 2008, she has been frequently a visiting professor at the [http://www.upenn.edu University of Pennsylvania], in Philadelphia, working on plasmonic structures with [http://www.ese.upenn.edu/~engheta Prof. Nader Engheta] and his group. <br />
<br />
Since 2000 she is member of the [http://www.ieee.org Institute of Electrical and Electronic Engineers (IEEE)] and since November 2006 she has been the Italian Student Adviser for the [http://www.iet.org Institution of Engineering and Technology (IET)]. <br />
<br />
Her current research includes high frequency scattering theories, asymptotics electromagnetic methods, numerical electromagnetic methods, periodic structures, bandgap structures, antenna design, antenna miniaturization, wideband and ultrawideband antennas, RFID systems, printed devices at microwave frequencies, new emerging waveguides, metamaterials and polaritons at optical frequency. For further details, see [[Research Activity]] section<br />
<br><br><br />
----<br />
* [[My Curriculum Vitae]] (and [[Media:CV_ALESSIA_POLEMI.pdf|pdf]] version) <br> <br> <br />
* [[Research Activity]] <br> <br><br />
* [[My publications]] <br> <br><br />
* [[Teaching Activity]] <br> <br><br />
* [[MATERIALE DIDATTICO]] <br><br><br />
----<br />
;[[Image:news.gif|120px]] [[News and Events]]<br />
----</div>Apolemihttps://web.ing.unimo.it/wiki/index.php?title=News_and_Events&diff=7032News and Events2009-12-02T07:46:44Z<p>Apolemi: /* EVENTS */</p>
<hr />
<div>== EVENTS ==<br />
- Seminario '''Tecnologia RFID: introduzione e applicazioni''' nell'ambito del corso Sistemi Radio e a Microonde e del corso di Radiopropagazione. Partecipazione dei gruppi di ricerca di informatica ed elettronica. '''Venerdì 4 Dicembre, ore 14.30-17.00, Facoltà di Ingegneria, Modena, aula FA-2G'''. Scarica la locandina [[Media:RFID_UniMoRe_v2.0.pdf| flyer]]<br />
<br />
== NEWS ==<br />
- LE LEZIONI DI RADIOPROPAGAZIONE INIZIERANNO IL GIORNO MARTEDì 17 NOVEMBRE P.V.<br />
<br><br />
<br />
- I will be visiting the Department of Electric and System Engineering at University of Pennsylvania from Oct 1st to Nov 6th. For any communication, please contact me at my email address.<br><br />
<br />
- The student Erio Gandini has been selected for the Phd program at the [http://www.univ-rennes1.fr/ University of Rennes], starting from October 2009, in the framework of a joint project between IETr and Thalès Alenia Space (TAS).<br><br />
<br />
<br />
- Collaboration with [http://www.ese.upenn.edu/ Electric and System Engineering Department] at [http://www.upenn.edu/ University of Pennsylvania] with Prof. Nader Engheta, within metamaterials and nanotechnologies at optical frequencies.<br><br><br />
<br />
- Collaboration with [http://www.esa.int/ European Space Agency] for the realization of an electromagnetic tool for beam tracing in complex environments, such as satellite platforms.<br><br><br />
<br />
- Collaboration with [http://www.univ-rennes1.fr/ University of Rennes] in the framework of an european Research Network Program (RNP) on "New frontiers in millimetre / sub-millimetre waves integrated dielectric focusing systems".<br><br><br />
<br />
<br />
<br><br><br><br />
[[Image:home.gif|30px|left]] <br><br />
[[User:Apolemi | Home]]</div>Apolemihttps://web.ing.unimo.it/wiki/index.php?title=News_and_Events&diff=7031News and Events2009-12-02T07:45:55Z<p>Apolemi: /* EVENTS */</p>
<hr />
<div>== EVENTS ==<br />
- Seminario '''Tecnologia RFID: introduzione e applicazioni''' nell'ambito del corso Sistemi Radio e a Microonde e del corso di Radiopropagazione. Partecipazione dei gruppi di ricerca di informatica ed elettronica. Venerdì 4 Dicembre, ore 14.30-17.00, Facoltà di Ingegneria, Modena, aula FA-2G. Scarica la locandina [[Media:RFID_UniMoRe_v2.0.pdf| flyer]]<br />
<br />
== NEWS ==<br />
- LE LEZIONI DI RADIOPROPAGAZIONE INIZIERANNO IL GIORNO MARTEDì 17 NOVEMBRE P.V.<br />
<br><br />
<br />
- I will be visiting the Department of Electric and System Engineering at University of Pennsylvania from Oct 1st to Nov 6th. For any communication, please contact me at my email address.<br><br />
<br />
- The student Erio Gandini has been selected for the Phd program at the [http://www.univ-rennes1.fr/ University of Rennes], starting from October 2009, in the framework of a joint project between IETr and Thalès Alenia Space (TAS).<br><br />
<br />
<br />
- Collaboration with [http://www.ese.upenn.edu/ Electric and System Engineering Department] at [http://www.upenn.edu/ University of Pennsylvania] with Prof. Nader Engheta, within metamaterials and nanotechnologies at optical frequencies.<br><br><br />
<br />
- Collaboration with [http://www.esa.int/ European Space Agency] for the realization of an electromagnetic tool for beam tracing in complex environments, such as satellite platforms.<br><br><br />
<br />
- Collaboration with [http://www.univ-rennes1.fr/ University of Rennes] in the framework of an european Research Network Program (RNP) on "New frontiers in millimetre / sub-millimetre waves integrated dielectric focusing systems".<br><br><br />
<br />
<br />
<br><br><br><br />
[[Image:home.gif|30px|left]] <br><br />
[[User:Apolemi | Home]]</div>Apolemihttps://web.ing.unimo.it/wiki/index.php?title=File:RFID_UniMoRe_v2.0.pdf&diff=7030File:RFID UniMoRe v2.0.pdf2009-12-02T07:45:29Z<p>Apolemi: </p>
<hr />
<div></div>Apolemihttps://web.ing.unimo.it/wiki/index.php?title=News_and_Events&diff=7026News and Events2009-11-21T11:30:12Z<p>Apolemi: /* EVENTS */</p>
<hr />
<div>== EVENTS ==<br />
- I will give a seminar at the IET event '''Innovation strategy with RFID''' at the Museo della Tecnica Elettrica, Pavia, Italy, November 13th, 2009. Download the [[Media:IET_Italy_RFID-Nov2009.pdf| flyer]] and the [[Media:Programme_IET13nov09.pdf| program]] of the event.<br />
<br />
== NEWS ==<br />
- LE LEZIONI DI RADIOPROPAGAZIONE INIZIERANNO IL GIORNO MARTEDì 17 NOVEMBRE P.V.<br />
<br><br />
<br />
- I will be visiting the Department of Electric and System Engineering at University of Pennsylvania from Oct 1st to Nov 6th. For any communication, please contact me at my email address.<br><br />
<br />
- The student Erio Gandini has been selected for the Phd program at the [http://www.univ-rennes1.fr/ University of Rennes], starting from October 2009, in the framework of a joint project between IETr and Thalès Alenia Space (TAS).<br><br />
<br />
<br />
- Collaboration with [http://www.ese.upenn.edu/ Electric and System Engineering Department] at [http://www.upenn.edu/ University of Pennsylvania] with Prof. Nader Engheta, within metamaterials and nanotechnologies at optical frequencies.<br><br><br />
<br />
- Collaboration with [http://www.esa.int/ European Space Agency] for the realization of an electromagnetic tool for beam tracing in complex environments, such as satellite platforms.<br><br><br />
<br />
- Collaboration with [http://www.univ-rennes1.fr/ University of Rennes] in the framework of an european Research Network Program (RNP) on "New frontiers in millimetre / sub-millimetre waves integrated dielectric focusing systems".<br><br><br />
<br />
<br />
<br><br><br><br />
[[Image:home.gif|30px|left]] <br><br />
[[User:Apolemi | Home]]</div>Apolemihttps://web.ing.unimo.it/wiki/index.php?title=My_Curriculum_Vitae&diff=7022My Curriculum Vitae2009-11-21T11:17:27Z<p>Apolemi: /* RESEARCH CONTRACTS */</p>
<hr />
<div>'''(LAST UPDATE: 07/12/2009)'''<br><br />
<br />
===PERSONAL INFORMATION===<br />
[[Office address:]] <br><br />
Department of Information Engineering <br><br />
University of Modena and Reggio Emilia <br><br />
Via Vignolese 905<br><br />
41100 Modena, ITALY<br><br />
Tel. +39 059 2056326<br><br />
Fax. +39 059 2056129<br><br />
Mobile: +39 335 7181823<br><br />
E-mail: [mailto:alessia.polemi@unimore.it alessia.polemi@unimore.it]<br><br />
E-mail: [mailto:apolemi@seas.upenn.edu apolemi@seas.upenn.edu]<br><br />
web-site: http://www.dii.unimore.it/polemi<br><br />
[[Home address:]] <br><br />
Via San Faustino 123/10<br><br />
41100 Modena,ITALY<br><br><br />
<br />
===EDUCATION===<br />
* July 1999: M.S. (cum laude) in Telecommunication Engineering at University of Siena. Thesis dissertation: "Green’s Functions for phased arrays of dipoles on dielectric slab" (supervisors: Prof. S. Maci, Prof. R. Tiberio, Prof. A. Toccafondi). <br><br><br />
* January 2000: national qualification for engineers at the University of Florence. <br><br><br />
* March 2003: PhD in Information Engineering (curriculum: electromagnetic waves) at the University of Siena. Thesis dissertation: "Frequency Domain Green's Function for Periodic Large Phased Arrays in Multilayered Dielectric Regions " (tutor: Prof. R. Tiberio). <br><br><br />
* January 2003-October 2006: post-doc researcher at the Department of Information Engineering, University of Siena<br><br><br />
<br />
===PRESENT EMPLOYMENT===<br />
* November 2006: Assistant Professor at the School of Engineering of University of Modena and Reggio Emilia (scientific area: ELECTROMAGNETIC FIELDS)<br />
<br />
===RESEARCH INTERESTS===<br />
* High frequency scattering theories<br><br />
* Asymptotics electromagnetic methods<br><br />
* Numerical electromagnetic methods<br><br />
* Periodic structures<br><br />
* Bandgap structures<br><br />
* Antenna design<br><br />
* Antenna miniaturization<br><br />
* Wideband and ultrawideband antennas<br><br />
* RFID systems<br><br />
* Printed devices at microwave frequencies<br><br />
* New emerging waveguides<br><br />
* Metamaterials <br><br />
* Polaritons at optical frequency<br><br />
Further details in [[Research Activity]] section. <br><br><br />
<br />
===PROFESSIONAL SOCIETIES===<br />
* 1999, appointed to the profession of Engineer <br><br><br />
* 2000, Member of the Institute of Electrical and Electronic Engineers (IEEE) <br><br><br />
* September 2003-December 2005, president of the academic spin-off company WaveComm srl.<br><br><br />
* 2006, Italian Student Adviser for the Institution of Engineering and Technology (IET) <br><br><br />
<br><br><br />
<br />
===SOFTWARE SKILLS AND COMPETENCE===<br />
* Operating systems MS Windows 98/NT/2k/XP/Vista <br><br />
* MS Office<br><br />
* Maltlab<br><br />
* CorelDraw<br><br />
* Latex<br><br />
* Fortran<br><br />
* C<br><br />
* Mathematica<br><br />
* Electromagnetic simulation software<br><br />
** Ansoft Designer<br><br />
** HFSS<br><br />
** CST Microwave Studio<br><br />
** Grasp<br><br />
** FEKO<br><br />
** MicroWave Office<br><br />
** Wipl-d<br><br><br />
<br />
===TEACHING ACTIVITY===<br />
* 1999/2000, seminars in the Electromagnetic Field course at the School of Engineering of University of Siena <br><br />
* 2000/2001, seminars in the Microwave course at the School of Engineering of University of Siena <br><br />
* 2001/2002, seminars in the Antennas course at the School of Engineering of University of Siena <br><br />
* 2002/2003, course of Design of Microwave Circuits at the School of Engineering of University of Siena <br><br />
* 2003, course of Numerical Methods for Electromagnetics at the Master on Microwave Systems on Technologies for Telecommunications, Messina (Italy) <br><br />
* 2003/2004 and 2004/2005, course of Electromagnetic Modelling at the School of Engineering of University of Siena <br><br />
* 2005, seminars into the school “High Frequency Methods and Travelling Wave Antennas”, European School of Antennas (ACE – Antenna Centre of Excellence), at University of Siena, about:<br><br />
** Green’s function of the dielectric slab<br> <br />
** Scattering from a perfectly conducting half-plane<br><br><br />
* Since 2005: <br><br />
** course of Radio Propagation class at the School of Engineering of University of Modena and Reggio Emilia<br><br />
** assisting in the Electromagnetic Field class at the School of Engineering of University of Modena and Reggio Emilia<br><br />
** Microwave Lab class at the School of Engineering of University of Modena and Reggio Emilia<br><br><br />
<br />
Visit the page [[Teaching Activity]] for Teaching Statement . <br><br><br />
<br />
===STUDENT SUPERVISED===<br />
* 2001 M.S. "Giacomo Donzelli", GENERALIZED PENCIL OF FUNCTION TECHNIQUE FOR MULTILAYERED PRINTED STRUCTURES<br><br />
* 2002 M.S. "Alberto Nencini", ASYMPTOTIC GREEN'S FUNCTION FOR A SECTORAL ARRAY OF ELEMENTARY SOURCES ON A DIELECTRIC SLAB<br> <br />
* 2005 M.S. "Giorgio Carluccio", EXTENSION OF THE INCREMENTAL THEORY OF DIFFRACTION TO COMPLEX SOURCES <br><br />
* 2006 M.S. "Michele Gravina", ANTENNA FOR BIOMEDICAL RFID APPLICATION<br><br />
* 2006 M.S. "Daniele Ciccarese", WIMAX: MAN WIRELESS TECHNOLOGY <br><br />
* 2007 M.S. "Guido Santamaria", ELECTROMAGNETIC CHARACTERIZATION OF TRANSITIONS BETWEEN COAXIAL CABLE AND MICROSTRIP<br><br />
* 2007 M.S. "Lorenzo Santunione", DESIGN AND CHARACTERIZATION OF A PRINTED DIPOLE ANTENNA WITH UNBALNCED FEEDING<br><br />
* 2007 Laurea Degree. "Enrico Busi", ANALYSIS AND DESIGN OF A PLANAR ANTENNA FOR UWB APPLICATIONS<br><br />
* 2008 M.S. "Marcello di Clemente", SAW SENSORS<br><br />
* 2008 Laurea Degree. "Gagliardi Giuseppina", WIDE BAND PATCH ANTENNAS DESIGN<br><br />
* 2008 M.S. "Javier Molejón Asenjo", DESIGN OF A DUAL BAND ANTENNA FOR RFID APPLICATIONS IN THE UHF BAND <br><br />
* 2009 M.S. "Luca Morandini", DEVICES FOR THE MONITORING OF ELECTROMAGNETIC INTERFERENCES DURING TIMING IN SPORT RACES, THROUGHOUT RFID SYSTEMS<br><br />
* 2009 M.S. "Erio Gandini", ANALYSIS OF BACKSCATTERING FROM PLANAR FRESNEL LENSES<br><br><br />
<br />
===ATTENDED SPECIALIZED PHD COURSES===<br />
* 2000, at University of Siena <br><br />
** Functional analysis elements <br><br />
** Interpolation and approximation of curves and surfaces <br> <br />
** Optimization Methods <br><br />
** Wavelets <br><br />
** Object Oriented Programming <br><br />
* 2002, at Chalmers University, Gotheborg, Sweden <br><br />
** Artificial Magnetic Conductors and Soft and Hard surfaces and their Use in Antenna Analysis and Design <br><br />
* 2002, at University of Ancona, PhD School <br><br />
** Ground Penetrating Radar <br><br />
*2005, at Denmark Technical University - Ticra, European School of Antennas (ACE - Antenna Center of Excellence) <br><br />
** Reflector antennas: analysis and design <br><br />
* 2005, at Politecnico of Turin, European School of Antennas (ACE - Antenna Center of Excellence) <br><br />
** Computational EM for antenna analysis <br><br />
* 2005, at University of Siena, European School of Antennas (ACE - Antenna Center of Excellence) <br><br />
** High Frequency Methods and Travelling Wave Antennas <br><br />
* 2006, at University of Dubrovnik, European School of Antennas (ACE - Antenna Center of Excellence) <br><br />
** Advanced Mathematics for Antenna Analysis <br><br><br />
<br />
===NATIONAL RESEARCH PROGRAMS===<br />
* 2000-2002. PAR (Piano d’Ateneo per la Ricerca) “Antenna installation for wireless communication systems”<br><br />
* 2000-2002. ASI (Italian Space Agency): “Reflectarrays for satellite applications” <br><br />
* 2003-2005. PRIN (Progetto di ricerca di interesse nazionale) “Electromagnetic models for analysis of passive reflectarrays”<br><br />
* 2005-2007. PRIN (Progetto di ricerca di interesse nazionale) “Microwave Radiometer for fire monitoring” <br><br><br />
<br />
===INTERNATIONAL RESEARCH PROGRAMS===<br />
* 2004-2005. ACE Antenna Centre of Excellence, V Framework Program, WP. 1.1.1 Integration, WP. 3.1.1 European School of Antennas<br><br />
* 2005-2006. ACE Antennas Centre of Excellence, VI Framework Program, WP. 3.1.1 European School of Antennas<br><br />
* 2005-2007. EAML European Antenna Modeling Library, contract with ESA-ESTEC n.18802/04/NL/JD, WP. 1.6.1.0 5S Green’s Function for stratified environment<br><br />
* 2009-ongoing. EAML European Antenna Modeling Library, TT&C Coverage in Complex Environments <br><br />
* 2009-ongoing. EuroStar Project, New production process for medical bags based on RadioFrequency sterilization and ICT<br><br><br />
<br />
===RESEARCH CONTRACTS===<br />
* 2000-2001. Research contract between Department of Information Engineering (University of Siena) - IDS spa, in the framework of the agreement with Italian Navy for "Electromagnetic models for prediction of scattering objects" <br><br />
* 2000-2002. Research contract Department of Information Engineering (University of Siena) - IDS spa, in the framework of the agreement with IDS spa for "Green’s function for multilayered materials"<br><br />
* 2002-2003. Research contract Department of Information Engineering (University of Siena) - IDS spa, in the framework of the agreement with IDS spa for "Incremental Theory of Diffraction for dielectric screens"<br> <br />
* 2003-2004. Research contract with Consorzio Etruria ed Innovazione scpa, entitled "Feasibility and design of an automatic identification system on controlled areas based on the standard ISO/IEC 15693" <br><br />
* 2004-2005. Research contract with Consorzio Etruria ed Innovazione scpa, entitled "Electromagnetic scattering from non perfectly conducting half-planes and junctions between planes: UTD and ITD formulation" <br><br />
* 2005-2006. Research contract Department of Information Engineering (University of Siena) - IDS spa, in the framework of the agreement with IDS spa for "Green’s functions for dielectric multilayers; extension to magnetic sources" <br><br />
* 2007-2008. Research contract Department of Information Engineering (University of Modena and Reggio Emilia) -Politecnico di Torino, entitled "Evolution and evolutionary maintenance of European Antenna Modeling Library Components" <br><br />
* 2008. Research contract Department of Information Engineering (University of Modena and Reggio Emilia) –MD-Microdetectors (protected by NDA) <br> <br><br />
<br />
===PUBLICATIONS===<br />
[http://www.dii.unimo.it/wiki/index.php/My_publications Publications]<br />
<br />
<br />
<br><br><br><br />
[[Image:home.gif|30px|left]] <br><br />
[[User:Apolemi | Home]]</div>Apolemihttps://web.ing.unimo.it/wiki/index.php?title=My_Curriculum_Vitae&diff=7021My Curriculum Vitae2009-11-21T11:16:52Z<p>Apolemi: /* RESEARCH CONTRACTS */</p>
<hr />
<div>'''(LAST UPDATE: 07/12/2009)'''<br><br />
<br />
===PERSONAL INFORMATION===<br />
[[Office address:]] <br><br />
Department of Information Engineering <br><br />
University of Modena and Reggio Emilia <br><br />
Via Vignolese 905<br><br />
41100 Modena, ITALY<br><br />
Tel. +39 059 2056326<br><br />
Fax. +39 059 2056129<br><br />
Mobile: +39 335 7181823<br><br />
E-mail: [mailto:alessia.polemi@unimore.it alessia.polemi@unimore.it]<br><br />
E-mail: [mailto:apolemi@seas.upenn.edu apolemi@seas.upenn.edu]<br><br />
web-site: http://www.dii.unimore.it/polemi<br><br />
[[Home address:]] <br><br />
Via San Faustino 123/10<br><br />
41100 Modena,ITALY<br><br><br />
<br />
===EDUCATION===<br />
* July 1999: M.S. (cum laude) in Telecommunication Engineering at University of Siena. Thesis dissertation: "Green’s Functions for phased arrays of dipoles on dielectric slab" (supervisors: Prof. S. Maci, Prof. R. Tiberio, Prof. A. Toccafondi). <br><br><br />
* January 2000: national qualification for engineers at the University of Florence. <br><br><br />
* March 2003: PhD in Information Engineering (curriculum: electromagnetic waves) at the University of Siena. Thesis dissertation: "Frequency Domain Green's Function for Periodic Large Phased Arrays in Multilayered Dielectric Regions " (tutor: Prof. R. Tiberio). <br><br><br />
* January 2003-October 2006: post-doc researcher at the Department of Information Engineering, University of Siena<br><br><br />
<br />
===PRESENT EMPLOYMENT===<br />
* November 2006: Assistant Professor at the School of Engineering of University of Modena and Reggio Emilia (scientific area: ELECTROMAGNETIC FIELDS)<br />
<br />
===RESEARCH INTERESTS===<br />
* High frequency scattering theories<br><br />
* Asymptotics electromagnetic methods<br><br />
* Numerical electromagnetic methods<br><br />
* Periodic structures<br><br />
* Bandgap structures<br><br />
* Antenna design<br><br />
* Antenna miniaturization<br><br />
* Wideband and ultrawideband antennas<br><br />
* RFID systems<br><br />
* Printed devices at microwave frequencies<br><br />
* New emerging waveguides<br><br />
* Metamaterials <br><br />
* Polaritons at optical frequency<br><br />
Further details in [[Research Activity]] section. <br><br><br />
<br />
===PROFESSIONAL SOCIETIES===<br />
* 1999, appointed to the profession of Engineer <br><br><br />
* 2000, Member of the Institute of Electrical and Electronic Engineers (IEEE) <br><br><br />
* September 2003-December 2005, president of the academic spin-off company WaveComm srl.<br><br><br />
* 2006, Italian Student Adviser for the Institution of Engineering and Technology (IET) <br><br><br />
<br><br><br />
<br />
===SOFTWARE SKILLS AND COMPETENCE===<br />
* Operating systems MS Windows 98/NT/2k/XP/Vista <br><br />
* MS Office<br><br />
* Maltlab<br><br />
* CorelDraw<br><br />
* Latex<br><br />
* Fortran<br><br />
* C<br><br />
* Mathematica<br><br />
* Electromagnetic simulation software<br><br />
** Ansoft Designer<br><br />
** HFSS<br><br />
** CST Microwave Studio<br><br />
** Grasp<br><br />
** FEKO<br><br />
** MicroWave Office<br><br />
** Wipl-d<br><br><br />
<br />
===TEACHING ACTIVITY===<br />
* 1999/2000, seminars in the Electromagnetic Field course at the School of Engineering of University of Siena <br><br />
* 2000/2001, seminars in the Microwave course at the School of Engineering of University of Siena <br><br />
* 2001/2002, seminars in the Antennas course at the School of Engineering of University of Siena <br><br />
* 2002/2003, course of Design of Microwave Circuits at the School of Engineering of University of Siena <br><br />
* 2003, course of Numerical Methods for Electromagnetics at the Master on Microwave Systems on Technologies for Telecommunications, Messina (Italy) <br><br />
* 2003/2004 and 2004/2005, course of Electromagnetic Modelling at the School of Engineering of University of Siena <br><br />
* 2005, seminars into the school “High Frequency Methods and Travelling Wave Antennas”, European School of Antennas (ACE – Antenna Centre of Excellence), at University of Siena, about:<br><br />
** Green’s function of the dielectric slab<br> <br />
** Scattering from a perfectly conducting half-plane<br><br><br />
* Since 2005: <br><br />
** course of Radio Propagation class at the School of Engineering of University of Modena and Reggio Emilia<br><br />
** assisting in the Electromagnetic Field class at the School of Engineering of University of Modena and Reggio Emilia<br><br />
** Microwave Lab class at the School of Engineering of University of Modena and Reggio Emilia<br><br><br />
<br />
Visit the page [[Teaching Activity]] for Teaching Statement . <br><br><br />
<br />
===STUDENT SUPERVISED===<br />
* 2001 M.S. "Giacomo Donzelli", GENERALIZED PENCIL OF FUNCTION TECHNIQUE FOR MULTILAYERED PRINTED STRUCTURES<br><br />
* 2002 M.S. "Alberto Nencini", ASYMPTOTIC GREEN'S FUNCTION FOR A SECTORAL ARRAY OF ELEMENTARY SOURCES ON A DIELECTRIC SLAB<br> <br />
* 2005 M.S. "Giorgio Carluccio", EXTENSION OF THE INCREMENTAL THEORY OF DIFFRACTION TO COMPLEX SOURCES <br><br />
* 2006 M.S. "Michele Gravina", ANTENNA FOR BIOMEDICAL RFID APPLICATION<br><br />
* 2006 M.S. "Daniele Ciccarese", WIMAX: MAN WIRELESS TECHNOLOGY <br><br />
* 2007 M.S. "Guido Santamaria", ELECTROMAGNETIC CHARACTERIZATION OF TRANSITIONS BETWEEN COAXIAL CABLE AND MICROSTRIP<br><br />
* 2007 M.S. "Lorenzo Santunione", DESIGN AND CHARACTERIZATION OF A PRINTED DIPOLE ANTENNA WITH UNBALNCED FEEDING<br><br />
* 2007 Laurea Degree. "Enrico Busi", ANALYSIS AND DESIGN OF A PLANAR ANTENNA FOR UWB APPLICATIONS<br><br />
* 2008 M.S. "Marcello di Clemente", SAW SENSORS<br><br />
* 2008 Laurea Degree. "Gagliardi Giuseppina", WIDE BAND PATCH ANTENNAS DESIGN<br><br />
* 2008 M.S. "Javier Molejón Asenjo", DESIGN OF A DUAL BAND ANTENNA FOR RFID APPLICATIONS IN THE UHF BAND <br><br />
* 2009 M.S. "Luca Morandini", DEVICES FOR THE MONITORING OF ELECTROMAGNETIC INTERFERENCES DURING TIMING IN SPORT RACES, THROUGHOUT RFID SYSTEMS<br><br />
* 2009 M.S. "Erio Gandini", ANALYSIS OF BACKSCATTERING FROM PLANAR FRESNEL LENSES<br><br><br />
<br />
===ATTENDED SPECIALIZED PHD COURSES===<br />
* 2000, at University of Siena <br><br />
** Functional analysis elements <br><br />
** Interpolation and approximation of curves and surfaces <br> <br />
** Optimization Methods <br><br />
** Wavelets <br><br />
** Object Oriented Programming <br><br />
* 2002, at Chalmers University, Gotheborg, Sweden <br><br />
** Artificial Magnetic Conductors and Soft and Hard surfaces and their Use in Antenna Analysis and Design <br><br />
* 2002, at University of Ancona, PhD School <br><br />
** Ground Penetrating Radar <br><br />
*2005, at Denmark Technical University - Ticra, European School of Antennas (ACE - Antenna Center of Excellence) <br><br />
** Reflector antennas: analysis and design <br><br />
* 2005, at Politecnico of Turin, European School of Antennas (ACE - Antenna Center of Excellence) <br><br />
** Computational EM for antenna analysis <br><br />
* 2005, at University of Siena, European School of Antennas (ACE - Antenna Center of Excellence) <br><br />
** High Frequency Methods and Travelling Wave Antennas <br><br />
* 2006, at University of Dubrovnik, European School of Antennas (ACE - Antenna Center of Excellence) <br><br />
** Advanced Mathematics for Antenna Analysis <br><br><br />
<br />
===NATIONAL RESEARCH PROGRAMS===<br />
* 2000-2002. PAR (Piano d’Ateneo per la Ricerca) “Antenna installation for wireless communication systems”<br><br />
* 2000-2002. ASI (Italian Space Agency): “Reflectarrays for satellite applications” <br><br />
* 2003-2005. PRIN (Progetto di ricerca di interesse nazionale) “Electromagnetic models for analysis of passive reflectarrays”<br><br />
* 2005-2007. PRIN (Progetto di ricerca di interesse nazionale) “Microwave Radiometer for fire monitoring” <br><br><br />
<br />
===INTERNATIONAL RESEARCH PROGRAMS===<br />
* 2004-2005. ACE Antenna Centre of Excellence, V Framework Program, WP. 1.1.1 Integration, WP. 3.1.1 European School of Antennas<br><br />
* 2005-2006. ACE Antennas Centre of Excellence, VI Framework Program, WP. 3.1.1 European School of Antennas<br><br />
* 2005-2007. EAML European Antenna Modeling Library, contract with ESA-ESTEC n.18802/04/NL/JD, WP. 1.6.1.0 5S Green’s Function for stratified environment<br><br />
* 2009-ongoing. EAML European Antenna Modeling Library, TT&C Coverage in Complex Environments <br><br />
* 2009-ongoing. EuroStar Project, New production process for medical bags based on RadioFrequency sterilization and ICT<br><br><br />
<br />
===RESEARCH CONTRACTS===<br />
* 2000-2001. Research contract between Department of Information Engineering (University of Siena) - IDS spa, in the framework of the agreement with Italian Navy for "Electromagnetic models for prediction of scattering objects" <br><br />
* 2000-2002. Research contract Department of Information Engineering (University of Siena) - IDS spa, in the framework of the agreement with IDS spa for "Green’s function for multilayered materials"<br><br />
* 2002-2003. Research contract Department of Information Engineering (University of Siena) - IDS spa, in the framework of the agreement with IDS spa for "Incremental Theory of Diffraction for dielectric screens"<br> <br />
* 2003-2004. Research contract with Consorzio Etruria ed Innovazione scpa, entitled "Feasibility and design of an automatic identification system on controlled areas based on the standard ISO/IEC 15693" <br><br />
* 2004-2005. Research contract with Consorzio Etruria ed Innovazione scpa, entitled "Electromagnetic scattering from non perfectly conducting half-planes and junctions between planes: UTD and ITD formulation" <br><br />
* 2005-2006. Research contract Department of Information Engineering (University of Siena) - IDS spa, in the framework of the agreement with IDS spa for "Green’s functions for dielectric multilayers; extension to magnetic sources" <br><br />
* 2007-2008. Research contract Department of Information Engineering (University of Modena and Reggio Emilia) -Politecnico di Torino, entitled "Evolution and evolutionary maintenance of European Antenna Modeling Library Components" <br><br><br />
<br />
===PUBLICATIONS===<br />
[http://www.dii.unimo.it/wiki/index.php/My_publications Publications]<br />
<br />
<br />
<br><br><br><br />
[[Image:home.gif|30px|left]] <br><br />
[[User:Apolemi | Home]]</div>Apolemihttps://web.ing.unimo.it/wiki/index.php?title=My_Curriculum_Vitae&diff=7020My Curriculum Vitae2009-11-21T11:15:52Z<p>Apolemi: /* INTERNATIONAL RESEARCH PROGRAMS */</p>
<hr />
<div>'''(LAST UPDATE: 07/12/2009)'''<br><br />
<br />
===PERSONAL INFORMATION===<br />
[[Office address:]] <br><br />
Department of Information Engineering <br><br />
University of Modena and Reggio Emilia <br><br />
Via Vignolese 905<br><br />
41100 Modena, ITALY<br><br />
Tel. +39 059 2056326<br><br />
Fax. +39 059 2056129<br><br />
Mobile: +39 335 7181823<br><br />
E-mail: [mailto:alessia.polemi@unimore.it alessia.polemi@unimore.it]<br><br />
E-mail: [mailto:apolemi@seas.upenn.edu apolemi@seas.upenn.edu]<br><br />
web-site: http://www.dii.unimore.it/polemi<br><br />
[[Home address:]] <br><br />
Via San Faustino 123/10<br><br />
41100 Modena,ITALY<br><br><br />
<br />
===EDUCATION===<br />
* July 1999: M.S. (cum laude) in Telecommunication Engineering at University of Siena. Thesis dissertation: "Green’s Functions for phased arrays of dipoles on dielectric slab" (supervisors: Prof. S. Maci, Prof. R. Tiberio, Prof. A. Toccafondi). <br><br><br />
* January 2000: national qualification for engineers at the University of Florence. <br><br><br />
* March 2003: PhD in Information Engineering (curriculum: electromagnetic waves) at the University of Siena. Thesis dissertation: "Frequency Domain Green's Function for Periodic Large Phased Arrays in Multilayered Dielectric Regions " (tutor: Prof. R. Tiberio). <br><br><br />
* January 2003-October 2006: post-doc researcher at the Department of Information Engineering, University of Siena<br><br><br />
<br />
===PRESENT EMPLOYMENT===<br />
* November 2006: Assistant Professor at the School of Engineering of University of Modena and Reggio Emilia (scientific area: ELECTROMAGNETIC FIELDS)<br />
<br />
===RESEARCH INTERESTS===<br />
* High frequency scattering theories<br><br />
* Asymptotics electromagnetic methods<br><br />
* Numerical electromagnetic methods<br><br />
* Periodic structures<br><br />
* Bandgap structures<br><br />
* Antenna design<br><br />
* Antenna miniaturization<br><br />
* Wideband and ultrawideband antennas<br><br />
* RFID systems<br><br />
* Printed devices at microwave frequencies<br><br />
* New emerging waveguides<br><br />
* Metamaterials <br><br />
* Polaritons at optical frequency<br><br />
Further details in [[Research Activity]] section. <br><br><br />
<br />
===PROFESSIONAL SOCIETIES===<br />
* 1999, appointed to the profession of Engineer <br><br><br />
* 2000, Member of the Institute of Electrical and Electronic Engineers (IEEE) <br><br><br />
* September 2003-December 2005, president of the academic spin-off company WaveComm srl.<br><br><br />
* 2006, Italian Student Adviser for the Institution of Engineering and Technology (IET) <br><br><br />
<br><br><br />
<br />
===SOFTWARE SKILLS AND COMPETENCE===<br />
* Operating systems MS Windows 98/NT/2k/XP/Vista <br><br />
* MS Office<br><br />
* Maltlab<br><br />
* CorelDraw<br><br />
* Latex<br><br />
* Fortran<br><br />
* C<br><br />
* Mathematica<br><br />
* Electromagnetic simulation software<br><br />
** Ansoft Designer<br><br />
** HFSS<br><br />
** CST Microwave Studio<br><br />
** Grasp<br><br />
** FEKO<br><br />
** MicroWave Office<br><br />
** Wipl-d<br><br><br />
<br />
===TEACHING ACTIVITY===<br />
* 1999/2000, seminars in the Electromagnetic Field course at the School of Engineering of University of Siena <br><br />
* 2000/2001, seminars in the Microwave course at the School of Engineering of University of Siena <br><br />
* 2001/2002, seminars in the Antennas course at the School of Engineering of University of Siena <br><br />
* 2002/2003, course of Design of Microwave Circuits at the School of Engineering of University of Siena <br><br />
* 2003, course of Numerical Methods for Electromagnetics at the Master on Microwave Systems on Technologies for Telecommunications, Messina (Italy) <br><br />
* 2003/2004 and 2004/2005, course of Electromagnetic Modelling at the School of Engineering of University of Siena <br><br />
* 2005, seminars into the school “High Frequency Methods and Travelling Wave Antennas”, European School of Antennas (ACE – Antenna Centre of Excellence), at University of Siena, about:<br><br />
** Green’s function of the dielectric slab<br> <br />
** Scattering from a perfectly conducting half-plane<br><br><br />
* Since 2005: <br><br />
** course of Radio Propagation class at the School of Engineering of University of Modena and Reggio Emilia<br><br />
** assisting in the Electromagnetic Field class at the School of Engineering of University of Modena and Reggio Emilia<br><br />
** Microwave Lab class at the School of Engineering of University of Modena and Reggio Emilia<br><br><br />
<br />
Visit the page [[Teaching Activity]] for Teaching Statement . <br><br><br />
<br />
===STUDENT SUPERVISED===<br />
* 2001 M.S. "Giacomo Donzelli", GENERALIZED PENCIL OF FUNCTION TECHNIQUE FOR MULTILAYERED PRINTED STRUCTURES<br><br />
* 2002 M.S. "Alberto Nencini", ASYMPTOTIC GREEN'S FUNCTION FOR A SECTORAL ARRAY OF ELEMENTARY SOURCES ON A DIELECTRIC SLAB<br> <br />
* 2005 M.S. "Giorgio Carluccio", EXTENSION OF THE INCREMENTAL THEORY OF DIFFRACTION TO COMPLEX SOURCES <br><br />
* 2006 M.S. "Michele Gravina", ANTENNA FOR BIOMEDICAL RFID APPLICATION<br><br />
* 2006 M.S. "Daniele Ciccarese", WIMAX: MAN WIRELESS TECHNOLOGY <br><br />
* 2007 M.S. "Guido Santamaria", ELECTROMAGNETIC CHARACTERIZATION OF TRANSITIONS BETWEEN COAXIAL CABLE AND MICROSTRIP<br><br />
* 2007 M.S. "Lorenzo Santunione", DESIGN AND CHARACTERIZATION OF A PRINTED DIPOLE ANTENNA WITH UNBALNCED FEEDING<br><br />
* 2007 Laurea Degree. "Enrico Busi", ANALYSIS AND DESIGN OF A PLANAR ANTENNA FOR UWB APPLICATIONS<br><br />
* 2008 M.S. "Marcello di Clemente", SAW SENSORS<br><br />
* 2008 Laurea Degree. "Gagliardi Giuseppina", WIDE BAND PATCH ANTENNAS DESIGN<br><br />
* 2008 M.S. "Javier Molejón Asenjo", DESIGN OF A DUAL BAND ANTENNA FOR RFID APPLICATIONS IN THE UHF BAND <br><br />
* 2009 M.S. "Luca Morandini", DEVICES FOR THE MONITORING OF ELECTROMAGNETIC INTERFERENCES DURING TIMING IN SPORT RACES, THROUGHOUT RFID SYSTEMS<br><br />
* 2009 M.S. "Erio Gandini", ANALYSIS OF BACKSCATTERING FROM PLANAR FRESNEL LENSES<br><br><br />
<br />
===ATTENDED SPECIALIZED PHD COURSES===<br />
* 2000, at University of Siena <br><br />
** Functional analysis elements <br><br />
** Interpolation and approximation of curves and surfaces <br> <br />
** Optimization Methods <br><br />
** Wavelets <br><br />
** Object Oriented Programming <br><br />
* 2002, at Chalmers University, Gotheborg, Sweden <br><br />
** Artificial Magnetic Conductors and Soft and Hard surfaces and their Use in Antenna Analysis and Design <br><br />
* 2002, at University of Ancona, PhD School <br><br />
** Ground Penetrating Radar <br><br />
*2005, at Denmark Technical University - Ticra, European School of Antennas (ACE - Antenna Center of Excellence) <br><br />
** Reflector antennas: analysis and design <br><br />
* 2005, at Politecnico of Turin, European School of Antennas (ACE - Antenna Center of Excellence) <br><br />
** Computational EM for antenna analysis <br><br />
* 2005, at University of Siena, European School of Antennas (ACE - Antenna Center of Excellence) <br><br />
** High Frequency Methods and Travelling Wave Antennas <br><br />
* 2006, at University of Dubrovnik, European School of Antennas (ACE - Antenna Center of Excellence) <br><br />
** Advanced Mathematics for Antenna Analysis <br><br><br />
<br />
===NATIONAL RESEARCH PROGRAMS===<br />
* 2000-2002. PAR (Piano d’Ateneo per la Ricerca) “Antenna installation for wireless communication systems”<br><br />
* 2000-2002. ASI (Italian Space Agency): “Reflectarrays for satellite applications” <br><br />
* 2003-2005. PRIN (Progetto di ricerca di interesse nazionale) “Electromagnetic models for analysis of passive reflectarrays”<br><br />
* 2005-2007. PRIN (Progetto di ricerca di interesse nazionale) “Microwave Radiometer for fire monitoring” <br><br><br />
<br />
===INTERNATIONAL RESEARCH PROGRAMS===<br />
* 2004-2005. ACE Antenna Centre of Excellence, V Framework Program, WP. 1.1.1 Integration, WP. 3.1.1 European School of Antennas<br><br />
* 2005-2006. ACE Antennas Centre of Excellence, VI Framework Program, WP. 3.1.1 European School of Antennas<br><br />
* 2005-2007. EAML European Antenna Modeling Library, contract with ESA-ESTEC n.18802/04/NL/JD, WP. 1.6.1.0 5S Green’s Function for stratified environment<br><br />
* 2009-ongoing. EAML European Antenna Modeling Library, TT&C Coverage in Complex Environments <br><br />
* 2009-ongoing. EuroStar Project, New production process for medical bags based on RadioFrequency sterilization and ICT<br><br><br />
<br />
===RESEARCH CONTRACTS===<br />
Years 2000-2001. Research contract between Department of Information Engineering (University of Siena) - IDS spa, in the framework of the agreement with Italian Navy for "Electromagnetic models for prediction of scattering objects" <br><br />
<br />
Years 2000-2002. Research contract Department of Information Engineering (University of Siena) - IDS spa, in the framework of the agreement with IDS spa for "Green’s function for multilayered materials"<br><br />
<br />
Years 2002-2003. Research contract Department of Information Engineering (University of Siena) - IDS spa, in the framework of the agreement with IDS spa for "Incremental Theory of Diffraction for dielectric screens" <br><br />
<br />
Years 2003-2004. Research contract with Consorzio Etruria ed Innovazione scpa, entitled "Feasibility and design of an automatic identification system on controlled areas based on the standard ISO/IEC 15693" <br><br />
<br />
Years 2004-2005. Research contract with Consorzio Etruria ed Innovazione scpa, entitled "Electromagnetic scattering from non perfectly conducting half-planes and junctions between planes: UTD and ITD formulation" <br><br />
<br />
Years 2005-2006. Research contract Department of Information Engineering (University of Siena) - IDS spa, in the framework of the agreement with IDS spa for "Green’s functions for dielectric multilayers; extension to magnetic sources" <br><br />
<br />
Years 2007-2008. Research contract Department of Information Engineering (University of Modena and Reggio Emilia) -Politecnico di Torino, entitled "Evolution and evolutionary maintenance of European Antenna Modelling Library Components" <br><br />
<br />
Year 2008. Research contract Department of Information Engineering (University of Modena and Reggio Emilia) –MD-Microdetectors (protected by NDA)<br><br><br />
<br />
===PUBLICATIONS===<br />
[http://www.dii.unimo.it/wiki/index.php/My_publications Publications]<br />
<br />
<br />
<br><br><br><br />
[[Image:home.gif|30px|left]] <br><br />
[[User:Apolemi | Home]]</div>Apolemihttps://web.ing.unimo.it/wiki/index.php?title=My_Curriculum_Vitae&diff=7019My Curriculum Vitae2009-11-21T11:15:02Z<p>Apolemi: /* NATIONAL RESEARCH PROGRAMS */</p>
<hr />
<div>'''(LAST UPDATE: 07/12/2009)'''<br><br />
<br />
===PERSONAL INFORMATION===<br />
[[Office address:]] <br><br />
Department of Information Engineering <br><br />
University of Modena and Reggio Emilia <br><br />
Via Vignolese 905<br><br />
41100 Modena, ITALY<br><br />
Tel. +39 059 2056326<br><br />
Fax. +39 059 2056129<br><br />
Mobile: +39 335 7181823<br><br />
E-mail: [mailto:alessia.polemi@unimore.it alessia.polemi@unimore.it]<br><br />
E-mail: [mailto:apolemi@seas.upenn.edu apolemi@seas.upenn.edu]<br><br />
web-site: http://www.dii.unimore.it/polemi<br><br />
[[Home address:]] <br><br />
Via San Faustino 123/10<br><br />
41100 Modena,ITALY<br><br><br />
<br />
===EDUCATION===<br />
* July 1999: M.S. (cum laude) in Telecommunication Engineering at University of Siena. Thesis dissertation: "Green’s Functions for phased arrays of dipoles on dielectric slab" (supervisors: Prof. S. Maci, Prof. R. Tiberio, Prof. A. Toccafondi). <br><br><br />
* January 2000: national qualification for engineers at the University of Florence. <br><br><br />
* March 2003: PhD in Information Engineering (curriculum: electromagnetic waves) at the University of Siena. Thesis dissertation: "Frequency Domain Green's Function for Periodic Large Phased Arrays in Multilayered Dielectric Regions " (tutor: Prof. R. Tiberio). <br><br><br />
* January 2003-October 2006: post-doc researcher at the Department of Information Engineering, University of Siena<br><br><br />
<br />
===PRESENT EMPLOYMENT===<br />
* November 2006: Assistant Professor at the School of Engineering of University of Modena and Reggio Emilia (scientific area: ELECTROMAGNETIC FIELDS)<br />
<br />
===RESEARCH INTERESTS===<br />
* High frequency scattering theories<br><br />
* Asymptotics electromagnetic methods<br><br />
* Numerical electromagnetic methods<br><br />
* Periodic structures<br><br />
* Bandgap structures<br><br />
* Antenna design<br><br />
* Antenna miniaturization<br><br />
* Wideband and ultrawideband antennas<br><br />
* RFID systems<br><br />
* Printed devices at microwave frequencies<br><br />
* New emerging waveguides<br><br />
* Metamaterials <br><br />
* Polaritons at optical frequency<br><br />
Further details in [[Research Activity]] section. <br><br><br />
<br />
===PROFESSIONAL SOCIETIES===<br />
* 1999, appointed to the profession of Engineer <br><br><br />
* 2000, Member of the Institute of Electrical and Electronic Engineers (IEEE) <br><br><br />
* September 2003-December 2005, president of the academic spin-off company WaveComm srl.<br><br><br />
* 2006, Italian Student Adviser for the Institution of Engineering and Technology (IET) <br><br><br />
<br><br><br />
<br />
===SOFTWARE SKILLS AND COMPETENCE===<br />
* Operating systems MS Windows 98/NT/2k/XP/Vista <br><br />
* MS Office<br><br />
* Maltlab<br><br />
* CorelDraw<br><br />
* Latex<br><br />
* Fortran<br><br />
* C<br><br />
* Mathematica<br><br />
* Electromagnetic simulation software<br><br />
** Ansoft Designer<br><br />
** HFSS<br><br />
** CST Microwave Studio<br><br />
** Grasp<br><br />
** FEKO<br><br />
** MicroWave Office<br><br />
** Wipl-d<br><br><br />
<br />
===TEACHING ACTIVITY===<br />
* 1999/2000, seminars in the Electromagnetic Field course at the School of Engineering of University of Siena <br><br />
* 2000/2001, seminars in the Microwave course at the School of Engineering of University of Siena <br><br />
* 2001/2002, seminars in the Antennas course at the School of Engineering of University of Siena <br><br />
* 2002/2003, course of Design of Microwave Circuits at the School of Engineering of University of Siena <br><br />
* 2003, course of Numerical Methods for Electromagnetics at the Master on Microwave Systems on Technologies for Telecommunications, Messina (Italy) <br><br />
* 2003/2004 and 2004/2005, course of Electromagnetic Modelling at the School of Engineering of University of Siena <br><br />
* 2005, seminars into the school “High Frequency Methods and Travelling Wave Antennas”, European School of Antennas (ACE – Antenna Centre of Excellence), at University of Siena, about:<br><br />
** Green’s function of the dielectric slab<br> <br />
** Scattering from a perfectly conducting half-plane<br><br><br />
* Since 2005: <br><br />
** course of Radio Propagation class at the School of Engineering of University of Modena and Reggio Emilia<br><br />
** assisting in the Electromagnetic Field class at the School of Engineering of University of Modena and Reggio Emilia<br><br />
** Microwave Lab class at the School of Engineering of University of Modena and Reggio Emilia<br><br><br />
<br />
Visit the page [[Teaching Activity]] for Teaching Statement . <br><br><br />
<br />
===STUDENT SUPERVISED===<br />
* 2001 M.S. "Giacomo Donzelli", GENERALIZED PENCIL OF FUNCTION TECHNIQUE FOR MULTILAYERED PRINTED STRUCTURES<br><br />
* 2002 M.S. "Alberto Nencini", ASYMPTOTIC GREEN'S FUNCTION FOR A SECTORAL ARRAY OF ELEMENTARY SOURCES ON A DIELECTRIC SLAB<br> <br />
* 2005 M.S. "Giorgio Carluccio", EXTENSION OF THE INCREMENTAL THEORY OF DIFFRACTION TO COMPLEX SOURCES <br><br />
* 2006 M.S. "Michele Gravina", ANTENNA FOR BIOMEDICAL RFID APPLICATION<br><br />
* 2006 M.S. "Daniele Ciccarese", WIMAX: MAN WIRELESS TECHNOLOGY <br><br />
* 2007 M.S. "Guido Santamaria", ELECTROMAGNETIC CHARACTERIZATION OF TRANSITIONS BETWEEN COAXIAL CABLE AND MICROSTRIP<br><br />
* 2007 M.S. "Lorenzo Santunione", DESIGN AND CHARACTERIZATION OF A PRINTED DIPOLE ANTENNA WITH UNBALNCED FEEDING<br><br />
* 2007 Laurea Degree. "Enrico Busi", ANALYSIS AND DESIGN OF A PLANAR ANTENNA FOR UWB APPLICATIONS<br><br />
* 2008 M.S. "Marcello di Clemente", SAW SENSORS<br><br />
* 2008 Laurea Degree. "Gagliardi Giuseppina", WIDE BAND PATCH ANTENNAS DESIGN<br><br />
* 2008 M.S. "Javier Molejón Asenjo", DESIGN OF A DUAL BAND ANTENNA FOR RFID APPLICATIONS IN THE UHF BAND <br><br />
* 2009 M.S. "Luca Morandini", DEVICES FOR THE MONITORING OF ELECTROMAGNETIC INTERFERENCES DURING TIMING IN SPORT RACES, THROUGHOUT RFID SYSTEMS<br><br />
* 2009 M.S. "Erio Gandini", ANALYSIS OF BACKSCATTERING FROM PLANAR FRESNEL LENSES<br><br><br />
<br />
===ATTENDED SPECIALIZED PHD COURSES===<br />
* 2000, at University of Siena <br><br />
** Functional analysis elements <br><br />
** Interpolation and approximation of curves and surfaces <br> <br />
** Optimization Methods <br><br />
** Wavelets <br><br />
** Object Oriented Programming <br><br />
* 2002, at Chalmers University, Gotheborg, Sweden <br><br />
** Artificial Magnetic Conductors and Soft and Hard surfaces and their Use in Antenna Analysis and Design <br><br />
* 2002, at University of Ancona, PhD School <br><br />
** Ground Penetrating Radar <br><br />
*2005, at Denmark Technical University - Ticra, European School of Antennas (ACE - Antenna Center of Excellence) <br><br />
** Reflector antennas: analysis and design <br><br />
* 2005, at Politecnico of Turin, European School of Antennas (ACE - Antenna Center of Excellence) <br><br />
** Computational EM for antenna analysis <br><br />
* 2005, at University of Siena, European School of Antennas (ACE - Antenna Center of Excellence) <br><br />
** High Frequency Methods and Travelling Wave Antennas <br><br />
* 2006, at University of Dubrovnik, European School of Antennas (ACE - Antenna Center of Excellence) <br><br />
** Advanced Mathematics for Antenna Analysis <br><br><br />
<br />
===NATIONAL RESEARCH PROGRAMS===<br />
* 2000-2002. PAR (Piano d’Ateneo per la Ricerca) “Antenna installation for wireless communication systems”<br><br />
* 2000-2002. ASI (Italian Space Agency): “Reflectarrays for satellite applications” <br><br />
* 2003-2005. PRIN (Progetto di ricerca di interesse nazionale) “Electromagnetic models for analysis of passive reflectarrays”<br><br />
* 2005-2007. PRIN (Progetto di ricerca di interesse nazionale) “Microwave Radiometer for fire monitoring” <br><br><br />
<br />
===INTERNATIONAL RESEARCH PROGRAMS===<br />
Alessia Polemi has been part of the following international research programs:<br><br />
<br />
Years 2004-2005. ACE Antenna Centre of Excellence, V Framework Program, WP. 1.1.1 Integration, WP. 3.1.1 European School of Antennas<br><br />
<br />
Years 2005-2006. ACE Antennas Centre of Excellence, VI Framework Program, WP. 3.1.1 European School of Antennas<br><br />
<br />
Years 2005-2007. EAML European Antenna Modeling Library, contract with ESA-ESTEC n.18802/04/NL/JD, WP. 1.6.1.0 5S Green’s Function for stratified environment<br><br />
<br />
Years 2009-ongoing. EAML European Antenna Modeling Library, TT&C Coverage in Complex Environments <br><br />
<br />
Years 2009-ongoing. EuroStar Project, New production process for medical bags based on RadioFrequency sterilization and ICT<br><br><br />
<br />
===RESEARCH CONTRACTS===<br />
Years 2000-2001. Research contract between Department of Information Engineering (University of Siena) - IDS spa, in the framework of the agreement with Italian Navy for "Electromagnetic models for prediction of scattering objects" <br><br />
<br />
Years 2000-2002. Research contract Department of Information Engineering (University of Siena) - IDS spa, in the framework of the agreement with IDS spa for "Green’s function for multilayered materials"<br><br />
<br />
Years 2002-2003. Research contract Department of Information Engineering (University of Siena) - IDS spa, in the framework of the agreement with IDS spa for "Incremental Theory of Diffraction for dielectric screens" <br><br />
<br />
Years 2003-2004. Research contract with Consorzio Etruria ed Innovazione scpa, entitled "Feasibility and design of an automatic identification system on controlled areas based on the standard ISO/IEC 15693" <br><br />
<br />
Years 2004-2005. Research contract with Consorzio Etruria ed Innovazione scpa, entitled "Electromagnetic scattering from non perfectly conducting half-planes and junctions between planes: UTD and ITD formulation" <br><br />
<br />
Years 2005-2006. Research contract Department of Information Engineering (University of Siena) - IDS spa, in the framework of the agreement with IDS spa for "Green’s functions for dielectric multilayers; extension to magnetic sources" <br><br />
<br />
Years 2007-2008. Research contract Department of Information Engineering (University of Modena and Reggio Emilia) -Politecnico di Torino, entitled "Evolution and evolutionary maintenance of European Antenna Modelling Library Components" <br><br />
<br />
Year 2008. Research contract Department of Information Engineering (University of Modena and Reggio Emilia) –MD-Microdetectors (protected by NDA)<br><br><br />
<br />
===PUBLICATIONS===<br />
[http://www.dii.unimo.it/wiki/index.php/My_publications Publications]<br />
<br />
<br />
<br><br><br><br />
[[Image:home.gif|30px|left]] <br><br />
[[User:Apolemi | Home]]</div>Apolemihttps://web.ing.unimo.it/wiki/index.php?title=My_Curriculum_Vitae&diff=7018My Curriculum Vitae2009-11-21T11:14:10Z<p>Apolemi: /* ATTENDED PHD COURSES */</p>
<hr />
<div>'''(LAST UPDATE: 07/12/2009)'''<br><br />
<br />
===PERSONAL INFORMATION===<br />
[[Office address:]] <br><br />
Department of Information Engineering <br><br />
University of Modena and Reggio Emilia <br><br />
Via Vignolese 905<br><br />
41100 Modena, ITALY<br><br />
Tel. +39 059 2056326<br><br />
Fax. +39 059 2056129<br><br />
Mobile: +39 335 7181823<br><br />
E-mail: [mailto:alessia.polemi@unimore.it alessia.polemi@unimore.it]<br><br />
E-mail: [mailto:apolemi@seas.upenn.edu apolemi@seas.upenn.edu]<br><br />
web-site: http://www.dii.unimore.it/polemi<br><br />
[[Home address:]] <br><br />
Via San Faustino 123/10<br><br />
41100 Modena,ITALY<br><br><br />
<br />
===EDUCATION===<br />
* July 1999: M.S. (cum laude) in Telecommunication Engineering at University of Siena. Thesis dissertation: "Green’s Functions for phased arrays of dipoles on dielectric slab" (supervisors: Prof. S. Maci, Prof. R. Tiberio, Prof. A. Toccafondi). <br><br><br />
* January 2000: national qualification for engineers at the University of Florence. <br><br><br />
* March 2003: PhD in Information Engineering (curriculum: electromagnetic waves) at the University of Siena. Thesis dissertation: "Frequency Domain Green's Function for Periodic Large Phased Arrays in Multilayered Dielectric Regions " (tutor: Prof. R. Tiberio). <br><br><br />
* January 2003-October 2006: post-doc researcher at the Department of Information Engineering, University of Siena<br><br><br />
<br />
===PRESENT EMPLOYMENT===<br />
* November 2006: Assistant Professor at the School of Engineering of University of Modena and Reggio Emilia (scientific area: ELECTROMAGNETIC FIELDS)<br />
<br />
===RESEARCH INTERESTS===<br />
* High frequency scattering theories<br><br />
* Asymptotics electromagnetic methods<br><br />
* Numerical electromagnetic methods<br><br />
* Periodic structures<br><br />
* Bandgap structures<br><br />
* Antenna design<br><br />
* Antenna miniaturization<br><br />
* Wideband and ultrawideband antennas<br><br />
* RFID systems<br><br />
* Printed devices at microwave frequencies<br><br />
* New emerging waveguides<br><br />
* Metamaterials <br><br />
* Polaritons at optical frequency<br><br />
Further details in [[Research Activity]] section. <br><br><br />
<br />
===PROFESSIONAL SOCIETIES===<br />
* 1999, appointed to the profession of Engineer <br><br><br />
* 2000, Member of the Institute of Electrical and Electronic Engineers (IEEE) <br><br><br />
* September 2003-December 2005, president of the academic spin-off company WaveComm srl.<br><br><br />
* 2006, Italian Student Adviser for the Institution of Engineering and Technology (IET) <br><br><br />
<br><br><br />
<br />
===SOFTWARE SKILLS AND COMPETENCE===<br />
* Operating systems MS Windows 98/NT/2k/XP/Vista <br><br />
* MS Office<br><br />
* Maltlab<br><br />
* CorelDraw<br><br />
* Latex<br><br />
* Fortran<br><br />
* C<br><br />
* Mathematica<br><br />
* Electromagnetic simulation software<br><br />
** Ansoft Designer<br><br />
** HFSS<br><br />
** CST Microwave Studio<br><br />
** Grasp<br><br />
** FEKO<br><br />
** MicroWave Office<br><br />
** Wipl-d<br><br><br />
<br />
===TEACHING ACTIVITY===<br />
* 1999/2000, seminars in the Electromagnetic Field course at the School of Engineering of University of Siena <br><br />
* 2000/2001, seminars in the Microwave course at the School of Engineering of University of Siena <br><br />
* 2001/2002, seminars in the Antennas course at the School of Engineering of University of Siena <br><br />
* 2002/2003, course of Design of Microwave Circuits at the School of Engineering of University of Siena <br><br />
* 2003, course of Numerical Methods for Electromagnetics at the Master on Microwave Systems on Technologies for Telecommunications, Messina (Italy) <br><br />
* 2003/2004 and 2004/2005, course of Electromagnetic Modelling at the School of Engineering of University of Siena <br><br />
* 2005, seminars into the school “High Frequency Methods and Travelling Wave Antennas”, European School of Antennas (ACE – Antenna Centre of Excellence), at University of Siena, about:<br><br />
** Green’s function of the dielectric slab<br> <br />
** Scattering from a perfectly conducting half-plane<br><br><br />
* Since 2005: <br><br />
** course of Radio Propagation class at the School of Engineering of University of Modena and Reggio Emilia<br><br />
** assisting in the Electromagnetic Field class at the School of Engineering of University of Modena and Reggio Emilia<br><br />
** Microwave Lab class at the School of Engineering of University of Modena and Reggio Emilia<br><br><br />
<br />
Visit the page [[Teaching Activity]] for Teaching Statement . <br><br><br />
<br />
===STUDENT SUPERVISED===<br />
* 2001 M.S. "Giacomo Donzelli", GENERALIZED PENCIL OF FUNCTION TECHNIQUE FOR MULTILAYERED PRINTED STRUCTURES<br><br />
* 2002 M.S. "Alberto Nencini", ASYMPTOTIC GREEN'S FUNCTION FOR A SECTORAL ARRAY OF ELEMENTARY SOURCES ON A DIELECTRIC SLAB<br> <br />
* 2005 M.S. "Giorgio Carluccio", EXTENSION OF THE INCREMENTAL THEORY OF DIFFRACTION TO COMPLEX SOURCES <br><br />
* 2006 M.S. "Michele Gravina", ANTENNA FOR BIOMEDICAL RFID APPLICATION<br><br />
* 2006 M.S. "Daniele Ciccarese", WIMAX: MAN WIRELESS TECHNOLOGY <br><br />
* 2007 M.S. "Guido Santamaria", ELECTROMAGNETIC CHARACTERIZATION OF TRANSITIONS BETWEEN COAXIAL CABLE AND MICROSTRIP<br><br />
* 2007 M.S. "Lorenzo Santunione", DESIGN AND CHARACTERIZATION OF A PRINTED DIPOLE ANTENNA WITH UNBALNCED FEEDING<br><br />
* 2007 Laurea Degree. "Enrico Busi", ANALYSIS AND DESIGN OF A PLANAR ANTENNA FOR UWB APPLICATIONS<br><br />
* 2008 M.S. "Marcello di Clemente", SAW SENSORS<br><br />
* 2008 Laurea Degree. "Gagliardi Giuseppina", WIDE BAND PATCH ANTENNAS DESIGN<br><br />
* 2008 M.S. "Javier Molejón Asenjo", DESIGN OF A DUAL BAND ANTENNA FOR RFID APPLICATIONS IN THE UHF BAND <br><br />
* 2009 M.S. "Luca Morandini", DEVICES FOR THE MONITORING OF ELECTROMAGNETIC INTERFERENCES DURING TIMING IN SPORT RACES, THROUGHOUT RFID SYSTEMS<br><br />
* 2009 M.S. "Erio Gandini", ANALYSIS OF BACKSCATTERING FROM PLANAR FRESNEL LENSES<br><br><br />
<br />
===ATTENDED SPECIALIZED PHD COURSES===<br />
* 2000, at University of Siena <br><br />
** Functional analysis elements <br><br />
** Interpolation and approximation of curves and surfaces <br> <br />
** Optimization Methods <br><br />
** Wavelets <br><br />
** Object Oriented Programming <br><br />
* 2002, at Chalmers University, Gotheborg, Sweden <br><br />
** Artificial Magnetic Conductors and Soft and Hard surfaces and their Use in Antenna Analysis and Design <br><br />
* 2002, at University of Ancona, PhD School <br><br />
** Ground Penetrating Radar <br><br />
*2005, at Denmark Technical University - Ticra, European School of Antennas (ACE - Antenna Center of Excellence) <br><br />
** Reflector antennas: analysis and design <br><br />
* 2005, at Politecnico of Turin, European School of Antennas (ACE - Antenna Center of Excellence) <br><br />
** Computational EM for antenna analysis <br><br />
* 2005, at University of Siena, European School of Antennas (ACE - Antenna Center of Excellence) <br><br />
** High Frequency Methods and Travelling Wave Antennas <br><br />
* 2006, at University of Dubrovnik, European School of Antennas (ACE - Antenna Center of Excellence) <br><br />
** Advanced Mathematics for Antenna Analysis <br><br><br />
<br />
===NATIONAL RESEARCH PROGRAMS===<br />
Alessia Polemi has been part of the following national research programs:<br><br />
<br />
Years 2000-2002. PAR (Piano d’Ateneo per la Ricerca) entitled “Antenna installation for wireless communication systems”<br><br />
<br />
Years 2000-2002. ASI (Italian Space Agency): “Reflectarrays for satellite applications”<br />
<br><br />
<br />
Years 2003-2005. PRIN (Progetto di ricerca di interesse nazionale) entitled “Electromagnetic models for analysis of passive reflectarrays”<br><br />
<br />
Years 2005-2007. PRIN (Progetto di ricerca di interesse nazionale) entitled “Microwave Radiometer for fire monitoring”<br><br><br />
<br />
===INTERNATIONAL RESEARCH PROGRAMS===<br />
Alessia Polemi has been part of the following international research programs:<br><br />
<br />
Years 2004-2005. ACE Antenna Centre of Excellence, V Framework Program, WP. 1.1.1 Integration, WP. 3.1.1 European School of Antennas<br><br />
<br />
Years 2005-2006. ACE Antennas Centre of Excellence, VI Framework Program, WP. 3.1.1 European School of Antennas<br><br />
<br />
Years 2005-2007. EAML European Antenna Modeling Library, contract with ESA-ESTEC n.18802/04/NL/JD, WP. 1.6.1.0 5S Green’s Function for stratified environment<br><br />
<br />
Years 2009-ongoing. EAML European Antenna Modeling Library, TT&C Coverage in Complex Environments <br><br />
<br />
Years 2009-ongoing. EuroStar Project, New production process for medical bags based on RadioFrequency sterilization and ICT<br><br><br />
<br />
===RESEARCH CONTRACTS===<br />
Years 2000-2001. Research contract between Department of Information Engineering (University of Siena) - IDS spa, in the framework of the agreement with Italian Navy for "Electromagnetic models for prediction of scattering objects" <br><br />
<br />
Years 2000-2002. Research contract Department of Information Engineering (University of Siena) - IDS spa, in the framework of the agreement with IDS spa for "Green’s function for multilayered materials"<br><br />
<br />
Years 2002-2003. Research contract Department of Information Engineering (University of Siena) - IDS spa, in the framework of the agreement with IDS spa for "Incremental Theory of Diffraction for dielectric screens" <br><br />
<br />
Years 2003-2004. Research contract with Consorzio Etruria ed Innovazione scpa, entitled "Feasibility and design of an automatic identification system on controlled areas based on the standard ISO/IEC 15693" <br><br />
<br />
Years 2004-2005. Research contract with Consorzio Etruria ed Innovazione scpa, entitled "Electromagnetic scattering from non perfectly conducting half-planes and junctions between planes: UTD and ITD formulation" <br><br />
<br />
Years 2005-2006. Research contract Department of Information Engineering (University of Siena) - IDS spa, in the framework of the agreement with IDS spa for "Green’s functions for dielectric multilayers; extension to magnetic sources" <br><br />
<br />
Years 2007-2008. Research contract Department of Information Engineering (University of Modena and Reggio Emilia) -Politecnico di Torino, entitled "Evolution and evolutionary maintenance of European Antenna Modelling Library Components" <br><br />
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Year 2008. Research contract Department of Information Engineering (University of Modena and Reggio Emilia) –MD-Microdetectors (protected by NDA)<br><br><br />
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===PUBLICATIONS===<br />
[http://www.dii.unimo.it/wiki/index.php/My_publications Publications]<br />
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[[User:Apolemi | Home]]</div>Apolemi