Your search keyword '"Pelosi, Giuseppe"' showing total 7 results

1. Finite element design of CNT-based multilayer absorbers.

Author

d'Elia, Ugo, Pelosi, Giuseppe, Selleri, Stefano, and Taddei, Ruggero

Subjects

*CARBON nanotubes, *FINITE element method, *ARTIFICIAL neural networks, *GENETIC algorithms, *MATHEMATICAL optimization

Abstract

Purpose – A design procedure for multi-layer absorbers based on carbon nanotubes (CNT) frequency selective surfaces (FSS) sheets is here developed. The paper aims to discuss there issues. Design/methodology/approach – Single layer FSS are first analyzed via finite element (FE). Then equivalent sheets admittances are extracted in a transmission line model. Neural networks (NNs) interpolation over this data and subsequent multi-objective genetic algorithm (GA) based optimizations are then performed to design multiple layers absorbing structures. Designs are finally validated via full wave FEM simulations. Findings – In this paper, some absorbing structures made of three or four FSS sheets with total thicknesses around 6 mm are synthesized. Research limitations/implications – NNs' accuracy used in the equivalent model can be refined with further training. Practical implications – Low profile absorbing materials are of relevant industrial interest both for radar cloaking and anechoic chambers. Originality/value – The transmission line model combined with NNs and GA optimization is capable of speeding up the design procedure with respect to a conventional full-wave FEM approach. [ABSTRACT FROM AUTHOR]

Published

2013

2. A General Multisegment Artificial Neural Network Architecture for the Efficient Evaluation of Electromagnetic Plane-Wave Wedge Diffraction.

Author

Manara, Giuliano, Nepa, Paolo, Pelosi, Giuseppe, Pinto, Alessandro, and Selleri, Stefano

Subjects

*ELECTRIC impedance, *ARTIFICIAL neural networks, *ANTENNAS (Electronics), *ELECTROMAGNETIC fields, *ANTENNA radiation patterns, *ELECTRIC fields, *DATA transmission systems, *ANTENNA design, *TELECOMMUNICATION

Abstract

A multisegment artificial neural network (ANN) is proposed as an interpolation technique for the evaluation of the electromagnetic field diffracted at the edge of anisotropic impedance wedges under plane wave illumination at oblique incidence. Multisegmentation is needed as the high-frequency wedge diffracted field is characterized by a number of discontinuities at the shadow boundaries of the geometrical optics and surface wave fields. The proposed approach is applied, as a test case, to the problem of an anisotropic impedance right-angled wedge illuminated by a skewly incident plane wave. Some exact analytical solutions valid for specific surface impedance tensors are used to obtain numerical data for the ANN training phase as well as to show the interpolation capabilities of the implemented ANN. Nevertheless, the proposed ANN structure is general and can be trained with data obtained from other available solutions (analytical, perturbative, numerical) valid for more general wedge configurations, eventually leading to a single software tool encompassing all of them and providing accurate approximations of the wedge diffracted field in a relatively short time, comparable to that of a closed form analytical solution. [ABSTRACT FROM AUTHOR]

Published

2007

3. Neural network applications in microwave device design.

Author

Selleri, Stefano, Manetti, Stefano, and Pelosi, Giuseppe

Subjects

*ARTIFICIAL neural networks, *MICROWAVE circuits, *MICROWAVE antennas, *ANTENNAS (Electronics), *MICROWAVE devices

Abstract

This paper deals with many different neural network architectures that have been introduced to simulate the electromagnetic behavior of complex microwave devices and antennas. Many issues linked to the peculiarities of such devices are addressed. Furthermore, the inverse problem of designing a microwave device, once the required characteristics are given, is also developed by using a neural network approach. © 2002 John Wiley & Sons, Inc. Int J RF and Microwave CAE 12: 90–97, 2002. [ABSTRACT FROM AUTHOR]

Published

2002

4. Profiled Corrugated Circular Horns Analysis and Synthesis Via an Artificial Neural Network.

Author

Fedi, Giulio, Manetti, Stefano, Pelosi, Giuseppe, and Selleri, Stefano

Subjects

*ARTIFICIAL neural networks, *HORN (Musical instrument)

Abstract

Presents a study which examined the artificial neural network approach for the analysis and synthesis of profiled circular corrugated horn. Geometrical aspects of the profiled corrugated circular horns; Analysis and synthesis procedure; Conclusion.

Published

2001

5. Passive target detection and tracking from electromagnetic field measurements.

Author

Gao, Lin, Selleri, Stefano, Battistelli, Giorgio, Chisci, Luigi, and Pelosi, Giuseppe

Subjects

*ELECTROMAGNETIC measurements, *ARTIFICIAL neural networks, *ALGORITHMS, *TRACKING algorithms

Abstract

This paper presents a novel approach to the localization of moving targets in a complex environment based on the measurement of the perturbations induced by the target presence on an independently‐generated time‐varying electromagnetic field. Field perturbations are measured via a set of sensors deployed over the domain of interest and used to detect and track a possible target by resorting to a particle Bernoulli filter (PBF). To comply with real‐time operation, the PBF works along with an artificial neural network (ANN) model of the environment trained offline via finite elements (FEs). The performance of the proposed algorithm is assessed via simulation experiments. [ABSTRACT FROM AUTHOR]

Published

2020

6. Direct-coupled cavity filters design using a hybrid feedforward neural network–finite elements procedure.

Author

Fedi, Giulio, Gaggelli, Alessio, Manetti, Stefano, and Pelosi, Giuseppe

Subjects

*ARTIFICIAL neural networks, *MICROWAVE circuits, *FINITE element method, *COUPLED mode theory (Wave-motion), *HYBRID computer simulation

Abstract

In many filtering applications, direct-coupled cavity filters are often used for their symmetry and handling easiness. In this paper, a method is described for the design of these filtering devices by using an artificial neural network (ANN). Starting from design requirements, the procedure discussed herein directly determines the geometric dimensions of the filtering device with good accuracy and very short processing time. ©1999 John Wiley & Sons, Inc. Int J RF and Microwave CAE 9: 287–296, 1999. [ABSTRACT FROM AUTHOR]

Published

1999

7. A finite-element neural-network approach to microwave filter design.

Author

Fedi, Giulio, Gaggelli, Alessio, Manetti, Stefano, and Pelosi, Giuseppe

Subjects

*MICROWAVE filters, *MICROWAVE devices, *ARTIFICIAL neural networks, *FINITE element method, *NUMERICAL analysis

Abstract

A straightforward method for the design of microwave filtering devices by using neural networks is proposed. Starting from the filter requirements, this technique is able to perform the synthesis of microwave filters with good accuracy and high computational efficiency. The neural-network training set is generated by applying the finite-element (FE) approach. © 1998 John Wiley & Sons, Inc. Microwave Opt Technol Lett 19: 36–38, 1998. [ABSTRACT FROM AUTHOR]

Published

1998