Fast Wideband Monostatic Scattering Analysis Method Combining Macro-Block Characteristic Basis Function Method With Improved FIR for Freestanding Large-Scale Finite Periodic Arrays

An efficient numerical method for the wideband scattering analysis of the freestanding large-scale finite periodic array is presented using the macro block-characteristic basis function method (MB-CBFM) and the improved frequency-independent reaction (FIR). In the MB-CBFM, the blocks (unit cells) ar...

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Main Authors: Ping Du, Anyong Qing, Gang Zheng, Peng-Hao Hu
Format: Article
Language:English
Published: IEEE 2021-01-01
Series:IEEE Access
Subjects:
Online Access:https://ieeexplore.ieee.org/document/9328285/
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spelling doaj-72876d78ee4f48ef8cdef4ddbeb15d4e2021-03-30T15:13:54ZengIEEEIEEE Access2169-35362021-01-019156031560810.1109/ACCESS.2021.30526129328285Fast Wideband Monostatic Scattering Analysis Method Combining Macro-Block Characteristic Basis Function Method With Improved FIR for Freestanding Large-Scale Finite Periodic ArraysPing Du0https://orcid.org/0000-0001-8404-0824Anyong Qing1Gang Zheng2https://orcid.org/0000-0001-8507-7880Peng-Hao Hu3https://orcid.org/0000-0001-6014-1567School of Electronic Science and Applied Physics, Hefei University of Technology, Hefei, ChinaSchool of Electrical Engineering, Southwest Jiaotong University, Chengdu, ChinaState Key Laboratory of Satellite Ocean Environment Dynamics, Second Institute of Oceanography, Ministry of Natural Resources, Hangzhou, ChinaSchool of Instrument Science and Opto-electronics Engineering, Hefei University of Technology, Hefei, ChinaAn efficient numerical method for the wideband scattering analysis of the freestanding large-scale finite periodic array is presented using the macro block-characteristic basis function method (MB-CBFM) and the improved frequency-independent reaction (FIR). In the MB-CBFM, the blocks (unit cells) are divided into some types of macro blocks. By analyzing the subarray with the macro blocks, the CBFs for the macro blocks will be obtained. The blocks in the same macro block share the same CBFs. Substituting the CBFs into the moment matrix equation, a reduced matrix equation whose size does not depend on the number of the blocks can be obtained and handled utilizing direct methods. When the MB-CBFM is applied for wideband analysis, the matrix needs to be recomputed. The reduced matrix can be efficiently generated by using the improved FIR, in which the matrix elements are expressed as the product of the geometrical elements and the phase factor. The geometrical elements are computed one time and reused. Only the phase factor needs to be recomputed. Several numerical examples are carried out. Simulation results show that the results of the proposed algorithm agree well with those of other numerical methods. The total CPU time is significantly reduced.https://ieeexplore.ieee.org/document/9328285/Finite periodic arraymacro block-characteristic basis functionimproved frequency-independent reactionscatteringwideband
collection DOAJ
language English
format Article
sources DOAJ
author Ping Du
Anyong Qing
Gang Zheng
Peng-Hao Hu
spellingShingle Ping Du
Anyong Qing
Gang Zheng
Peng-Hao Hu
Fast Wideband Monostatic Scattering Analysis Method Combining Macro-Block Characteristic Basis Function Method With Improved FIR for Freestanding Large-Scale Finite Periodic Arrays
IEEE Access
Finite periodic array
macro block-characteristic basis function
improved frequency-independent reaction
scattering
wideband
author_facet Ping Du
Anyong Qing
Gang Zheng
Peng-Hao Hu
author_sort Ping Du
title Fast Wideband Monostatic Scattering Analysis Method Combining Macro-Block Characteristic Basis Function Method With Improved FIR for Freestanding Large-Scale Finite Periodic Arrays
title_short Fast Wideband Monostatic Scattering Analysis Method Combining Macro-Block Characteristic Basis Function Method With Improved FIR for Freestanding Large-Scale Finite Periodic Arrays
title_full Fast Wideband Monostatic Scattering Analysis Method Combining Macro-Block Characteristic Basis Function Method With Improved FIR for Freestanding Large-Scale Finite Periodic Arrays
title_fullStr Fast Wideband Monostatic Scattering Analysis Method Combining Macro-Block Characteristic Basis Function Method With Improved FIR for Freestanding Large-Scale Finite Periodic Arrays
title_full_unstemmed Fast Wideband Monostatic Scattering Analysis Method Combining Macro-Block Characteristic Basis Function Method With Improved FIR for Freestanding Large-Scale Finite Periodic Arrays
title_sort fast wideband monostatic scattering analysis method combining macro-block characteristic basis function method with improved fir for freestanding large-scale finite periodic arrays
publisher IEEE
series IEEE Access
issn 2169-3536
publishDate 2021-01-01
description An efficient numerical method for the wideband scattering analysis of the freestanding large-scale finite periodic array is presented using the macro block-characteristic basis function method (MB-CBFM) and the improved frequency-independent reaction (FIR). In the MB-CBFM, the blocks (unit cells) are divided into some types of macro blocks. By analyzing the subarray with the macro blocks, the CBFs for the macro blocks will be obtained. The blocks in the same macro block share the same CBFs. Substituting the CBFs into the moment matrix equation, a reduced matrix equation whose size does not depend on the number of the blocks can be obtained and handled utilizing direct methods. When the MB-CBFM is applied for wideband analysis, the matrix needs to be recomputed. The reduced matrix can be efficiently generated by using the improved FIR, in which the matrix elements are expressed as the product of the geometrical elements and the phase factor. The geometrical elements are computed one time and reused. Only the phase factor needs to be recomputed. Several numerical examples are carried out. Simulation results show that the results of the proposed algorithm agree well with those of other numerical methods. The total CPU time is significantly reduced.
topic Finite periodic array
macro block-characteristic basis function
improved frequency-independent reaction
scattering
wideband
url https://ieeexplore.ieee.org/document/9328285/
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AT gangzheng fastwidebandmonostaticscatteringanalysismethodcombiningmacroblockcharacteristicbasisfunctionmethodwithimprovedfirforfreestandinglargescalefiniteperiodicarrays
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