Field discrete Monte Carlo simulation of electromagnetic scattering characteristics of plasma sheath

The electromagnetic scattering of an ultra-high-speed plasma covered target is simulated by the field discrete Monte Carlo method. The flow field network is used to simulate the trajectory of electromagnetic wave particles according to the electromagnetic distribution parameters, and the electromagn...

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Veröffentlicht in:	AIP advances 2020-10, Vol.10 (10), p.105019-105019-6
Hauptverfasser:	Jia, Jieshu, Gao, Ruilin, Xie, Baozhuo, Liang, Zichang, Wei, Feiming, Zhang, Yuan
Format:	Artikel
Sprache:	eng
Schlagworte:	Computing time Electromagnetic properties Electromagnetic radiation Electromagnetic scattering Hypervelocity Mathematical analysis Monte Carlo simulation Parameters Plasma sheaths Radar cross sections
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container_end_page	105019-6
container_issue	10
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container_title	AIP advances
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creator	Jia, Jieshu Gao, Ruilin Xie, Baozhuo Liang, Zichang Wei, Feiming Zhang, Yuan
description	The electromagnetic scattering of an ultra-high-speed plasma covered target is simulated by the field discrete Monte Carlo method. The flow field network is used to simulate the trajectory of electromagnetic wave particles according to the electromagnetic distribution parameters, and the electromagnetic characteristics are calculated according to the statistical parameters of the reflected particles. The computational time-consumption is less correlated with the incident electromagnetic wave frequency [except for the Radar Cross Section (RCS) valley characteristics], and it is convenient for parallel calculation, which realizes the fast calculation of the electromagnetic scattering of the electrically large plasma-covered target. On this basis, the electromagnetic scattering characteristics of the blunt cone hypervelocity target are calculated, and the main RCS reduction and enhancement mechanisms are given.
doi_str_mv	10.1063/1.5144831
format	Article
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The flow field network is used to simulate the trajectory of electromagnetic wave particles according to the electromagnetic distribution parameters, and the electromagnetic characteristics are calculated according to the statistical parameters of the reflected particles. The computational time-consumption is less correlated with the incident electromagnetic wave frequency [except for the Radar Cross Section (RCS) valley characteristics], and it is convenient for parallel calculation, which realizes the fast calculation of the electromagnetic scattering of the electrically large plasma-covered target. 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subjects	Computing time Electromagnetic properties Electromagnetic radiation Electromagnetic scattering Hypervelocity Mathematical analysis Monte Carlo simulation Parameters Plasma sheaths Radar cross sections
title	Field discrete Monte Carlo simulation of electromagnetic scattering characteristics of plasma sheath
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