Research on the SDIF Failure Principle for RF Stealth Radar Signal Design

Radio frequency (RF) stealth is one of the essential research hotspots in the radar field. The anti-sorting signal is an important direction of the RF stealth signal. Theoretically speaking, the anti-sorting signal design is based on the failure principle of the radar signal sorting algorithm, and t...

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Veröffentlicht in:	Electronics (Basel) 2022-06, Vol.11 (11), p.1777
Hauptverfasser:	Jia, Jinwei, Han, Zhuangzhi, Liu, Limin, Xie, Hui, Lv, Meng
Format:	Artikel
Sprache:	eng
Schlagworte:	Algorithms Design Experimentation Failure Methods Principles Pulse repetition interval Radar Radiation Radio equipment Radio frequency Radio signals Receivers & amplifiers Signal processing Sorting algorithms Vibration
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container_title	Electronics (Basel)
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creator	Jia, Jinwei Han, Zhuangzhi Liu, Limin Xie, Hui Lv, Meng
description	Radio frequency (RF) stealth is one of the essential research hotspots in the radar field. The anti-sorting signal is an important direction of the RF stealth signal. Theoretically speaking, the anti-sorting signal design is based on the failure principle of the radar signal sorting algorithm, and the SDIF algorithm is a core sorting algorithm widely used in engineering. Thus, in this paper, the SDIF algorithm is first analyzed in detail. It is pointed out that the threshold function of the SDIF algorithm will fail when the signal pulse repetition interval (PRI) value obeys the interval distribution whose length is 20 times larger than the minimum interval of PRI. Secondly, the correctness of the failure principle of SDIF threshold separation is proved by the formula. Finally, the correctness is further verified by the signal design case. The principle of SDIF sorting threshold failure provides theoretical support for anti-sorting RF stealth signal design. It also complements the shortcoming of the casual design for the anti-sorting signal. Furthermore, the principle of SDIF sorting threshold failure helps improve anti-sorting signal design efficiency. Compared with the Dwell & Switch (D&S) signal and jitter signal, the anti-sorting ability of the signal designed by using the sorting failure principle is notably enhanced through simulation and experimentation.
doi_str_mv	10.3390/electronics11111777
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The anti-sorting signal is an important direction of the RF stealth signal. Theoretically speaking, the anti-sorting signal design is based on the failure principle of the radar signal sorting algorithm, and the SDIF algorithm is a core sorting algorithm widely used in engineering. Thus, in this paper, the SDIF algorithm is first analyzed in detail. It is pointed out that the threshold function of the SDIF algorithm will fail when the signal pulse repetition interval (PRI) value obeys the interval distribution whose length is 20 times larger than the minimum interval of PRI. Secondly, the correctness of the failure principle of SDIF threshold separation is proved by the formula. Finally, the correctness is further verified by the signal design case. The principle of SDIF sorting threshold failure provides theoretical support for anti-sorting RF stealth signal design. It also complements the shortcoming of the casual design for the anti-sorting signal. 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subjects	Algorithms Design Experimentation Failure Methods Principles Pulse repetition interval Radar Radiation Radio equipment Radio frequency Radio signals Receivers & amplifiers Signal processing Sorting algorithms Vibration
title	Research on the SDIF Failure Principle for RF Stealth Radar Signal Design
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