Systems Engineering and Electronics ›› 2025, Vol. 47 ›› Issue (11): 3598-3611.doi: 10.12305/j.issn.1001-506X.2025.11.09
• Sensors and Signal Processing • Previous Articles
Joint suppression method of ambiguity function sidelobe in 5G signals via blockwise reconstruction and decorrelation
Shuai MA1,2(
), Zeqi YANG1,2(), Kai CHANG3(), Ning LIU3(), Xiaode LYU1,*()
- 1. National Key Laboratory of Microwave Imaging,Aerospace Information Research Institute,Chinese Academy of Sciences,Beijing 100190,China
2. School of Electronic,Electrical and Communication Engineering,University of Chinese Academy of Sciences,Beijing 100049,China
3. Unit 32802 of the PLA,Beijing 100083,China
-
Received:2025-03-18Accepted:2025-07-01Online:2025-11-25Published:2025-12-08 -
Contact:Xiaode LYU E-mail:mashuai22@mails.ucas.ac.cn;yangzeqi22@mails.ucas.ac.cn;kerkaichance@gmail.com;978599056@qq.com;lvxd@aircas.ac.cn
CLC Number:
Cite this article
Shuai MA, Zeqi YANG, Kai CHANG, Ning LIU, Xiaode LYU. Joint suppression method of ambiguity function sidelobe in 5G signals via blockwise reconstruction and decorrelation[J]. Systems Engineering and Electronics, 2025, 47(11): 3598-3611.
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Table 1
Frequency bands and bandwidth selection range for 5G signal defined by standards"
| FR频段 | 对应的频率范围/GHz | 定义的最大信道 带宽/MHz |
| FR1 | 0.41~7.125 | 100 |
| FR2 | 24.25~52.6 | 400 |
Table 1
Fig.1
5G signal wireless frame structure in FR1 band"
Fig.1
Table 2
5G NR supported SCS and symbol length in FR1 band"
| 子载波间隔/kHz | OFDM符号长度/μs | NCP长度/μs |
| 15 | 66.67 | 4.69 |
| 30 | 33.33 | 2.34 |
| 60 | 16.67 | 1.17 |
Table 2
Fig.2
SSB structure in 5G synchronization signal"
Fig.2
Table 3
5G downlink signal parameter configuration"
| 参数名 | 参数设置 |
| 信号链路 | 下行链路 |
| 频谱范围 | FR1 |
| 调制方式 | 16QAM |
| 信道带宽/MHz | 20 |
| 信号SCS/kHz | 15 |
| SSB/PBCH周期/ms | 5 |
| 信号帧长度/ms | 30 |
Table 3
Fig.3
Simulated 5G signal ambiguity function"
Fig.3
Fig.4
5G signal ambiguity function range dimension plots in different SCSs"
Fig.4
Table 4
5G signal time-delay dimension sidelobe positions for different SCSs"
| SCS/kHz | OFDM符号长度/μs | 距离维副峰位置/μs |
| 15 | ||
| 30 | ||
| 60 |
Table 4
Fig.5
5G signal ambiguity function Doppler dimension plot"
Fig.5
Table 5
Time domain position of SSB in different Cases"
| 模式 | n的取值 | 位置索引 | |
| Fc | 3 GHz | ||
| 模式A(15 kHz) | n=0,1 | n=0,1,2,3 | {2,8}+14n |
| 模式B(30 kHz) | n=0,1 | n=0,1 | {4,8,6,20}+28n |
| 模式C(60 kHz) | n=0,1 | n=0,1,2,3 | {2,8}+14n |
Table 5
Fig.6
SSB time-domain position in one period"
Fig.6
Fig.7
Schematic diagram of blockwise reconstruction fast ambiguity function computation method"
Fig.7
Fig.8
Integrated processing flow of sidelobe peak interference suppression"
Fig.8
Table 6
Simulation parameter configuration for 5G signal sidelobe suppression"
| 参数名 | 参数设置 |
| 信号链路 | 下行链路 |
| 频谱范围 | FR1 |
| 调制方式 | 16QAM |
| 信道带宽/MHz | 20 |
| 信号SCS/kHz | 15 /30 /60 |
| SSB/PBCH周期/ms | 5 |
| 信号帧长度/ms | 30 |
| SSB/PBCH映射类型/kHz | 模式A:15 |
| 模式B:30 | |
| 模式C:60 | |
| OFDM符号长度/μs | 模式A:16.67 |
| 模式B:33.33 | |
| 模式C:66.67 |
Table 6
Fig.9
Comparison of 5G signal ambiguity function plots before and after sidelobe suppression (Case A)"
Fig.9
Fig.10
Comparison of 5G signal ambiguity function plots before and after sidelobe suppression (Case B)"
Fig.10
Fig.11
Comparison of 5G signal ambiguity function plots before and after sidelobe suppression (Case C)"
Fig.11
Table 7
Changes in amplitude of sidelobe in range-dimensional before and after sidelobe suppression of 5G signal"
| 模式 | SCS/kHz | 距离维副峰 | |||
| 副峰 位置/μs | 抑制前 幅度/dB | 抑制后 幅度/dB | 副峰 抑制比/dB | ||
| 模式A | 15 | 66.67 | 18.05 | 3.61 | 14.44 |
| 模式B | 30 | 33.33 | 23.76 | 18.91 | 4.85 |
| 模式C | 60 | 16.67 | 29.06 | 22.64 | 6.42 |
Table 7
Table 8
Changes in amplitude of sidelobe in Doppler-dimensional before and after sidelobe suppression of 5G signal"
| 模式 | 副峰 周期/Hz | 副峰抑制 | 主峰 幅度/dB | 副峰 幅度/dB | 峰值 旁瓣比/dB |
| 模式A | 200 | 处理前 | 41.11 | 17.47 | −23.64 |
| 处理后 | 40.46 | 6.10 | −34.36 | ||
| 模式B | 200 | 处理前 | 47.02 | 23.76 | −23.26 |
| 处理后 | 46.26 | 14.93 | −31.33 | ||
| 模式C | 200 | 处理前 | 52.51 | 29.06 | −23.45 |
| 处理后 | 52.11 | 23.66 | −28.45 |
Table 8
Fig.12
Doppler ambiguity function of 5G signal before and after processing with the proposed method"
Fig.12
Table 9
Changes in Doppler-dimensional sidelobe amplitude of 5G signal before and after processing in different SSB cycles with the proposed method"
| SSB周期/ms | 多普勒副峰 周期/Hz | 抑制前 幅值/dB | 抑制后 幅值/dB | 副峰 抑制比/dB |
| 5 | 200 | 17.473 | 6.095 | 11.378 |
| 10 | 100 | 17.527 | 6.526 | 11.001 |
| 20 | 50 | 14.617 | 6.586 | 8.031 |
| 40 | 25 | 14.688 | 6.733 | 7.955 |
| 80 | 12.5 | 17.527 | 6.657 | 10.87 |
| 160 | 6.25 | 16.768 | 6.852 | 9.916 |
Table 9
Fig.13
Range-Doppler ambiguity function results of 5G signals processed with the proposed method in Case A"
Fig.13
Fig.14
Target detection results of 5G signals before sidelobe suppression"
Fig.14
Fig.15
Target detection results of 5G signals after sidelobe suppression"
Fig.15
| 1 | HE Z Y, CHEN W, YANG Y, et al. Maritime ship target imaging with GNSS-based passive multistatic radar[J]. IEEE Trans. on Geoscience and Remote Sensing, 2023, 61, 5800918. |
| 2 |
ZUO L, WANG J, SUI J X, et al. An inter subband processing algorithm for complex clutter suppression in passive bistatic radar[J]. Remote Sensing, 2021, 13 (23): 4954.
doi: 10.3390/rs13234954 |
| 3 | HU S B, YI J X, WAN X R, et al. Doppler separation-based clutter suppression method for passive radar on moving platforms[J]. IEEE Trans. on Geoscience and Remote Sensing, 2024, 62, 4701714. |
| 4 | ZIKIDIS K, SKONDRAS A, TOKAS C. Low observable principles, stealth aircraft and anti-stealth technologies[J]. Journal of Computations & Modelling, 2014, 4 (1): 129- 165. |
| 5 | HE P C, DAI S L. Real-time stealth corridor path planning for fleets of unmanned aerial vehicles in low-altitude penetration[J]. International Journal of Robotics and Automation, 2015. |
| 6 | DIEGO C, RODRIGO B G, DANIEL O. K-space signal occupancy of Starlink signals and their applications in passive radar imaging[C]// Proc. of the IEEE Radar Conference, 2023. |
| 7 | 任汉. 复杂环境下新体制雷达信号的无源定位技术研究[D]. 北京: 中国科学院大学, 2023. |
| REN H. Research on passive location technology of new radar signal in complex environment[D]. Beijing: University of the Chinese Academy of Sciences, 2023. | |
| 8 |
OLSEN K E, ASEN W. Bridging the gap between civilian and military pacsive radar[J]. IEEE Aerospace and Electronic Systems Magazine, 2017, 32 (2): 4- 12.
doi: 10.1109/MAES.2017.160030 |
| 9 |
NOROOZI A, SEBT M A. Algebraic solution for three-dimensional TDOA/AOA localisation in mul-tiple-input-multiple-output passive radar[J]. IET Radar, Sonar and Navigation, 2018, 12 (1): 21- 29.
doi: 10.1049/iet-rsn.2017.0117 |
| 10 | YANG Z Q, MA S, LIU N, et al. A novel clutter suppression algorithm for low-slow-small targets detecting based on sparse adaptive filtering[J]. Journal of Beijing Institute of Technology, 2024, 33 (1): 54- 64. |
| 11 | SCHWARK C, CRISTALLINI D. Advanced multipath clutter cancellation in OFDM-based passive radar systems[C]// Proc. of the IEEE Radar Conference, 2016. |
| 12 | MAHFOUDIA O, HORLIN F, NEYT X. Pilot-based detection for DVB-T passive coherent location radars[J]. IET Radar, Sonar & Navigation, 2020, 14 (6): 845- 851. |
| 13 | ANSARI F, SAMADI S, MOHSENI R. Clean processing for direct signal cancellation using sparse representation in passive synthetic aperture Radar based on DVB-T signal[J]. Multimedia Tools and Applications, 2024, 83 (5): 13315. |
| 14 | MA S, YANG Z Q, ZHANG H, et al. Equalization reconstruction algorithm based on reference signal frequency domain block joint for DTMB-based passive radar[J]. Journal of Beijing Institute of Technology, 2024, 33 (1): 41- 53. |
| 15 |
ZHU H J, WANG L J, LIU M Q. Using DTMB-based passive radar for small unmanned aerial vehicle detection[J]. Wireless Communications and Mobile Computing, 2021, 2021, 9987992.
doi: 10.1155/2021/9987992 |
| 16 |
RAJA A R S A, ALHAJI M S, ABDUL R N E, et al. Passive forward-scattering radar using digital video broadcasting satellite signal for drone detection[J]. Remote Sensing, 2020, 12 (18): 3075.
doi: 10.3390/rs12183075 |
| 17 | HUANG C, LI Z Y, AN H Y, et al. Passive multistatic radar imaging of vessel target using GNSS satellites of opportunity[J]. IEEE Trans. on Geoscience and Remote Sensing, 2022, 60, 5116416. |
| 18 | BLÁZQUEZ-GARCÍA R, CRISTALLINI D, UMMENHOFER M, et al. Experimental comparison of Starlink and OneWeb signals for passive radar[C]//Proc. of the IEEE Radar Conference, 2023. |
| 19 | LYU X D, ZHANG H L, LIU Z S, et al. Research on co-channel base station interference suppression method of passive radar based on LTE signal[J]. Journal of Electronics & Information Technology, 2019, 41 (9): 2123- 2130. |
| 20 | TAYLOR F D, LIEVSAY J R. LTE bandwidth and modulation scheme effects on passive bistatic radar[C]//Proc. of the 52nd Asilomar Conference on Signals, Systems, and Computers, 2018. |
| 21 | TAYLOR A, POULLIN D. Experimental UAV detection using 4G-LTE-based passive Radar[C]//Proc. of the IEEE International Radar Conference, 2023. |
| 22 | SAMCZYŃSKI P, ABRATKIEWICZ K, PŁOTKA M, et al. 5G network-based passive radar[J]. IEEE Trans. on Geoscience and Remote Sensing, 2021, 60, 5108209. |
| 23 | KIVIRANTA M, MOILANEN I, ROIVAINEN J. 5G radar: scenarios, numerology and simulations[C]//Proc. of the International Conference on Military Communications and Information Systems, 2019. |
| 24 | COLONE F, FALCONE P, LOMBARDO P. Passive bistatic radar based on mixed DSSS and OFDM WiFi transmissions[C]//Proc. of the 8th European Radar Conference, 2011: 154−157. |
| 25 |
高志文, 陶然, 单涛. DVB-T辐射源雷达信号模糊函数的副峰分析与抑制[J]. 电子学报, 2008, 36 (3): 505- 509.
doi: 10.3321/j.issn:0372-2112.2008.03.018 |
|
GAO Z W, TAO R, SHAN T. Analysis and suppression of side peaks of ambiguity function of DVB-T radiator radar signal[J]. Journal of Electronics, 2008, 36 (3): 505- 509.
doi: 10.3321/j.issn:0372-2112.2008.03.018 |
|
| 26 | LI J C, LYU X D, ZHAO Y D. A novel algorithm for side peaks suppression of ambiguity function for passive radar based on chinese DTTB signal[J]. Journal of Electronics (China), 2012, 29 (6): 485- 492. |
| 27 | 万显荣, 岑博, 程丰, 等. 基于CMMB的外辐射源雷达信号模糊函数分析与处理[J]. 电子与信息学报, 2011, 33 (10): 2489- 2493. |
| WAN X R, CEN B, CHENG F, et al. Ambiguity function analysis and processing of external radiation source radar signal based on CMMB[J]. Journal of Electronics & Information Technology, 2011, 33 (10): 2489- 2493. | |
| 28 | 吕晓德, 张汉良, 杨璟茂, 等. 基于LTE 信号的外辐射源雷达副峰特性及抑制方法研究[J]. 电子与信息学报, 2018, 40 (10): 2498- 2505. |
| LYU X D, ZHANG H L, YANG J M, et al. Research on the characteristics and suppression methods of the side peak of external radiation source radar based on LTE signal[J]. Journal of Electronics & Information Technology, 2018, 40 (10): 2498- 2505. | |
| 29 | ZUO L, WANG J, CHEN G. Doppler ambiguity analysis and suppression for LTE-based passive bistatic radars[J]. Frontiers of Information Technology & Electronic Engineering, 2021, 22 (8): 1140- 1152. |
| 30 | 温博, 尹伟, 罗扬静, 等. 一种基于失配滤波的5G模糊函数副峰抑制技术[J]. 电讯技术, 2023, 63 (11): 1811- 1816. |
| WEN B, YIN W, LUO Y J, et al. A sub-peak suppression technique of 5G ambiguity function based on mismatch filtering[J]. Telecommunication Engineering, 2023, 63 (11): 1811- 1816. | |
| 31 | 王本静, 易建新, 万显荣, 等. LTE外辐射源雷达帧间模糊带分析与抑制[J]. 雷达学报, 2018, 7 (4): 514- 522. |
| WANG B J, YI J X, WAN X R, et al. Inter-frame ambiguity analysis and suppression of LTE signal for passive radar[J]. Journal of Radars, 2018, 7 (4): 514- 522. |
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