感知辅助的星地融合鲁棒安全波束成形算法

doi:10.12305/j.issn.1001-506X.2026.05.33

摘要/Abstract

摘要：

针对星地融合网络中的物理层安全传输问题，提出一种感知辅助的鲁棒安全波束成形（beamforming，BF）算法。在该网络中，卫星采用多播技术服务多个地球站的同时，还存在空中窃听者（airborne eavesdropper，AE）试图获取卫星的隐私信号；而地面基站在利用通感一体化技术服务多个用户的同时，对AE进行感知并施加友好干扰，从而提升整个系统的安全性能。为了达到上述目的，在仅已知合法用户与AE非完美信道状态信息的条件下，首先建立一个以系统总发射功率最小化为目标函数，且通信信号和感知信号的质量以及最大窃听概率满足要求为约束条件的优化问题。为了求解该非凸问题，接下来利用最大瑞利商得到地面基站的接收BF权矢量，利用伯恩斯坦不等式与柯西施瓦兹不等式将复杂的非凸约束转化为可行的凸约束，并进一步基于秩极小化迭代法求得鲁棒发射BF权矢量。最后，仿真结果验证了所提方案能够在保证安全通信要求的同时，最小化系统的总发射功率。通过提高通信、感知和安全一体化设计的协同能力，最终确保了星地融合网络的安全通信，证实了感知辅助安全通信的优越性。

关键词: 星地融合网络, 通信感知一体化, 鲁棒波束成形, 物理层安全

Abstract:

A sensing assisted robust secure beamforming （BF） algorithm is proposed to address the physical layer security issue of the satellite terrestrial integrated networks. The satellite uses multicast technology to serve multiple Earth stations, while there are also airborne eavesdropper （AE） attempting to wiretap the satellite privacy signals. The ground base station employs the integrated sensing and communication technology to serve multiple users while sensing and interfering with AE to assist satellite networks in achieving secure transmission. Specifically, under the condition that only the imperfect channel state information of all users and AE is available, a transmit power minimization problem is formulated, constrained by the quality-of-service requirements of all users, the perceived signal quality requirements, and the maximum intercept probability. To solve the nonconvex problem, the maximum Rayleigh quotient theorem is first used to obtain the receive BF weight vectors of the ground base station. Then, by jointly using Bernstein inequality and Cauchy Schwarz inequality, the complex nonconvex constraints are transformed into convex ones. Then, based on the rank minimization iterative method, the weight vector of the transmission BF is solved. Simulation results verify that the proposed scheme can minimize the total transmit power of the system while guaranteeing the requirements of secure communication. By enhancing the synergy of integrated communication, sensing, and security designs, the system ultimately ensured secure communication within the space-ground integrated network, thereby demonstrating the superiority of sensing-assisted secure communication.

Key words: satellite terrestrial integrated network, integrated sensing and communication, robust beamforming （BF）, physical layer security

中图分类号:

TN 95

王振彪, 糜雨廷, 赵柏, 王金元, 林敏. 感知辅助的星地融合鲁棒安全波束成形算法[J]. 系统工程与电子技术, 2026, 48(5): 1779-1787.

Zhenbiao WANG, Yuting MI, Bai ZHAO, Jinyuan WANG, Min LIN. Sensing-assisted robust secure beamforming algorithm in satellite-terrestrial integrated networks[J]. Systems Engineering and Electronics, 2026, 48(5): 1779-1787.

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参考文献 31

1	ZHANG X, SUN S, TAO M X, et al. Multi-satellite cooperative networks: joint hybrid beamforming and user scheduling design[J]. IEEE Trans. on Wireless Communications, 2024, 23 (7): 7938- 7952. doi: 10.1109/TWC.2023.3346463
2	顾晨伟, 林志, 林敏, 等. 卫星通信下行链路鲁棒安全波束成形设计[J]. 系统工程与电子技术, 2021, 43 (5): 1361- 1370. doi: 10.12305/j.issn.1001-506X.2021.05.25
	GU C W, LIN Z, LIN M, et al. Robust secure beamforming design for the downlink of satellite communications[J]. Systems Engineering & Electronics, 2021, 43 (5): 1361- 1370. doi: 10.12305/j.issn.1001-506X.2021.05.25
3	HAN D R, YE Q, PENG H X, et al. Two-timescale learning-based task offloading for remote IoT in integrated satellite–terrestrial networks[J]. IEEE Internet of Things Journal, 2023, 10 (12): 10131- 10145. doi: 10.1109/JIOT.2023.3237209
4	DONG H, HUA C Q, TAFAZOLLI R, et al. Joint beamformer design and user scheduling for integrated terrestrial-satellite networks[J]. IEEE Trans. on Wireless Communications, 2023, 22 (10): 6398- 6414. doi: 10.1109/TWC.2023.3240734
5	TSAI K C, FAN L, LENT R, et al. Distributionally robust optimal routing for integrated satellite-terrestrial networks under uncertainty[J]. IEEE Trans. on Communications, 2024, 72 (10): 6401- 6415. doi: 10.1109/TCOMM.2024.3397809
6	LIU X Y, LIN M, TAN M M, et al. Location-based downlink transmission scheme for IRS-aided integrated satellite-terrestrial networks[J]. IEEE Trans. on Communications, 2023, 72 (2): 1090- 1104.
7	林志, 林敏, 黄清泉, 等. 能效最大化准则下的星地融合网络的安全波束成形算法[J]. 电子学报, 2022, 50 (1): 124- 134. doi: 10.12263/DZXB.20200944
	LIN Z, LIN M, HUANG Q Q, et al. Secure beamforming algorithm in satellite-terrestrial integrated networks with Energy efficiency maximization criterion[J]. Acta Electronica Sinica, 2022, 50 (1): 124- 134. doi: 10.12263/DZXB.20200944
8	MITEV M, CHORTI A, POOR H V, et al. What physical layer security can do for 6G security[J]. IEEE Open Journal of Vehicular Technology, 2023, 4, 375- 388. doi: 10.1109/OJVT.2023.3245071
9	MA Y Y, ZHANG G, XU Z, et al. Secrecy capacity of SWIPT-based cognitive satellite-terrestrial network with artificial noise and non-colluding ERs[J]. IEEE Trans. on Aerospace and Electronic Systems, 2024, 60 (6): 9029- 9044. doi: 10.1109/TAES.2024.3440270
10	LIU S Y, ZHU X M, CHEN H Y, et al. Secure communication for integrated satellite–terrestrial backhaul networks: focus on up-link secrecy capacity based on artificial noise[J]. IEEE Wireless Communications Letters, 2023, 12 (8): 1369- 1373. doi: 10.1109/LWC.2023.3274761
11	YIN Z S, CHENG N, LUAN T H, et al. Green interference based symbiotic security in integrated satellite-terrestrial communications[J]. IEEE Trans. on Wireless Communications, 2022, 21 (11): 9962- 9973. doi: 10.1109/TWC.2022.3181277
12	赵柏, 林敏, 肖圣杰, 等. 基于速率分割的可重构智能表面辅助星地融合网络鲁棒安全传输方案[J]. 通信学报, 2023, 44(12): 50−60.
	ZHAO B, LIN M, XIAO S J, et al. Rate splitting based robust secure transmission scheme in RIS-assisted satellite-terrestrial integrated network[J] Journal on Communications, 2023, 44(12): 50−60.
13	LIU F, MASOUROS C, PETROPULU A P, et al. Joint radar and communication design: applications, state-of-the-art, and the road ahead[J]. IEEE Trans. on Communications, 2020, 68 (6): 3834- 3862. doi: 10.1109/TCOMM.2020.2973976
14	李晓辉, 李欢洋, 吕思婷, 等. 毫米波通感一体化中的混合波束赋形算法[J]. 系统工程与电子技术, 2023, 45 (5): 1512- 1517.
	LI X H, LI H Y, LV S T, et al. Hybrid beamforming algorithm in mmWave integrated sensing and communication[J]. Systems Engineering & Electronics, 2023, 45 (5): 1512- 1517.
15	LIU Z, YIN L F, SHIN W, et al. Rate-splitting multiple access for quantized ISAC LEO satellite systems: a max-min fair energy-efficient beam design[J]. IEEE Trans. on Wireless Communications, 2024, 20 (10): 15394- 15408.
16	CUI Z C, HU J, CHENG J, et al. Multi-domain NOMA for ISAC: utilizing the DOF in the delay-doppler domain[J]. IEEE Communications Letters, 2022, 27 (2): 726- 730.
17	SU N C, LIU F, MASOUROS C. Secure radar-communication systems with malicious targets: Integrating radar, communications and jamming functionalities[J]. IEEE Trans. on Wireless Communications, 2020, 20 (1): 83- 95.
18	LIU P, FEI Z S, WANG X, et al. Outage constrained robust secure beamforming in integrated sensing and communication systems[J]. IEEE Wireless Communications Letters, 2022, 11 (11): 2260- 2264. doi: 10.1109/LWC.2022.3198683
19	ZOU J Q, MASOUROS C, LIU F, et al. Securing the sensing functionality in ISAC networks: an artificial noise design[J]. IEEE Trans. on Vehicular Technology, 2024, 73 (11): 17800- 17805. doi: 10.1109/TVT.2024.3422036
20	LIN Z, LIN M, CHAMPAGNE B, et al. Secrecy-energy efficient hybrid beamforming for satellite-terrestrial integrated networks[J]. IEEE Trans. on Communications, 2021, 69 (9): 6345- 6360. doi: 10.1109/TCOMM.2021.3088898
21	LIAO B, NGO H Q, MATTHAIOU M, et al. Low-complexity transmit beamforming design for massive MIMO-ISAC systems[C]//Proc. of the IEEE Global Communications Conference. Kuala Lumpur, 2023: 540−545.
22	WANG Z N, LIN M, HUANG S P, et al. Robust beamforming for IRS-aided SWIPT in cognitive satellite and terrestrial networks[J]. IEEE Communications Letters, 2023, 27 (9): 2408- 2412. doi: 10.1109/LCOMM.2023.3288483
23	LI B, PETROPULU A P. Joint transmit designs for coexistence of MIMO wireless communications and sparse sensing radars in clutter[J]. IEEE Trans. on Aerospace and Electronic Systems, 2017, 53 (6): 2846- 2864. doi: 10.1109/TAES.2017.2717518
24	CHEN L, WANG Z Q, DU Y, et al. Generalized transceiver beamforming for DFRC with MIMO radar and MU-MIMO communication[J]. IEEE Journal on Selected Areas in Communications, 2022, 40 (6): 1795- 1808. doi: 10.1109/JSAC.2022.3155515
25	KHAWAR A, ABDELHADI A, CLANCY C. Target detection performance of spectrum sharing MIMO radars[J]. IEEE Sensors Journal, 2015, 15 (9): 4928- 4940. doi: 10.1109/JSEN.2015.2424393
26	LIU F, CUI Y H, MASOUROS C, et al. Integrated sensing and communications: toward dual-functional wireless networks for 6G and beyond[J]. IEEE Journal on Selected Areas in Communications, 2022, 40 (6): 1728- 1767. doi: 10.1109/JSAC.2022.3156632
27	WANG K Y, SO A M C, CHANG T H, et al. Outage constrained robust transmit optimization for multiuser MISO downlinks: tractable approximations by conic optimization[J]. IEEE Trans. on Signal Processing, 2014, 62 (21): 5690- 5705. doi: 10.1109/TSP.2014.2354312
28	CHEN Z, LI H B, CUI G L, et al. Adaptive transmit and receive beamforming for interference mitigation[J]. IEEE Signal Processing Letters, 2014, 21 (2): 235- 239. doi: 10.1109/LSP.2014.2298497
29	SUN C C, DAI R. An iterative approach to rank minimization problems[C]//Proc. of the 54th IEEE Conference on Decision and Control, 2015: 3317−3323.
30	JU I, CHUANG D P, LEE B S. A 17.5~ 20.5 GHz 30 W GaN HPA MMIC for Ka-band satellite communications[C]//Proc. of the 27th Asia Pacific Conference on Communications, 2022: 643−644.
31	LEI L, WANG A Y, LAGUNAS E, et al. Spatial-temporal resource optimization for uneven-traffic LEO satellite systems: beam pattern selection and user scheduling[J]. IEEE Journal on Selected Areas in Communications, 2024, 42 (5): 1279- 1291. doi: 10.1109/JSAC.2024.3383445

参数	数值
卫星轨道	LEO
卫星高度/km	600
卫星载频/GHz	20
卫星天线增益^[30]/dBi	25
地面接收增益^[31]/dBi	35
带宽/MHz	400
噪声温度/k	500

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