This paper studies the issue of sliding mode control for nonlinear cyber-physical systems subject to actuator false data injection attacks and multi-source disturbances at the same time. To begin with, nonlinear disturbance observers are developed to estimate the unknown disturbances. Then, to counter the effects from false data injection attacks, an attack compensator is designed based on higher-order sliding mode observer, which can online estimate the attack values. Subsequently, by integrating the attack and disturbance estimations, a dynamic sliding manifold is constructed, and then a novel sliding mode controller is designed. Under the proposed approach, the false data injection attacks and multi-source disturbances can be online estimated and compensated, thereby enhancing disturbance rejection ability and security for nonlinear cyber-physical systems. In addition, satisfactory control performance can be achieved with smaller switching gain under the proposed approach, and the chattering in sliding mode controller can be effectively attenuated. Finally, the proposed approach is applied for a single-link manipulator system, and simulation results demonstrate the effectiveness and superiority.
AshibaniYMahmoudQH (2017) Cyber physical systems security: Analysis, challenges and solutions. Computers & Security68: 81–97.
2.
ChenHZongGZhaoX, et al. (2023) Secure filter design of fuzzy switched CPSs with mismatched modes and application: A multidomain event-triggered strategy. IEEE Transactions on Industrial Informatics19(10): 10034–10044.
3.
ChenWH (2003) Nonlinear disturbance observer-enhanced dynamic inversion control of missiles. Journal of Guidance, Control, and Dynamics26(1): 161–166.
4.
DongSLiuM (2023) Adaptive fuzzy asynchronous control for nonhomogeneous Markov jump power systems under hybrid attacks. IEEE Transactions on Fuzzy Systems31(3): 1009–1019.
5.
DongYGuptaNChopraN (2020) False data injection attacks in bilateral teleoperation systems. IEEE Transactions on Control Systems Technology28(3): 1168–1176.
6.
DrazinPG (1992) Nonlinear systems. Cambridge: Cambridge University Press.
7.
FuHKrishnamurthyPKhorramiF (2025) Combining switching mechanism with re-initialization and anomaly detection for resiliency of cyber-physical systems. Automatica172: 111994.
8.
FuWQinJShiY, et al. (2019) Resilient consensus of discrete-time complex cyber-physical networks under deception attacks. IEEE Transactions on Industrial Informatics16(7): 4868–4877.
9.
GuoWLiuFWangY, et al. (2025) Adaptive event-triggered sliding mode load frequency control for cyber-physical power systems under false data injection attacks. IEEE Transactions on Industrial Informatics21: 2947–2956.
10.
HeLWangXZhangY, et al. (2024) Resilient cooperative platoon control for leader-following uncertain vehicular systems subject to cyber-physical attacks. Transactions of the Institute of Measurement and Control. Epub ahead of print 25 September. DOI: 10.1177/01423312241273783.
11.
JafariARezaeiSShiry GhidaryS, et al. (2013) A stable perturbation estimator in force-reflecting passivity-based teleoperation. Transactions of the Institute of Measurement and Control35(2): 147–156.
12.
KorayemMHDehkordiSFGhobadiN (2024) Wheel slippage compensation in mobile manipulators through combined kinematic, dynamic, and sliding mode control. Arabian Journal for Science and Engineering49(8): 11565–11585.
13.
LevantA (2003) Higher-order sliding modes, differentiation and output-feedback control. International Journal of Control76(9–10): 924–941.
14.
LiLChenYLiM, et al. (2023) Adaptive robust FDI attack detection for cyber-physical systems with disturbance. ICT Express9(4): 656–663.
15.
LiXZhangPDongH (2024) A robust covert attack strategy for a class of uncertain cyber-physical systems. IEEE Transactions on Automatic Control69(3): 1983–1990.
16.
LiuSWangXChenW, et al. (2025) Adaptive control for uncertain nonlinear systems against DoS attacks using quantized output only and application to a single-link robot. IEEE Transactions on Automation Science and Engineering22: 5262–5271.
17.
LuGLiKLiY (2025) Predefined time fuzzy adaptive tracking control for nonlinear cyber physical systems with unmeasurable states and FDI attacks. Nonlinear Dynamics113: 3389–3404.
18.
MazareM (2023) Reinforcement learning-based fixed-time resilient control of nonlinear cyber physical systems under false data injection attacks and mismatch disturbances. Journal of the Franklin Institute-Engineering and Applied Mathematics360(18): 14926–14938.
19.
QiYZhangSAhnCK (2023) Active disturbance rejection control for networked switched nonlinear systems with decentralized event-triggered communication. IEEE Transactions on Systems Man Cybernetics-Systems53(6): 3553–3565.
20.
QuYJiY (2024) Fractional-order finite-time sliding mode control for uncertain teleoperated cyber-physical system with actuator fault. ISA Transactions144: 61–71.
21.
RouhaniSHMojallaliHBaghramianA (2022) Load frequency control in the presence of simultaneous cyber-attack and participation of demand response program. Transactions of the Institute of Measurement and Control44(10): 1993–2011.
22.
ShenXLiuJLiuZ, et al. (2024) Sliding-mode control of neutral-point-clamped power converters with gain adaptation. IEEE Transactions on Power Electronics39(8): 9189–9201.
23.
SongJZhouSNiuY, et al. (2023) Antidisturbance control for hidden Markovian jump systems: Asynchronous disturbance observer approach. IEEE Transactions on Automatic Control68(11): 6982–6989.
24.
SunQYangGHDimirovskiGM (2024) Secure state estimation with disturbance rejection against switched sparse sensor attacks. Information Sciences675: 120709.
25.
TaheriMKhorasaniKMeskinN (2024) On zero dynamics and controllable cyber-attacks in cyber-physical systems and dynamic coding schemes as their countermeasures. IEEE-CAA Journal of Automatica Sinica11(11): 2191–2203.
26.
WangYZongGZhaoX, et al. (2024) Adaptive practical fixed-time synchronized tracking control of ASV with prescribed performance. Automatica166: 111716.
27.
WuYZhangLXieW, et al. (2024) Robust mixed h2/h∞ model predictive control for cyber-physical systems with input saturation and energy-bounded disturbance. IEEE Transactions on Industrial Informatics20(6): 8328–8337.
28.
XingSMengMDengF (2024) Fault-tolerant control of nonlinear networked control systems based on a dynamic event-triggered mechanism under dual cyber attacks. Transactions of the Institute of Measurement and Control. Epub ahead of print 25October. DOI: 10.1177/01423312241279903.
29.
XuKNiuY (2023) Decentralized event-triggered sliding mode scheme for frequency regulation of multi-area power systems under deception attacks. Transactions of the Institute of Measurement and Control. Epub ahead of print 8 March. DOI: 10.1177/01423312231156237.
30.
XueYRenWZhengBC, et al. (2022) Event-triggered adaptive sliding mode control of cyber-physical systems under false data injection attack. Applied Mathematics and Computation433: 127403.
31.
YangHHanHYinS, et al. (2022) Sliding mode-based adaptive resilient control for Markovian jump cyber-physical systems in face of simultaneous actuator and sensor attacks. Automatica142: 110345.
32.
YangJLiSYuX (2012) Sliding-mode control for systems with mismatched uncertainties via a disturbance observer. IEEE Transactions on Industrial Electronics60(1): 160–169.
33.
YangJYuXZhangL, et al. (2021) A Lyapunov-based approach for recursive continuous higher order nonsingular terminal sliding-mode control. IEEE Transactions on Automatic Control66(9): 4424–4431.
34.
YangMZhaiJ (2025) Predictor-based event-triggered learning control of networked control systems with false data injection attacks and output delay. Applied Mathematics and Computation490: 129213.
35.
YangYGaoXSongS, et al. (2025) Distributed consensus-based filtering against false data injection attacks. IEEE Transactions on Network Science and Engineering12(1): 110–121.
36.
YeZJiangBYuZ, et al. (2025) Adaptive descriptor sliding-mode observer-based dynamic event-triggered consensus of multiagent systems against actuator and sensor faults. IEEE Transactions on Cybernetics55: 672–683.
37.
YooSJ (2019) Neural-network-based adaptive resilient dynamic surface control against unknown deception attacks of uncertain nonlinear time-delay cyberphysical systems. IEEE Transactions on Neural Networks and Learning Systems31(10): 4341–4353.
38.
YuSYuXShirinzadehB, et al. (2005) Continuous finite-time control for robotic manipulators with terminal sliding mode. Automatica41(11): 1957–1964.
39.
ZhangBRenYAnC, et al. (2025) Optimal tracking performance of networked control systems with time delay under multiplicative false data injection attacks. Systems & Control Letters196: 105985.
40.
ZhangLChenZYuX, et al. (2023a) Sliding-mode-based robust output regulation and its application in PMSM servo systems. IEEE Transactions on Industrial Electronics70(2): 1852–1860.
41.
ZhangLYangJ (2022) Continuous nonsingular terminal sliding mode control for nonlinear systems subject to mismatched terms. Asian Journal of Control24(2): 885–894.
42.
ZhangQLiuKHanD, et al. (2023b) Design of stealthy deception attacks with partial system knowledge. IEEE Transactions on Automatic Control68(2): 1069–1076.
43.
ZhaoYChenZZhouC, et al. (2021) Passivity-based robust control against quantified false data injection attacks in cyber-physical systems. IEEE/CAA Journal of Automatica Sinica8(8): 1440–1450.
44.
ZongGXieHYangD, et al. (2024) Adaptive fuzzy tracking control for switched nonlinear systems under FDI attacks and input saturation: A flexible transient performance approach. IEEE Transactions on Cybernetics54: 7479–7488.
