| [1] |
Hoffmann, C.; Werner, H., A survey of linear parameter-varying control applications validated by experiments or high-fidelity simulations, IEEE Trans. Control Syst. Tech., 23, 2, 416-433 (2014) |
| [2] |
Antonio, S., Stability analysis of LPV systems: Scenario approach, Automatica, 104, 233-237 (2019) · Zbl 1415.93190 |
| [3] |
Chen, JL; Zhang, WD; Cao, YY, Observer-based consensus control against actuator faults for linear parameter-varying multiagent systems, IEEE Trans. Syst. Man Cybern., 47, 7, 1336-1347 (2016) |
| [4] |
Xing, MQ; Wang, YQ; Zhuang, GM; Chen, F., Dynamic event-based dissipative asynchronous control for singular Markov jump LPV systems with general transition rates, IET Control Theory Appl. (2020) · doi:10.1049/cth2.12067 |
| [5] |
Wang, Y.; Zhuang, GM; Chen, X.; Wang, Z.; Chen, F., Dynamic event-based finite-time mixed \(H_{\infty }\) and passive asynchronous filtering for T-S fuzzy singular Markov jump systems with general transition rates, Nonlinear Anal. Hybrid Syst., 36, 100874 (2020) · Zbl 1441.93071 |
| [6] |
Zhang, B.; Song, Y., Asynchronous Constrained Resilient Robust Model Predictive Control for Markovian Jump Systems, IEEE Trans. Ind. Inform., 16, 11, 7025-7034 (2020) |
| [7] |
Li, F.; Xu, S.; Shen, H., Passivity-Based Control for Hidden Markov Jump Systems with Singular Perturbations and Partially Unknown Probabilities, IEEE Trans. Autom. Control, 65, 8, 3701-3706 (2020) · Zbl 1533.93758 |
| [8] |
Gunes, B.; Wingerden, JW; Verhaegen, M., Predictor-based tensor regression (PBTR) for LPV subspace identification, Automatica, 79, 235-243 (2017) · Zbl 1371.93207 |
| [9] |
Zhu, Y.; Zhong, Z.; Zheng, WX, HMM-Based \({\cal{H}}_{\infty }\) Filtering for Discrete-Time Markov Jump LPV Systems Over Unreliable Communication Channels, IEEE Trans. Syst. Man Cybern., 48, 12, 2035-2046 (2017) |
| [10] |
Wang, X.; Xia, J.; Wang, J., Reachable set estimation for Markov jump LPV systems with time delays, Appl. Math. Comput., 376, 125117 (2020) · Zbl 1475.60137 |
| [11] |
Kim, SH, \({\cal{H}}_2\) control of Markovian jump LPV systems with measurement noises: Application to a DC-motor device with voltage fluctuations, J. Frankl. Inst., 354, 4, 1784-1800 (2017) · Zbl 1378.93136 |
| [12] |
Cheng, J.; Zhang, D.; Qi, W.; Cao, J.; Shi, K., Finite-time stabilization of T-S fuzzy semi-Markov switching systems: A coupling memory sampled-data control approach, J. Frankl. Inst., 357, 16, 11265-11280 (2019) · Zbl 1450.93054 |
| [13] |
Dong, S.; Chen, CLP; Fang, M.; Wu, Z., Dissipativity-based asynchronous fuzzy sliding mode control for T-S fuzzy hidden Markov jump systems, IEEE Trans. Cybern., 50, 9, 4020-4030 (2020) |
| [14] |
Ren, Y.; Li, Q.; Ding, D., Dissipativity-preserving model reduction for Takagi-Sugeno fuzzy systems, IEEE Trans. Fuzzy Syst., 27, 4, 659-670 (2019) |
| [15] |
Zhang, J.; Peng, C., Event-triggered \(H_{\infty }\) filtering for networked Takagi-Sugeno fuzzy systems with asynchronous constraints, IET Signal Process., 9, 5, 403-411 (2015) |
| [16] |
Kwon, W.; Jin, Y.; Lee, SM, PI-type event-triggered \(H_{\infty }\) filter for networked T-S fuzzy systems using affine matched membership function approach, Appl. Math. Comput., 385, 125420 (2020) · Zbl 1508.93304 |
| [17] |
Joo, YH; Nagamani, G., Event-triggered stabilisation for T-S fuzzy systems with asynchronous premise constraints and its application to wind turbine system, IET Control Theory Appl., 13, 10, 1532-1542 (2019) · Zbl 1432.93195 |
| [18] |
Kim, SH, Dissipative control of Markovian jump fuzzy systems under nonhomogeneity and asynchronism, Nonlinear Dyn., 97, 3, 629-646 (2019) · Zbl 1430.60067 |
| [19] |
Nguyen, TB; Kim, SH, Dissipative control of interval type-2 nonhomogeneous Markovian jump fuzzy systems with incomplete transition descriptions, Nonlinear Dyn., 100, 2, 1289-1308 (2020) · Zbl 1459.93090 |
| [20] |
Wu, HM; Tafreshi, R., Air-fuel ratio control of lean-burn SI engines using the LPV-based fuzzy technique, IET Control Theory Appl., 12, 10, 1414-1420 (2018) |
| [21] |
Mehrabian, AR; Hashemi, SV, Fuzzy linear parameter varying modeling and control of an anti-air missile, Int. J. Control Autom. Syst., 5, 3, 324-328 (2007) |
| [22] |
Rajkumar, R., Lee, I., Sha, L.: Cyber-physical systems: the next computing revolution. In: Proceesings of the 47th Design Automation Conference, pp. 731-736 DAC (2010) |
| [23] |
Xu, Z.; He, D.; Wang, H., A novel proxy-oriented public auditing scheme for cloud-based medical cyber physical systems, J. Inform. Security Appl., 51, 102453 (2020) |
| [24] |
Ma, Q.; Xu, S., Consensus switching of second-order multiagent systems with time delay, IEEE Trans. Cybern. (2020) · doi:10.1109/TCYB.2020.3011448 |
| [25] |
Xia, X.; Liu, C.; Wang, H., A Design of Cyber-Physical System Architecture for Smart City. Recent Trends in Intelligent Computing, Communication and Devices, 967-973 (2020), Singapore: Springer, Singapore |
| [26] |
Cheng, J.; Park, JH; Zhao, X.; Karimi, HR; Cao, J., Quantized nonstationary filtering of network-based Markov switching RSNSs: a multiple hierarchical structure strategy, IEEE Trans. Autom. Control, 65, 11, 4816-4823 (2019) · Zbl 1536.93909 |
| [27] |
Yuan, H.; Xia, Y.; Yang, H., Resilient state estimation of cyber-physical system with multichannel transmission under DoS attack, IEEE Trans. Syst. Man Cybern. Syst. (2020) · doi:10.1109/TSMC.2020.2964586 |
| [28] |
Zhang, H.; Wang, Z.; Yan, HC; Yang, F.; Zhou, X., Adaptive event-triggered transmission scheme and \(H_{\infty }\) filtering co-design over a filtering network with switching topology, IEEE Trans. Cybern., 49, 12, 4296-4307 (2019) |
| [29] |
Fu, W.; Qin, J.; Shi, Y., Resilient consensus of discrete-time complex cyber-physical networks under deception attacks, IEEE Trans Ind. Inform., 16, 7, 4868-4877 (2019) |
| [30] |
Tian, E.; Peng, C., Memory-based event-triggering \({\cal{H}}_{\infty }\) load frequency control for power systems under deception attacks, IEEE Trans. Cybern., 50, 11, 4610-4618 (2020) |
| [31] |
Yuan, J.; Wang, Y.; Ji, Z., A differentially private square root unscented Kalman filter for protecting process parameters in ICPSs, ISA Trans., 104, 44-52 (2020) |
| [32] |
Wang, HT; Wang, YQ; Zhuang, GM, Asynchronous \(H_{\infty }\) controller design for neutral singular Markov jump systems under dynamic event-triggered schemes, J. Frankl. Inst. (2020) · Zbl 1455.93047 · doi:10.1016/j.jfranklin.2020.10.034 |
| [33] |
Yan, HC; Hu, CY; Zhang, H.; Karimi, HR; Jiang, XW, \(H_{\infty }\) output tracking control for networked systems with adaptively adjusted event-triggered scheme, IEEE Trans. Syst. Man Cybernet., 49, 10, 2050-2058 (2019) |
| [34] |
Cheng, J.; Park, JH; Cao, J.; Qi, W., A hidden mode observation approach to finite-time SOFC of Markovian switching systems with quantization, Nonlinear Dyn., 100, 509-521 (2020) · Zbl 1434.93019 |
| [35] |
Qi, Y.; Zeng, P.; Bao, W., Event-triggered and self-triggered \({\cal{H}}_{\infty }\) control of uncertain switched linear systems, IEEE Trans Syst. Man Cybern. Syst., 50, 4, 1442-1454 (2018) |
| [36] |
Qi, WH; Zong, GD; Zheng, WX, Adaptive event-triggered SMC for stochastic switching systems with semi-Markov process and application to boost converter circuit model, IEEE Trans. Circuits Syst. I: Regular Papers (2020) · doi:10.1109/TCSI.2020.3036847 |
| [37] |
Peng, C.; Han, Q.; Yue, D., To transmit or not to transmit: a discrete event-triggered communication scheme for networked Takagi-Sugeno fuzzy systems, IEEE Trans. Fuzzy Syst., 21, 1, 164-170 (2013) |
| [38] |
Liu, Y.; Guo, BZ; Park, JH, Event-based reliable dissipative filtering for T-S fuzzy systems with asynchronous constraints, IEEE Trans. Fuzzy Syst., 26, 4, 2089-2098 (2018) |
| [39] |
Chen, ZR; Zhang, BY, Event-based control for networked T-S fuzzy systems via auxiliary random series approach, IEEE Trans. Cyber., 50, 5, 2166-2175 (2018) |
| [40] |
Cheng, J.; Ahn, CK; Karim, HR, An event-based asynchronous approach to Markov jump systems with hidden mode detections and missing Measurements, IEEE Trans. Syst. Man Cybern. Syst., 49, 9, 1749-1758 (2019) |
| [41] |
Qiu, J.; Sun, K.; Wang, T., Observer-based fuzzy adaptive event-triggered control for pure-feedback nonlinear systems with prescribed performance, IEEE Trans. Fuzzy Syst., 27, 11, 2152-2162 (2019) |
| [42] |
Tian, E.; Wang, Z.; Zou, L., Probabilistic-constrained filtering for a class of nonlinear systems with improved static event-triggered communication, Int. J. Robust Nonlinear Control, 29, 5, 1484-1498 (2019) · Zbl 1410.93130 |
| [43] |
Ge, X.; Han, QL; Wang, Z., A dynamic event-triggered transmission scheme for distributed set-membership estimation over wireless sensor networks, IEEE Trans Cybern., 49, 1, 171-183 (2017) |
| [44] |
Lehmann, D.; Lunze, J., Extension and experimental evaluation of an event-based state-feedback approach, Control Eng. Practice, 19, 2, 101-112 (2011) |
| [45] |
Yang, RH; Zhang, H.; Feng, G.; Yan, HC; Wang, ZP, Robust cooperative output regulation of multi-agent systems via adaptive event-triggered control, Automatica, 102, 129-136 (2019) · Zbl 1415.93100 |
| [46] |
Zhang, Q.; Yan, H.; Zhang, H., \({\cal{H}}_{\infty }\) control of singular system based on stochastic cyber-attacks and dynamic event-triggered mechanism, IEEE Trans. Syst. Man Cybern. Syst. (2020) · Zbl 1478.93712 · doi:10.1016/j.nahs.2020.100943 |
| [47] |
Wang, YQ; Chen, F.; Zhuang, GM, Dynamic event-based reliable dissipative asynchronous control for stochastic Markov jump systems with general transition probabilities, Nonlinear Dyn., 101, 1, 465-485 (2020) · Zbl 1516.93057 |
| [48] |
Wang, HT; Wang, YQ; Zhuang, GM; Lu, JW, Asynchronous passive dynamic event-triggered controller design for singular Markov jump systems with general transition rates under stochastic cyber-attacks, IET Control Theory Appl., 14, 16, 2291-2302 (2020) · Zbl 1542.93271 |
| [49] |
Tagaki, T.; Sugeno, M., Fuzzy identification of systems and its application to modelling and control, IEEE Trans. Syst. Man Cybern. Syst., 15, 1, 116-132 (1985) · Zbl 0576.93021 |
| [50] |
Yue, D.; Tian, E.; Han, QL, A delay system method for designing event-triggered controllers of networked control systems, IEEE Trans. Autom. Control, 58, 2, 475-481 (2013) · Zbl 1369.93183 |
