Abstract
When shared, band-limited, real-time communication networks are employed in a control system to exchange information between spatially distributed components, such as controllers, actuators, and sensors, it is categorized as a networked control system (NCS). The primary advantages of a NCS are reduced complexity and wiring, reduced design and implementation cost, ease of system maintenance and modification, and efficient data sharing. In addition, this unique architecture creates a way to connect the cyberspace to the physical space for remote operation of systems. The NCS architecture allows for performing more complex tasks, but also requires taking the network effects into account when designing control laws and stability conditions. In this entry, we review significant results on the architecture and stability analysis of a NCS. The results presented address communication network-induced challenges such as time delays, scheduling, and information packet dropouts.
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Bibliography
Baillieul J (1999) Feedback designs for controlling device arrays with communication channel bandwidth constraints. In: Lecture notes of the fourth ARO workshop on smart structures, Penn State University
Baillieul J, Antsaklis PJ (2007) Control and communication challenges in networked control systems. Proc IEEE 95(1):9–28
Hespanha JP, Naghshtabrizi P, Xu Y (2007) A survey of recent results in networked control systems. Proc IEEE 95(1):138–162
Johansson KH, Torngren M, Nielsen L (2005) Vehicle applications of controller area network. In: Levine WS, Hristu-Varsakelis D (eds) Handbook of networked and embedded control systems. Birkhäuser, Boston, pp 741–765
Lin H, Zhai G, Antsaklis PJ (2003) Robust stability and disturbance attenuation analysis of a class of networked control systems. In: 42nd IEEE conference on decision and control, Maui, vol 2, pp 1182–1187
Lin H, Zhai G, Fang L, Antsaklis PJ (2005) Stability and H1 performance preserving scheduling policy for networked control systems. In: Proceedings 16th IFAC world congress, Prague
Montestruque LA, Antsaklis PJ (2004) Stability of model-based networked control systems with time-varying transmission times. IEEE Trans Autom Control 49(9):1562–1572
Nair GN, Evans RJ (2000) Stabilization with data-rate-limited feedback: tightest attainable bounds. Syst Control Lett 41(1):49–56. Elsevier
Nesic D, Teel A (2004a) Input-output stability properties of networked control systems. IEEE Trans Autom Control 49(10):1650–1667
Nesic D, Teel A (2004b) Input-to-state stability of networked control systems. Automatica 40(12):2121–2128
Onat A, Naskali T, Parlakay E, Mutluer O (2011) Control over imperfect networks: model-based predictive networked control systems. IEEE Trans Ind Electron 58:905–913
Seiler P, Sengupta R (2005) An H ∞ approach to networked control, IEEE Trans Autom Control 50(3):356–364
Tabbara M, Nesic D, Teel A (2007) Stability of wireless and wireline networked control systems. IEEE Trans Autom Control 52(9):1615–1630
Tatikonda S, Mitter S (2004) Control under communication constraints. IEEE Trans Autom Control 49(7):1056–1068
Walsh G, Ye H (2001) Scheduling of networked control systems. IEEE Control Syst Mag 21(1): 57–65
Walsh G, Ye H, Bushnell L (2001a) Stability analysis of networked control systems. IEEE Trans Control Syst Technol 10(3):438–446
Walsh G, Beldiman O, Bushnell L (2001b) Asymptotic behavior of nonlinear networked control systems. IEEE Trans Autom Control 44:1093–1097
Wang X, Hovakimyan N (2013) Distributed control of uncertain networked systems: a decoupled design. IEEE Trans Autom Control 58(10):2536–2549
Wong WS, Brockett RW (1999) System with finite communication bandwidth constraints-II: stabilization with limited information feedback. IEEE Trans Autom Control 44(5):1049–1053
Yang TC (2006) Networked control system: a brief survey. IEE Proc Control Theory Appl 153(4):403–412
Ye H, Walsh G, Bushnell L (2001) Real-time mixed-traffic wireless networks. IEEE Trans Ind Electron 48(5):883–890
Yu M, Wang L, Chu T, Hao F (2004) An LMI approach to networked control systems with data packet dropout and transmission delays. 43rd IEEE conference on decision and control, Paridise Island, Bahamas, vol 4, pp 3545–3550
Yue D, Han QL, Peng C (2004) State feedback controller design for networked control systems. IEEE Trans Circuits Syst 51(11):640–644
Zhai G, Hu B, Yasuda K, Michel A (2002), Qualitative analysis of discrete-time switched systems, in Proc. Amer. Contr. Conf, vol 3, pp 1880–1885
Zhang W, Branicky MS (2001) Stability of networked control systems with time-varying transmission period. In: Allerton conference on communication, control, and computing, Monticello, IL
Zhang W, Branicky MS, Phillips SM (2001) Stability of networked control systems. IEEE Control Syst Mag 21(1):84–99
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Bushnell, L., Ye, H. (2015). Networked Control Systems: Architecture and Stability Issues. In: Baillieul, J., Samad, T. (eds) Encyclopedia of Systems and Control. Springer, London. https://doi.org/10.1007/978-1-4471-5058-9_151
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DOI: https://doi.org/10.1007/978-1-4471-5058-9_151
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