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On stochastic string stability with applications to platooning over additive noise channels (2403.05718v1)

Published 8 Mar 2024 in eess.SY, cs.SY, and math.DS

Abstract: This paper addresses the string stabilization of vehicular platooning when stochastic phenomena are inherent in inter-vehicle communication. To achieve this, we first provide two definitions to analytically assess the string stability in stochastic scenarios, considering the mean and variance of tracking errors as the platoon size grows. Subsequently, we analytically derive necessary and sufficient conditions to achieve this notion of string stability in predecessor-following linear platoons that communicate through additive white noise channels. We conclude that the condition ensuring string stability with ideal communication is essentially the same that achieves stochastic string stability when additive noise channels are in place and guarantees that the tracking error means and variances converge.

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References (33)
  1. Stochastic string stability of vehicle platoons via cooperative adaptive cruise control with lossy communication. IEEE Trans. on Intelligent Transportation Systems, 23(8):10912–10922, 2022.
  2. K. J. Åström. Introduction to stochastic control theory. Courier Corporation, 2012.
  3. K. J. Åström and B. Wittenmark. Computer-controlled systems: theory and design. Courier Corporation, 2013.
  4. D. S. Bernstein. Matrix mathematics. Princeton university press, 2009.
  5. B. Besselink and K. H. Johansson. String stability and a delay-based spacing policy for vehicle platoons subject to disturbances. IEEE Trans. on Automatic Control, 62(9):4376–4391, 2017.
  6. Distributed consensus control of vehicular platooning under delay, packet dropout and noise: Relative state and relative input-output control strategies. IEEE Trans. on Intelligent Transportation Systems, 23(11):20123–20133, 2022.
  7. String stability for vehicular platoon control: Definitions and analysis methods. Annual Reviews in Control, 47:81–97, 2019.
  8. Y. Feng and H. Sun. Robust optimal control for discrete-time lti systems over multiple additive white gaussian noise channels. IEEE Trans. on Automatic Control, 68(9):5174–5186, 2023.
  9. A. Goldsmith. Wireless communications. Cambridge university press, 2005.
  10. Mean square stabilization over SNR-constrained channels with colored and spatially correlated additive noises. IEEE Trans. on Automatic Control, 64(11):4825–4832, 2019.
  11. Comparison of simple strategies for vehicular platooning with lossy communication. IEEE Access, 9:103996–104010, 2021.
  12. Mean square stability conditions for platoons with lossy inter-vehicle communication channels. Automatica, 147:110710, 2023.
  13. Platoon stability conditions under inter-vehicle additive noisy communication channels. IFAC-PapersOnLine, 53(2):3150–3155, 2020.
  14. String stability analysis for vehicle platooning under unreliable communication links with event-triggered strategy. IEEE Trans. on Vehicular Technology, 68(3):2152–2164, 2019.
  15. Robust control of heterogeneous vehicular platoon with non-ideal communication. Electronics, 8(2), 2019.
  16. Internal stability and string stability of connected vehicle systems with time delays. IEEE Trans. on Intelligent Transportation Systems, 22(10):6162–6174, 2021.
  17. Distributed control of cooperative vehicular platoon with nonideal communication condition. IEEE Trans. on Vehicular Technology, 2020.
  18. Leader tracking in homogeneous vehicle platoons with broadcast delays. Automatica, 50(1):64–74, 2014.
  19. Lp string stability of cascaded systems: Application to vehicle platooning. IEEE Trans. on Control Systems Technology, 22(2):786–793, 2014.
  20. Stability and frequency response under stochastic communication delays with applications to connected cruise control design. IEEE Trans. on Intelligent Transportation Systems, 18(2):388–403, 2017.
  21. Cooperative adaptive cruise control in the presence of communication and radar stochastic data loss. IEEE Trans. on Intelligent Transportation Systems, 2024.
  22. L. Rybarska-Rusinek and L. Socha. String stability of singularly perturbed stochastic systems. Stochastic analysis and applications, 25(4):719–737, 2007.
  23. L. Socha. Stochastic stability of interconnected string systems. Chaos, Solitons & Fractals, 19(4):949–955, 2004.
  24. T. Söderström. Discrete-time stochastic systems: estimation and control. Springer Science & Business Media, 2002.
  25. String stability for predecessor following platooning over lossy communication channels. In International Symposium on Mathematical Theory of Networks and Systems, 2018.
  26. Stabilization of two-input two-output systems over SNR-constrained channels. Automatica, 49(10):3133–3140, 2013.
  27. String stability of connected vehicle platoons under lossy v2v communication. IEEE Trans. on Intelligent Transportation Systems, 23(7):8834–8845, 2022.
  28. Numerical and empirical study of a kalman filtering-based strategy for platooning with lossy communication. Submitted to Mathematics, 2023.
  29. A survey on cooperative longitudinal motion control of multiple connected and automated vehicles. IEEE Intelligent Transportation Systems Magazine, 12(1):4–24, 2020.
  30. Automated vehicle-involved traffic flow studies: A survey of assumptions, models, speculations, and perspectives. Transportation research part C: emerging technologies, 127:103101, 2021.
  31. Stability analysis of vehicle platooning with limited communication range and random packet losses. IEEE Internet of Things Journal, 8(1):262–277, 2021.
  32. Vehicle platooning with non-ideal communication networks. IEEE Trans. on Vehicular Technology, 70(1):18–32, 2021.
  33. Robust and Optimal Control. Feher/Prentice Hall Digital and. Prentice Hall, 1996.
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