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Moving-Horizon Estimators for Hyperbolic and Parabolic PDEs in 1-D (2401.02516v2)

Published 4 Jan 2024 in eess.SY, cs.AI, cs.SY, math.AP, math.DS, and math.OC

Abstract: Observers for PDEs are themselves PDEs. Therefore, producing real time estimates with such observers is computationally burdensome. For both finite-dimensional and ODE systems, moving-horizon estimators (MHE) are operators whose output is the state estimate, while their inputs are the initial state estimate at the beginning of the horizon as well as the measured output and input signals over the moving time horizon. In this paper we introduce MHEs for PDEs which remove the need for a numerical solution of an observer PDE in real time. We accomplish this using the PDE backstepping method which, for certain classes of both hyperbolic and parabolic PDEs, produces moving-horizon state estimates explicitly. Precisely, to explicitly produce the state estimates, we employ a backstepping transformation of a hard-to-solve observer PDE into a target observer PDE, which is explicitly solvable. The MHEs we propose are not new observer designs but simply the explicit MHE realizations, over a moving horizon of arbitrary length, of the existing backstepping observers. Our PDE MHEs lack the optimality of the MHEs that arose as duals of MPC, but they are given explicitly, even for PDEs. In the paper we provide explicit formulae for MHEs for both hyperbolic and parabolic PDEs, as well as simulation results that illustrate theoretically guaranteed convergence of the MHEs.

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References (39)
  1. Nonlinear predictive control and moving horizon estimation — an introductory overview. In P. M. Frank, editor, Advances in Control, pages 391–449, London, 1999. Springer London.
  2. P. Bernard and M. Krstic. Adaptive output-feedback stabilization of non-local hyperbolic PDEs. Automatica, 50(10):2692–2699, 2014.
  3. Neural operators for bypassing gain and control computations in PDE backstepping. arXiv, 2023. https://arxiv.org/abs/2302.14265.
  4. Operator learning for nonlinear adaptive control. In N. Matni, M. Morari, and G. J. Pappas, editors, Proceedings of The 5th Annual Learning for Dynamics and Control Conference, volume 211 of Proceedings of Machine Learning Research, pages 346–357. PMLR, 15–16 Jun 2023.
  5. Stabilization of a system of n+1𝑛1n+1italic_n + 1 coupled first-order hyperbolic linear PDEs with a single boundary input. IEEE Transactions on Automatic Control, 58(12):3097–3111, 2013.
  6. M. K. J. Dongmo and T. Meurer. Moving horizon estimator design for a nonlinear diffusion-reaction system with sensor dynamics. IFAC-PapersOnLine, 55(20):85–90, 2022. 10th Vienna International Conference on Mathematical Modelling MATHMOD 2022.
  7. L. C. Evans. Partial differential equations. American Mathematical Society, Providence, R.I., 2010.
  8. Moving horizon estimation for hybrid systems. IEEE Transactions on Automatic Control, 47(10):1663–1676, 2002.
  9. Critical evaluation of extended kalman filtering and moving-horizon estimation. Industrial & Engineering Chemistry Research, 44(8):2451–2460, 2005.
  10. Fast moving horizon estimation for a two-dimensional distributed parameter system. Computers & Chemical Engineering, 63:159–172, 2014.
  11. Robust stability of moving horizon estimation under bounded disturbances. IEEE Transactions on Automatic Control, 61(11):3509–3514, 2016.
  12. I. Karafyllis and M. Krstic. Input-to-State Stability for PDEs. Springer Cham, 1 edition, 2019.
  13. Moving horizon estimation and nonlinear model predictive control for autonomous agricultural vehicles. Computers and Electronics in Agriculture, 98:25–33, 2013.
  14. Neural operators of backstepping controller and observer gain functions for reaction-diffusion PDEs. arXiv, 2023. https://arxiv.org/abs/2303.10506.
  15. Nonlinear Control of the Viscous Burgers Equation: Trajectory Generation, Tracking, and Observer Design. Journal of Dynamic Systems, Measurement, and Control, 131(2):021012, 02 2009.
  16. M. Krstic and A. Smyshlyaev. Boundary Control of PDEs: A Course on Backstepping Designs. SIAM, 2008.
  17. An industrial case study on the combined identification and offset-free control of a chemical process. Computers & Chemical Engineering, 179:108429, 2023.
  18. Moving horizon estimation for mobile robots with multirate sampling. IEEE Transactions on Industrial Electronics, 64(2):1457–1467, 2017.
  19. Backstepping observer-based output feedback control for a class of coupled parabolic PDEs with different diffusions. Systems & Control Letters, 97:61–69, 2016.
  20. Adaptive PDE observer for battery SOC/SOH estimation via an electrochemical model. ASME Journal of Dynamic Systems, Measurement, and Control, 136:011015–011026, 01 2014.
  21. Nonlinear Moving Horizon State Estimation, pages 349–365. Springer Netherlands, Dordrecht, 1995.
  22. Receding horizon recursive state estimation. In 1993 American Control Conference, pages 900–904, 1993.
  23. Constrained state estimation for nonlinear discrete-time systems: stability and moving horizon approximations. IEEE Transactions on Automatic Control, 48(2):246–258, 2003.
  24. Constrained linear state estimation—a moving horizon approach. Automatica, 37(10):1619–1628, 2001.
  25. Particle filtering and moving horizon estimation. Computers & Chemical Engineering, 30(10):1529–1541, 2006. Papers form Chemical Process Control VII.
  26. Model Predictive Control: Theory, Design, and Computation. Nob Hill Publishing, Santa Barbara, CA, 2nd, paperback edition, 2020. 770 pages, ISBN 978-0-9759377-5-4.
  27. A moving horizon-based approach for least-squares estimation. AIChE Journal, 42(8):2209–2224, 1996.
  28. Machine learning accelerated PDE backstepping observers. In 2022 IEEE 61st Conference on Decision and Control (CDC), pages 5423–5428, 2022.
  29. A. Smyshlyaev and M. Krstic. Closed-form boundary state feedbacks for a class of 1-D partial integro-differential equations. IEEE Transactions on Automatic Control, 49(12):2185–2202, 2004.
  30. A. Smyshlyaev and M. Krstic. Backstepping observers for a class of parabolic PDEs. Systems & Control Letters, 54(7):613–625, 2005.
  31. A. Smyshlyaev and M. Krstic. Adaptive Control of Parabolic PDEs. Princeton University Press, 2010.
  32. Prescribed–time estimation and output regulation of the linearized Schrödinger equation by backstepping. European Journal of Control, 55:3–13, 2020. Finite-time estimation, diagnosis and synchronization of uncertain systems.
  33. R. Vazquez and M. Krstic. A closed-form observer for the channel flow Navier-Stokes system. In Proceedings of the 44th IEEE Conference on Decision and Control, pages 5959–5964, 2005.
  34. R. Vazquez and M. Krstic. Boundary observer for output-feedback stabilization of thermal-fluid convection loop. IEEE Transactions on Control Systems Technology, 18(4):789–797, 2010.
  35. Backstepping boundary stabilization and state estimation of a 2 × 2 linear hyperbolic system. In 2011 50th IEEE Conference on Decision and Control and European Control Conference, pages 4937–4942, 2011.
  36. A closed-form observer for the 3D inductionless MHD and Navier-Stokes channel flow. In Proceedings of the 45th IEEE Conference on Decision and Control, pages 739–746, 2006.
  37. Magnetohydrodynamic state estimation with boundary sensors. Automatica, 44(10):2517–2527, 2008.
  38. An optimization based moving horizon estimation with application to localization of autonomous underwater vehicles. Robotics and Autonomous Systems, 62(10):1581–1596, 2014.
  39. Moving horizon estimation for networked time-delay systems under round-robin protocol. IEEE Transactions on Automatic Control, 64(12):5191–5198, 2019.
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