Learning Self-Triggered Controllers With Gaussian Processes

Hashimoto, Kazumune; Yoshimura, Yuichi; Ushio, Toshimitsu

doi:10.1109/tcyb.2020.2980048

Cited by 19 publications

(18 citation statements)

References 39 publications

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“…Similarly to Delimpaltadakis and Mazo [13], we upper-bound the time evolution of the (homogenized) triggering functioñ φ(ξ(t; x), w(t)) along the trajectories of DI ( 19) with a function μ((x, w), t) in analytic form that satisfies (15). For this purpose, first we provide a lemma, similar to the comparison lemma [22] and to [13,Lemma V.2], which shows how to derive upper bounds with linear dynamics of functions evolving along flowpipes of DIs.…”

Section: A Approximations Of Isochronous Manifolds Of Perturbed/uncertain Etc Systemsmentioning

confidence: 99%

“…This has shifted the control community's research focus from periodic to aperiodic sampling techniques, which promish to reduce resource utilization (e.g., bandwidth, processing power, etc.). Arguably, event-based control is the aperiodic scheme that has attracted wider attention, with its two sub-branches being event-triggered control (ETC, e.g., [1]- [5]) and self-triggered control (STC, e.g., [4], [6]- [13]). For an introduction to the topic, the reader is referred to [14].…”

Section: Introductionmentioning

confidence: 99%

“…Finally, Tiberi and Johansson [11] design ETC and STC that guarantee uniform ultimate boundedness for perturbed uncertain systems, whereas Tolic et al [12] employ the small-gain approach to design STC that guarantees L p -stability. Alternative approaches relying on a stochastic framework and learning techniques have also been proposed, see, e.g., [15], [16]. In contrast to the robust approaches listed earlier, they can cope with potentially unbounded disturbances, but they relax the performance guarantees to probabilistic assurances.…”

Section: Introductionmentioning

confidence: 99%

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Region-Based Self-Triggered Control for Perturbed and Uncertain Nonlinear Systems

Delimpaltadakis

Mazo

2021

IEEE Trans. Control Netw. Syst.

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In this work, we derive a region-based selftriggered control (STC) scheme for nonlinear systems with bounded disturbances and model uncertainties. The proposed STC scheme is able to guarantee different performance specifications (e.g., stability, boundedness, etc.), depending on the event-triggered control (ETC) triggering function that is chosen to be emulated. To deal with disturbances and uncertainties, we employ differential inclusions (DIs). By introducing ETC/STC notions in the context of DIs, we extend well-known results on ETC/STC to perturbed uncertain systems. Given these results, and adapting tools from our previous work, we derive inner approximations of isochronous manifolds of perturbed uncertain ETC systems. These approximations dictate a partition of the state space into regions, each of which is associated with a uniform intersampling time. At each sampling time instant, the controller checks which region the measured state belongs to and correspondingly decides the next sampling instant.

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Section: A Approximations Of Isochronous Manifolds Of Perturbed/uncertain Etc Systemsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Region-Based Self-Triggered Control for Perturbed and Uncertain Nonlinear Systems

Delimpaltadakis

Mazo

2021

IEEE Trans. Control Netw. Syst.

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“…The results of designing optimal control policies based on machine learning techniques can be broadly divided into two categories depending on whether models are taken into account when deriving the controllers; see model-free approaches [29,30,31,32] and model-based approaches [22,33,34,35,36,37,38,39,40,41,42,43,44,45]. In particular, our approach is related to the second category, since controllers are designed from the model estimated by the training data.…”

Section: Introductionmentioning

confidence: 99%

“…Optimal control frameworks that incorporate the GP regression were investigated in [42,43,22,34,40,41,44,45]. The authors in [42,43] formulated a chance-constrained MPC in terms of probabilistic reachable sets, and a sparse GP was introduced as an approximation technique to reduce the computational burden of solving the OCP.…”

Section: Introductionmentioning

confidence: 99%

Learning-based Event-triggered MPC with Gaussian processes and terminal constraints

Onoue¹,

Hashimoto²

2021

Preprint

Self Cite

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Event-triggered control strategy is capable of significantly reducing the number of control task executions without sacrificing control performance. In this paper, we propose a novel learning-based approach towards an event-triggered model predictive control (MPC) for nonlinear control systems whose dynamics are unknown apriori. In particular, the optimal control problems (OCPs) are formulated based on predictive states learned by Gaussian process (GP) regression under a terminal constraint constructed by a symbolic abstraction. The event-triggered condition proposed in this paper is derived from the recursive feasibility so that the OCPs are solved only when an error between the predictive and the actual states exceeds a certain threshold.Based on the event-triggered condition, we analyze the stability of the closed-loop system and show that the finite-time convergence to the terminal set is achieved as the uncertainty of the GP model becomes smaller. Moreover, in order to reduce the uncertainty of the GP model and increase efficiency to find the optimal solution, we provide an overall learning-based event-triggered MPC algorithm based on an iterative task. Finally, we demonstrate the proposed approach through a tracking control problem.

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Model‐free self‐triggered control based on deep reinforcement learning for unknown nonlinear systems

Wan

Karimi

Luan

et al. 2022

Intl J Robust & Nonlinear

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This article proposes a joint learning technique for control inputs and triggering intervals of self‐triggered control nonlinear systems with unknown dynamics. First, deep reinforcement learning is introduced to the self‐triggered control system by considering both the control performance and triggering performance in the reward function. Then, the control inputs and triggering intervals are simultaneously learned by the developed deep deterministic policy gradient approach. Under this strategy, not only the desired control performance is guaranteed for unknown nonlinear systems, but also both the computation and communication occupation for the controlled system are decreased without any triggering thresholds. Finally, simulations for the cart‐pole swing‐up system are illustrated to verify the effectiveness of the proposed scheme.

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Learning Self-Triggered Controllers With Gaussian Processes

Cited by 19 publications

References 39 publications

Region-Based Self-Triggered Control for Perturbed and Uncertain Nonlinear Systems

Region-Based Self-Triggered Control for Perturbed and Uncertain Nonlinear Systems

Learning-based Event-triggered MPC with Gaussian processes and terminal constraints

Model‐free self‐triggered control based on deep reinforcement learning for unknown nonlinear systems

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