Online Optimization of Dynamical Systems With Deep Learning Perception

Cothren, Liliaokeawawa; Bianchin, Gianluca; Dall’Anese, Emiliano

doi:10.1109/ojcsys.2022.3205871

Cited by 8 publications

(4 citation statements)

References 57 publications

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“…Remark 1: As discussed above, our setting and hence also the regret bound from Theorem 1 is applicable to different application scenarios considered in the literature. For example, in perception-based control [25], [28], [29], v t is the error from the perception maps, which can be further bounded if, e.g., a residual neural network is used for perception [29]. More specifically, our results are applicable to the setting considered in [28], where a tracking control problem for an LTI system with complex, nonlinear measurements is studied (note that, as a special case, our results also hold for w t ≡ 0).…”

Section: Theoretical Resultsmentioning

confidence: 99%

“…where where the state x t is estimated via perception maps [25], [29], and (iii) pseudo-measurements (as frequently employed in power systems [30], [31]), all of which result in state measurement noise v t . We have the following two standard assumptions on the disturbances and the system.…”

Section: Settingmentioning

confidence: 99%

“…In this work, we propose a framework for robust control of dynamical systems subject to a priori unknown and timevarying cost functions, and state and input constraints that have to be met at each time instance. In particular, we consider disturbances acting on the system as well as measurement noise, which can capture, e.g., model mismatch, exogenous (uncontrollable) inputs to the system, sensor inaccuracies, state estimation error due to the application of an observer or perception-based techniques [25], [28], [29], and pseudomeasurement in the context of power systems [30], [31]. The combination of these types of disturbances with state and input constraints that have to be satisfied at all times has -to the best of the authors' knowledge -not been studied within the OCO framework, with the notable exception of [20].…”

mentioning

confidence: 99%

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Online Convex Optimization for Data-Driven Control of Dynamical Systems

Nonhoff

Müller

2022

IEEE Open J. Control. Syst.

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We propose an algorithm based on online convex optimization for controlling discrete-time linear dynamical systems. The algorithm is data-driven, i.e., does not require a model of the system, and is able to handle a priori unknown and time-varying cost functions. To this end, we make use of a single persistently exciting input-output sequence of the system and results from behavioral systems theory which enable it to handle unknown linear time-invariant systems. Moreover, we consider noisy output feedback instead of full state measurements and allow general economic cost functions. Our analysis of the closed loop reveals that the algorithm is able to achieve sublinear regret, where the measurement noise only adds an additional constant term to the regret upper bound. In order to do so, we derive a data-driven characterization of the steady-state manifold of an unknown system. Moreover, our algorithm is able to asymptotically exactly estimate the measurement noise. The effectiveness and applicational aspects of the proposed method are illustrated by means of a detailed simulation example in thermal control.

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Section: Theoretical Resultsmentioning

confidence: 99%

Section: Settingmentioning

confidence: 99%

mentioning

confidence: 99%

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Online Convex Optimization for Data-Driven Control of Dynamical Systems

Nonhoff

Müller

2022

IEEE Open J. Control. Syst.

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“…In [16], a feedback optimization technique is designed for linear time-invariant systems. The approach is based on gradient flow dynamics augmented with learning methods to estimate the cost function based on infrequent and possibly noisy data.…”

Section: Introductionmentioning

confidence: 99%

Nonconvex Distributed Feedback Optimization for Aggregative Cooperative Robotics

Carnevale¹,

Mimmo²,

Notarstefano³

2023

Preprint

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Distributed aggregative optimization is a recently emerged framework in which the agents of a network want to minimize the sum of local objective functions, each one depending on the agent decision variable (e.g., the local position of a team of robots) and an aggregation of all the agents' variables (e.g., the team barycentre). In this paper, we address a distributed feedback optimization framework in which agents implement a local (distributed) policy to reach a steady-state minimizing an aggregative cost function. We propose AGGREGATIVE TRACKING FEEDBACK, i.e., a novel distributed feedback optimization law in which each agent combines a closed-loop gradient flow with a consensus-based dynamic compensator reconstructing the missing global information. By using tools from system theory, we prove that AGGREGATIVE TRACKING FEEDBACK steers the network to a stationary point of an aggregative optimization problem with (possibly) nonconvex objective function. The effectiveness of the proposed method is validated through numerical simulations on a multi-robot surveillance scenario. This research was partially supported by the projects OPT4SMART n. 638992 funded by the European Research Council and "Distributed Optimization for Cooperative Machine Learning in Complex Networks" n. PGR10067 funded by Ministero degli Affari Esteri e della Cooperazione Internazionale.

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