Model-free control of dynamical systems with deep reservoir computing

Canaday, Daniel; Pomerance, Andrew; Gauthier, Daniel J.

doi:10.1088/2632-072x/ac24f3

Cited by 31 publications

(16 citation statements)

References 32 publications

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“…For example, the NG-RC can be used to create a digital twin for dynamical systems 33 using only observed data or by combining approximate models with observations for data assimilation 34,35 . It can also be used for nonlinear control of dynamical systems 36 , which can be quickly adjusted to account for changes in the system, or for speeding up the simulation of turbulence 37 . Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons license, and indicate if changes were made.…”

Section: Discussionmentioning

confidence: 99%

Next generation reservoir computing

et al. 2021

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Reservoir computing is a best-in-class machine learning algorithm for processing information generated by dynamical systems using observed time-series data. Importantly, it requires very small training data sets, uses linear optimization, and thus requires minimal computing resources. However, the algorithm uses randomly sampled matrices to define the underlying recurrent neural network and has a multitude of metaparameters that must be optimized. Recent results demonstrate the equivalence of reservoir computing to nonlinear vector autoregression, which requires no random matrices, fewer metaparameters, and provides interpretable results. Here, we demonstrate that nonlinear vector autoregression excels at reservoir computing benchmark tasks and requires even shorter training data sets and training time, heralding the next generation of reservoir computing.

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Section: Discussionmentioning

confidence: 99%

Next generation reservoir computing

et al. 2021

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“…The solid blue curve is the exact complex-P result for Λ/γ = 0.005, while blue dots are obtained by evolving the TEOMs, Eqs. (10), (11a), (11b), to their steady state numerically. For small N , the response follows that of a linear oscillator (dashed black line), but becomes nonlinear with increasing N .…”

Section: B Application To Unconditional Qrc Node Dynamicsmentioning

confidence: 99%

“…Reservoir computing is a machine-learning paradigm that emphasizes learning efficiency [1-4]: a linear combination of the accessible degrees of freedom of a physical 'reservoir' is the only quantity trained for a given task. Crucially, foregoing optimization of internal parameters does not necessarily hinder the computational capacity of reservoir computers, and has in recent years enabled efficient approaches to forecasting [5][6][7], inference [8,9], control [10], and similar resource-intensive signal processing tasks [11][12][13][14][15]. By relaxing control over microscopic parameters of the learning machine, reservoir computing embraces the fundamental notion of computation with very general dynamical systems: physical or artificial dynamical systems stimulated by incoming time-dependent signals u(t) perform computation by transforming an input stream into an output stream, effectively computing a function F{u(t)} [see Fig.…”

Section: Introductionmentioning

confidence: 99%

Physical reservoir computing using finitely-sampled quantum systems

Khan¹,

Hu²,

Angelatos³

et al. 2021

Preprint

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The paradigm of reservoir computing exploits the nonlinear dynamics of a physical reservoir to perform complex time-series processing tasks such as speech recognition and forecasting. Unlike other machine-learning approaches, reservoir computing relaxes the need for optimization of intra-network parameters, and is thus particularly attractive for near-term hardware-efficient quantum implementations. However, the complete description of practical quantum reservoir computers requires accounting for their placement in a quantum measurement chain, and its conditional evolution under measurement. Consequently, training and inference has to be performed using finite samples from obtained measurement records. Here we describe a framework for reservoir computing with nonlinear quantum reservoirs under continuous heterodyne measurement. Using an efficient truncated-cumulants representation of the complete measurement chain enables us to sample stochastic measurement trajectories from reservoirs of several coupled nonlinear bosonic modes under strong excitation. This description also offers a mathematical basis to directly compare the information processing capacity of a given physical reservoir operated across classical and quantum regimes. Applying this framework to the classification of Gaussian states of systems that are part of the same measurement chain as the quantum reservoir computer, we uncover its working principles and provide a detailed analysis of its performance as a function of experimentally-controllable parameters. Our results identify the vicinity of bifurcation points as presenting optimal nonlinear processing regimes of an oscillator-based quantum reservoir. The considered models are directly realizable in modern circuit QED experiments, while the framework is applicable to more general quantum nonlinear reservoirs.

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“…Reservoir computing and its variant echo state Gaussian process [57] were also used in model predictive control of unknown nonlinear dynamical systems [58,59], which served as replacements of the traditional recurrent neural-network models with low computational cost. More recently, deep reservoir networks were proposed for controlling chaotic systems [60].…”

Section: Introductionmentioning

confidence: 99%

Model-free tracking control of complex dynamical trajectories with machine learning

Lai

Kong

Zhai

et al. 2023

Preprint

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Nonlinear tracking control enabling a dynamical system to track a desired trajectory is fundamental to robotics, serving a wide range of civil and defense applications. In control engineering, designing tracking control requires complete knowledge of the system model and equations. We develop a model-free, machine-learning framework to control a two-arm robotic manipulator using only partially observed states, where the controller is realized by reservoir computing. Stochastic input is exploited for training, which consists of the observed partial state vector as the first and its time-delayed copy as the second component so that the neural machine regards the latter as the future state of the former. In the testing (deployment) phase, the time-delayed component is replaced by the desired observational vector from the reference trajectory. We demonstrate the effectiveness of the control framework using a variety of periodic and chaotic signals, and establish its robustness against measurement noise, disturbances, and uncertainties.

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Model-free control of dynamical systems with deep reservoir computing

Cited by 31 publications

References 32 publications

Next generation reservoir computing

Next generation reservoir computing

Physical reservoir computing using finitely-sampled quantum systems

Model-free tracking control of complex dynamical trajectories with machine learning

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