An Efficient DP Algorithm on a Tree-Structure for Finite Horizon Optimal Control Problems

Alla, Alessandro; Falcone, Maurizio; Saluzzi, Luca

doi:10.1137/18m1203900

Cited by 46 publications

(62 citation statements)

References 22 publications

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“…The former dynamics may be observed almost completely, while the latter dynamics can be almost partly as considered in the presented model. Considering several state variables leads to an optimization problem having a huge degree of freedom whose numerical computation encounters the cure of dimensionality unless a sparse and efficient method is employed 97 . Considering both completely observable and partially observable dynamics would pose additional theoretical and technical issues.…”

Section: Discussionmentioning

confidence: 99%

A hybrid stochastic river environmental restoration modeling with discrete and costly observations

Yoshioka

Tsujimura

Hamagami

et al. 2020

Optim Control Appl Methods

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Summary A recent river environmental restoration problem is approached from a standpoint of stochastic control of hybrid regime‐switching diffusion processes with discrete and costly observations. This setting harmonizes with real problems because continuously obtaining environmental and ecological information is difficult, and is often costly. The main problem is to decide when and how much of the sediment should be supplied into a river environment to effectively suppress bloom of benthic algae. The interventions are allowed only at observation times. Finding the optimal river restoration policy ultimately reduces to solving an optimality equation in an unconventional form due to the observation cost and discrete observations. We show its unique solvability and present a connection with degenerate parabolic partial differential equations, with which we can construct an effective algorithm for its approximation. An uncertainty‐averse optimization problem is also considered as an advanced problem. Coefficients and parameter values are identified from experimental and observation results to numerically compute the optimal restoration policy of an existing river environment with and without uncertainty.

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Section: Discussionmentioning

confidence: 99%

A hybrid stochastic river environmental restoration modeling with discrete and costly observations

Yoshioka

Tsujimura

Hamagami

et al. 2020

Optim Control Appl Methods

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“…In the literature there are different techniques to tackle this situation. Related recent works include, polynomial approximation [28], deep neural technique [32], tensor calculus [18], Taylor series expansions [13] and graph-tree structures [5].…”

Section: Introductionmentioning

confidence: 99%

Policy iteration for Hamilton–Jacobi–Bellman equations with control constraints

Kundu

Kunisch

2021

Comput Optim Appl

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Policy iteration is a widely used technique to solve the Hamilton Jacobi Bellman (HJB) equation, which arises from nonlinear optimal feedback control theory. Its convergence analysis has attracted much attention in the unconstrained case. Here we analyze the case with control constraints both for the HJB equations which arise in deterministic and in stochastic control cases. The linear equations in each iteration step are solved by an implicit upwind scheme. Numerical examples are conducted to solve the HJB equation with control constraints and comparisons are shown with the unconstrained cases.

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“…However, the design of numerical methods for the solution of high-dimensional HJ PDEs remains a daunting task. Along this direction, some encouraging results have been obtained over the last years in connection with the use of sparse grids [11,29], causality-free methods [34,22,48], machine learning techniques [40,39], tensor calculus [47], graph-tree structures [3], Taylor series expansions [17], and polynomial approximation [32]. In this latter work, we develop a numerical scheme based on a high-dimensional polynomial ansatz for the value function coupled with a Newton-type (policy iteration) method for the solution of the Galerkin residual equation associated to the HJB equation.…”

Section: Introductionmentioning

confidence: 99%

Robust Feedback Control of Nonlinear PDEs by Numerical Approximation of High-Dimensional Hamilton--Jacobi--Isaacs Equations

Kalise¹,

Kundu²,

Kunisch³

2020

SIAM J. Appl. Dyn. Syst.

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We propose an approach for the synthesis of robust and optimal feedback controllers for nonlinear PDEs. Our approach considers the approximation of infinite-dimensional control systems by a pseudospectral collocation method, leading to high-dimensional nonlinear dynamics. For the reduced-order model, we construct a robust feedback control based on the H∞ control method, which requires the solution of an associated high-dimensional Hamilton-Jacobi-Isaacs nonlinear PDE. The dimensionality of the Isaacs PDE is tackled by means of a separable representation of the control system, and a polynomial approximation ansatz for the corresponding value function. Our method proves to be effective for the robust stabilization of nonlinear dynamics up to dimension d ≈ 12. We assess the robustness and optimality features of our design over a class of nonlinear parabolic PDEs, including nonlinear advection and reaction terms. The proposed design yields a feedback controller achieving optimal stabilization and disturbance rejection properties, along with providing a modelling framework for the robust control of PDEs under parametric uncertainties.

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An Efficient DP Algorithm on a Tree-Structure for Finite Horizon Optimal Control Problems

Cited by 46 publications

References 22 publications

A hybrid stochastic river environmental restoration modeling with discrete and costly observations

A hybrid stochastic river environmental restoration modeling with discrete and costly observations

Policy iteration for Hamilton–Jacobi–Bellman equations with control constraints

Robust Feedback Control of Nonlinear PDEs by Numerical Approximation of High-Dimensional Hamilton--Jacobi--Isaacs Equations

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