Numerical aspects of large-time optimal control of Burgers equation

Allahverdi, Navid; Pozo, Alejandro; Zuazua, Enrique

doi:10.1051/m2an/2015076

Cited by 20 publications

(17 citation statements)

References 34 publications

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“…Typical orthogonal expansions are Walsh functions , block‐pulse functions , shifted Legendre polynomials , Chebyshev polynomials , linear Legendre multi‐wavelets and hybrid functions . Recently, some computational methods have been proposed in for the optimal control of Burgers equation. In year 2016, a recursive shooting method was provided by the authors of for solving the optimal control problem (OCP) of linear time‐varying systems with state time‐delay.…”

Section: Introductionmentioning

confidence: 99%

An Efficient Finite Difference Method for The Time‐Delay Optimal Control Problems With Time‐Varying Delay

Jajarmi

Hajipour

2016

Asian Journal of Control

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In this paper, an efficient finite difference method is presented for the solution of time‐delay optimal control problems with time‐varying delay in the state. By using the Pontryagin's maximum principle, the original time‐delay optimal control problem is first transformed into a system of coupled two‐point boundary value problems involving both delay and advance terms. Then the derived system is converted into a system of linear algebraic equations by using a second‐order finite difference formula and a Hermite interpolation polynomial for the first‐order derivatives and delay terms, respectively. The convergence analysis of the proposed approach is provided. The new scheme is also successful for the optimal control of time‐delay systems affected by external persistent disturbances. Numerical examples are included to demonstrate the validity and applicability of the new technique. Some comparative results are included to illustrate the effectiveness of the proposed method.

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Section: Introductionmentioning

confidence: 99%

An Efficient Finite Difference Method for The Time‐Delay Optimal Control Problems With Time‐Varying Delay

Jajarmi

Hajipour

2016

Asian Journal of Control

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“…Here, the present result amounts to characterizing the terminal cost corresponding to given initial cost, see [16,Section 10.3] for further connections to optimal control problems. The present analytic results can also help in numerical investigations such as those in [2,10,26,27]. Sections 2 to 5 collect the analytic results, while all proofs are deferred to sections 6 to 9…”

Section: Introductionmentioning

confidence: 89%

Initial data identification in conservation laws and Hamilton–Jacobi equations

Colombo

Perrollaz

2020

Journal de Mathématiques Pures et Appliquées

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In the scalar 1D case, conservation laws and Hamilton-Jacobi equations are deeply related. For both, we characterize those profiles that can be attained as solutions at a given positive time corresponding to at least one initial datum. Then, for each of the two equations, we precisely identify all those initial data yielding a solution that coincide with a given profile at that positive time. Various topological and geometrical properties of the set of these initial data are then proved.2000 Mathematics Subject Classification: 35L65, 35F21, 93B30, 35R30.

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“…we introduce the mappings 1, ,i = index 1 ( , i) = + i(N + 1), 2, ,i = index 2 ( , i) = + 2i(N + 1), 3, ,i = ⌊ 1, ,i ∕(N + 1) ⌋ , 4, ,i = 1, ,i + 3, ,i , ∀i, . We also denote ,i by Ψ N+j+1,i , ∀i, j and define Ω ,i = {Ω 1, ,i , = 0, … , N,…”

Section: B3 Full Gg Discretizationmentioning

confidence: 99%

“…This forms an ill-posed backward problem that requires a highly proper discretization scheme in the numerical approximation of the equation to obtain an accurate approximation of the OCP. 3 (iv) The problem of variational data assimilation for a nonlinear evolution model can be formulated as an OCP governed by Burgers' equation, thus providing a means to develop a diagnostics to check Gauss-verifiability of the optimal solution. 4 Moreover, OCPs of viscous Burgers' equation were recently investigated, both theoretically and numerically, by many authors.…”

Section: Introductionmentioning

confidence: 99%

Distributed optimal control of viscous Burgers' equation via a high‐order, linearization, integral, nodal discontinuous Gegenbauer‐Galerkin method

Elgindy

Karasözen

2019

Optim Control Appl Methods

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We developed a novel direct optimization method to solve distributed optimal control of viscous Burgers' equation over a finite-time horizon by minimizing the distance between the state function and a desired target state profile along with the energy of the control. Through a novel linearization strategy, well-conditioned integral reformulations, optimal Gegenbauer barycentric quadratures, and nodal discontinuous Galerkin discretizations, the method reduces such optimal control problems into finite-dimensional, nonlinear programming problems subject to linear algebraic system of equations and discrete mixed path inequality constraints that can be solved easily using standard optimization software. The proposed method produces "an auxiliary control function" that provides a useful model to explicitly define the optimal controller of the state variable. We present an error analysis of the semidiscretization and full discretization of the weak form of the reduced equality constraint system equations to demonstrate the exponential convergence of the method. The accuracy of the proposed method is examined using two numerical examples for various target state functions in the existence/absence of control bounds. The proposed method is exponentially convergent in both space and time, thus producing highly accurate approximations using a significantly small number of collocation points. 254ELGINDY AND KARASÖZEN many OC applications, and this crucial objective becomes considerably more challenging when the dynamics is described by nonlinear partial differential equations so that the need for developing novel, highly accurate, and efficient techniques is evident. 2 Since the past two decades, OC problems (OCPs) of Burgers' equation has become one of the active topics in applied mathematics occurring in fluid mechanics, nonlinear acoustics, gas dynamics, traffic flow, heat conduction, elasticity, some probabilistic models, etc. Much interest have been developed toward the analysis of such problems for many reasons, among them: (i) to impose the OC on the many phenomena described by Burgers' equation such as the modeling of gas dynamics, traffic flow, wave processes in acoustics and hydrodynamics, etc. (ii) Such a problem is considered a first step toward developing methods for intricate flow control such as the Navier-Stokes equation that is hard to deal with. (iii) The need to analyze the inverse design of Burgers' equation in long time horizons. In particular, given a final desired target, the goal is to identify the initial datum that leads to it, along the Burgers' dynamics. This forms an ill-posed backward problem that requires a highly proper discretization scheme in the numerical approximation of the equation to obtain an accurate approximation of the OCP. 3 (iv) The problem of variational data assimilation for a nonlinear evolution model can be formulated as an OCP governed by Burgers' equation, thus providing a means to develop a diagnostics to check Gauss-verifiability of the optimal solution. 4 Moreover, OCPs of...

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Numerical aspects of large-time optimal control of Burgers equation

Cited by 20 publications

References 34 publications

An Efficient Finite Difference Method for The Time‐Delay Optimal Control Problems With Time‐Varying Delay

An Efficient Finite Difference Method for The Time‐Delay Optimal Control Problems With Time‐Varying Delay

Initial data identification in conservation laws and Hamilton–Jacobi equations

Distributed optimal control of viscous Burgers' equation via a high‐order, linearization, integral, nodal discontinuous Gegenbauer‐Galerkin method

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