STRONG STATIONARITY CONDITIONS FOR OPTIMAL CONTROL PROBLEMS GOVERNED BY A RATE-INDEPENDENT EVOLUTION VARIATIONAL INEQUALITY

Martin Brokate; Constantin Christof

doi:10.1137/22M1494403

STRONG STATIONARITY CONDITIONS FOR OPTIMAL CONTROL PROBLEMS GOVERNED BY A RATE-INDEPENDENT EVOLUTION VARIATIONAL INEQUALITY

Martin Brokate, Constantin Christof

Chair of Numerical Mathematics and Control Theory

Research output: Contribution to journal › Article › peer-review

2 Scopus citations

Abstract

We prove strong stationarity conditions for optimal control problems that are governed by a prototypical rate-independent evolution variational inequality, i.e., first-order necessary optimality conditions in the form of a primal-dual multiplier system that are equivalent to the purely primal notion of Bouligand stationarity. Our analysis relies on recent results on the Hadamard directional differentiability of the scalar stop operator and a new concept of temporal polyhedricity that generalizes classical ideas of Mignot. The established strong stationarity system is compared with known optimality conditions for optimal control problems governed by elliptic obstacle-type variational inequalities and stationarity systems obtained by regularization.

Original language	English
Pages (from-to)	2222-2250
Number of pages	29
Journal	SIAM Journal on Control and Optimization
Volume	61
Issue number	4
DOIs	https://doi.org/10.1137/22M1494403
State	Published - 2023

Keywords

Bouligand stationarity
Kurzweil integral
hysteresis
optimal control
polyhedricity
rate independence
stop operator
strong stationarity
sweeping process
variational inequality

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10.1137/22M1494403

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title = "STRONG STATIONARITY CONDITIONS FOR OPTIMAL CONTROL PROBLEMS GOVERNED BY A RATE-INDEPENDENT EVOLUTION VARIATIONAL INEQUALITY",

abstract = "We prove strong stationarity conditions for optimal control problems that are governed by a prototypical rate-independent evolution variational inequality, i.e., first-order necessary optimality conditions in the form of a primal-dual multiplier system that are equivalent to the purely primal notion of Bouligand stationarity. Our analysis relies on recent results on the Hadamard directional differentiability of the scalar stop operator and a new concept of temporal polyhedricity that generalizes classical ideas of Mignot. The established strong stationarity system is compared with known optimality conditions for optimal control problems governed by elliptic obstacle-type variational inequalities and stationarity systems obtained by regularization.",

keywords = "Bouligand stationarity, Kurzweil integral, hysteresis, optimal control, polyhedricity, rate independence, stop operator, strong stationarity, sweeping process, variational inequality",

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AB - We prove strong stationarity conditions for optimal control problems that are governed by a prototypical rate-independent evolution variational inequality, i.e., first-order necessary optimality conditions in the form of a primal-dual multiplier system that are equivalent to the purely primal notion of Bouligand stationarity. Our analysis relies on recent results on the Hadamard directional differentiability of the scalar stop operator and a new concept of temporal polyhedricity that generalizes classical ideas of Mignot. The established strong stationarity system is compared with known optimality conditions for optimal control problems governed by elliptic obstacle-type variational inequalities and stationarity systems obtained by regularization.

KW - Bouligand stationarity

KW - Kurzweil integral

KW - hysteresis

KW - optimal control

KW - polyhedricity

KW - rate independence

KW - stop operator

KW - strong stationarity

KW - sweeping process

KW - variational inequality

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JO - SIAM Journal on Control and Optimization

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STRONG STATIONARITY CONDITIONS FOR OPTIMAL CONTROL PROBLEMS GOVERNED BY A RATE-INDEPENDENT EVOLUTION VARIATIONAL INEQUALITY

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Keywords

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