Principle of minimal nonlocal complementary energy for nonlinear bond-based peridynamic diffusion and the associated optimal design problem

Anton Evgrafov

Abstract

We study an optimal design problem for a system governed by a nonlocal bond-based peridynamic analogue of a p-Laplacian operator [1] and its limit in the case of the vanishing nonlocal horizon. For optimal design problems of systems governed by elliptic PDEs, the dual variational principle (principle of minimal complementary energy) has proven to be an invaluable analytical tool [2]. Inspired by this fact, we study the principle of minimal complementary energy in the nonlocal case. For linear nonlocal diffusion with heterogeneous
material coefficients such an approach has proved to be successful [3, 4], with the main challenge being the need for the proper mathematical tools relating the local, vectorial fluxes with their two-point nonlocal analogues [3]. Generalizing these tools to the nonlinear case turns out to be an interesting challenge [5]. Our results provide an alternative way of rigorously establishing the relation between the nonlocal optimal design problems and their
local counterparts in the vanishing nonlocal horizon limit.

Originalsprog	Engelsk
Publikationsdato	sep. 2024
Status	Udgivet - sep. 2024
Begivenhed	EUROMECH Colloquium 643: Advances in peridynamic material modeling - Istituto Veneto di Scienze, Lettere ed Arti, Venice, Italien Varighed: 25 sep. 2024 → 27 sep. 2024 https://643.euromech.org/

Konference

Konference	EUROMECH Colloquium 643: Advances in peridynamic material modeling
Lokation	Istituto Veneto di Scienze, Lettere ed Arti
Land/Område	Italien
By	Venice
Periode	25/09/2024 → 27/09/2024
Internetadresse	https://643.euromech.org/

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Principle of minimal nonlocal complementary energy for nonlinear bond-based peridynamic diffusion and the associated optimal design problem
Evgrafov, A. (Foredragsholder)
25 sep. 2024
Aktivitet: Foredrag og mundtlige bidrag › Konferenceoplæg

Fil
EUROMECH Colloquium 643: Advances in peridynamic material modeling
Evgrafov, A. (Deltager)
25 sep. 2024 → 27 sep. 2024
Aktivitet: Deltagelse i faglig begivenhed › Organisering af eller deltagelse i konference

1 Tidsskriftartikel

The Nonlocal Kelvin Principle and the Dual Approach to Nonlocal Control in the Conduction Coefficients
Evgrafov, A. & Bellido, J. C., 2 feb. 2024, I: SIAM Journal on Control and Optimization. 62, 1, s. 487-508 22 s.
Publikation: Bidrag til tidsskrift › Tidsskriftartikel › Forskning › peer review

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2 Citationer (Scopus)

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Citationsformater

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title = "Principle of minimal nonlocal complementary energy for nonlinear bond-based peridynamic diffusion and the associated optimal design problem",

abstract = "We study an optimal design problem for a system governed by a nonlocal bond-based peridynamic analogue of a p-Laplacian operator [1] and its limit in the case of the vanishing nonlocal horizon. For optimal design problems of systems governed by elliptic PDEs, the dual variational principle (principle of minimal complementary energy) has proven to be an invaluable analytical tool [2]. Inspired by this fact, we study the principle of minimal complementary energy in the nonlocal case. For linear nonlocal diffusion with heterogeneousmaterial coefficients such an approach has proved to be successful [3, 4], with the main challenge being the need for the proper mathematical tools relating the local, vectorial fluxes with their two-point nonlocal analogues [3]. Generalizing these tools to the nonlinear case turns out to be an interesting challenge [5]. Our results provide an alternative way of rigorously establishing the relation between the nonlocal optimal design problems and theirlocal counterparts in the vanishing nonlocal horizon limit.",

author = "Anton Evgrafov",

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language = "English",

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Principle of minimal nonlocal complementary energy for nonlinear bond-based peridynamic diffusion and the associated optimal design problem. / Evgrafov, Anton.
2024. Abstract fra EUROMECH Colloquium 643: Advances in peridynamic material modeling, Venice, Italien.

Publikation: Konferencebidrag uden forlag/tidsskrift › Konferenceabstrakt til konference › Forskning › peer review

TY - ABST

T1 - Principle of minimal nonlocal complementary energy for nonlinear bond-based peridynamic diffusion and the associated optimal design problem

AU - Evgrafov, Anton

PY - 2024/9

Y1 - 2024/9

N2 - We study an optimal design problem for a system governed by a nonlocal bond-based peridynamic analogue of a p-Laplacian operator [1] and its limit in the case of the vanishing nonlocal horizon. For optimal design problems of systems governed by elliptic PDEs, the dual variational principle (principle of minimal complementary energy) has proven to be an invaluable analytical tool [2]. Inspired by this fact, we study the principle of minimal complementary energy in the nonlocal case. For linear nonlocal diffusion with heterogeneousmaterial coefficients such an approach has proved to be successful [3, 4], with the main challenge being the need for the proper mathematical tools relating the local, vectorial fluxes with their two-point nonlocal analogues [3]. Generalizing these tools to the nonlinear case turns out to be an interesting challenge [5]. Our results provide an alternative way of rigorously establishing the relation between the nonlocal optimal design problems and theirlocal counterparts in the vanishing nonlocal horizon limit.

AB - We study an optimal design problem for a system governed by a nonlocal bond-based peridynamic analogue of a p-Laplacian operator [1] and its limit in the case of the vanishing nonlocal horizon. For optimal design problems of systems governed by elliptic PDEs, the dual variational principle (principle of minimal complementary energy) has proven to be an invaluable analytical tool [2]. Inspired by this fact, we study the principle of minimal complementary energy in the nonlocal case. For linear nonlocal diffusion with heterogeneousmaterial coefficients such an approach has proved to be successful [3, 4], with the main challenge being the need for the proper mathematical tools relating the local, vectorial fluxes with their two-point nonlocal analogues [3]. Generalizing these tools to the nonlinear case turns out to be an interesting challenge [5]. Our results provide an alternative way of rigorously establishing the relation between the nonlocal optimal design problems and theirlocal counterparts in the vanishing nonlocal horizon limit.

M3 - Conference abstract for conference

T2 - EUROMECH Colloquium 643: Advances in peridynamic material modeling

Y2 - 25 September 2024 through 27 September 2024

ER -

Principle of minimal nonlocal complementary energy for nonlinear bond-based peridynamic diffusion and the associated optimal design problem

Abstract

Konference

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AUB Link

Fingeraftryk

Aktiviteter

Principle of minimal nonlocal complementary energy for nonlinear bond-based peridynamic diffusion and the associated optimal design problem

EUROMECH Colloquium 643: Advances in peridynamic material modeling

Publikation

The Nonlocal Kelvin Principle and the Dual Approach to Nonlocal Control in the Conduction Coefficients

Citationsformater