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A pointwise characterisation of the PDE system of vectorial calculus of variations in L

Part of: Representations of solutions Elliptic equations and systems

Published online by Cambridge University Press:  01 February 2019

Birzhan Ayanbayev  and
Nikos Katzourakis
Birzhan Ayanbayev
Affiliation:
Department of Mathematics and Statistics, University of Reading, Whiteknights, PO Box 220, ReadingRG6 6AXBerkshire, UK (n.katzourakis@reading.ac.uk; b.ayanbayev@pgr.reading.ac.uk)
Nikos Katzourakis
Affiliation:
Department of Mathematics and Statistics, University of Reading, Whiteknights, PO Box 220, ReadingRG6 6AXBerkshire, UK (n.katzourakis@reading.ac.uk; b.ayanbayev@pgr.reading.ac.uk)
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Abstract

Let n, $N \in {\open N}$ with $\Omega \subseteq {\open R}^n$ open. Given ${\rm H} \in C^2(\Omega \times {\open R}^N \times {\open R}^{Nn})$, we consider the functional 1

$${\rm E}_\infty (u,{\rm {\cal O}})\, : = \, \mathop {{\rm ess}\,\sup}\limits_{\rm {\cal O}} {\rm H}(\cdot, u,{\rm D}u),\quad u\in W_{{\rm loc}}^{1,\infty} (\Omega, {\open R}^N),\quad {\rm {\cal O}}{\Subset}\Omega.$$
The associated PDE system which plays the role of Euler–Lagrange equations in $L^\infty $ is 2
$$\left\{\matrix{{\rm H}_{P}(\cdot, u, {\rm D}u)\, {\rm D}\left({\rm H}(\cdot, u, {\rm D} u)\right) = \, 0, \hfill \cr {\rm H}(\cdot, u, {\rm D} u) \, [\![{\rm H}_{P}(\cdot, u, {\rm D} u)]\!]^\bot \left({\rm Div}\left({\rm H}_{P}(\cdot, u, {\rm D} u)\right)- {\rm H}_{\eta}(\cdot, u, {\rm D} u)\right) = 0,\hfill}\right.$$
 where $[\![A]\!]^\bot := {\rm Proj}_{R(A)^\bot }$. Herein we establish that generalised solutions to (2) can be characterised as local minimisers of (1) for appropriate classes of affine variations of the energy. Generalised solutions to (2) are understood as ${\cal D}$-solutions, a general framework recently introduced by one of the authors.

Keywords

∞-Laplaciangeneralised solutionscalculus of variations in L∞young measuresfully non-linear systems35J47

MSC classification

Primary: 35D99: None of the above, but in this section
Secondary: 35D40: Viscosity solutions 35J47: Second-order elliptic systems 35J92: Quasilinear elliptic equations with $p$-Laplacian 35J70: Degenerate elliptic equations 35J99: None of the above, but in this section
Type
Research Article
Information
Proceedings of the Royal Society of Edinburgh Section A: Mathematics , Volume 150 , Issue 4 , August 2020 , pp. 1653 - 1669
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Copyright
Copyright © Royal Society of Edinburgh 2019

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