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A multi-level ADMM algorithm for elliptic PDE-constrained optimization problems

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arxiv 1908.04652 v1 pith:HU4WVTDC submitted 2019-08-13 math.OC

A multi-level ADMM algorithm for elliptic PDE-constrained optimization problems

classification math.OC
keywords algorithmadmmiterationmulti-leveloptimizationpde-constrainedstrategysubproblems
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In this paper, the elliptic PDE-constrained optimization problem with box constraints on the control is studied. To numerically solve the problem, we apply the 'optimize-discretize-optimize' strategy. Specifically, the alternating direction method of multipliers (ADMM) algorithm is applied in function space first, then the standard piecewise linear finite element approach is employed to discretize the subproblems in each iteration. Finally, some efficient numerical methods are applied to solve the discretized subproblems based on their structures. Motivated by the idea of the multi-level strategy, instead of fixing the mesh size before the computation process, we propose the strategy of gradually refining the grid. Moreover, the subproblems in each iteration are solved inexactly. Based on the strategies above, an efficient convergent multi-level ADMM (mADMM) algorithm is proposed. We present the convergence analysis and the iteration complexity results o(1/k) of the proposed algorithm for the PDE-constrained optimization problems. Numerical results show the high efficiency of the mADMM algorithm.

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