English

An efficient duality-based approach for PDE-constrained sparse optimization

Optimization and Control 2017-08-31 v1

Abstract

In this paper, elliptic optimal control problems involving the L1L^1-control cost (L1L^1-EOCP) is considered. To numerically discretize L1L^1-EOCP, the standard piecewise linear finite element is employed. However, different from the finite dimensional l1l^1-regularization optimization, the resulting discrete L1L^1-norm does not have a decoupled form. A common approach to overcome this difficulty is employing a nodal quadrature formula to approximately discretize the L1L^1-norm. It is clear that this technique will incur an additional error. To avoid the additional error, solving L1L^1-EOCP via its dual, which can be reformulated as a multi-block unconstrained convex composite minimization problem, is considered. Motivated by the success of the accelerated block coordinate descent (ABCD) method for solving large scale convex minimization problems in finite dimensional space, we consider extending this method to L1L^1-EOCP. Hence, an efficient inexact ABCD method is introduced for solving L1L^1-EOCP. The design of this method combines an inexact 2-block majorized ABCD and the recent advances in the inexact symmetric Gauss-Seidel (sGS) technique for solving a multi-block convex composite quadratic programming whose objective contains a nonsmooth term involving only the first block. The proposed algorithm (called sGS-imABCD) is illustrated at two numerical examples. Numerical results not only confirm the finite element error estimates, but also show that our proposed algorithm is more efficient than (a) the ihADMM (inexact heterogeneous alternating direction method of multipliers), (b) the APG (accelerated proximal gradient) method.

Keywords

Cite

@article{arxiv.1708.09094,
  title  = {An efficient duality-based approach for PDE-constrained sparse optimization},
  author = {Xiaoliang Song and Bo Chen and Bo Yu},
  journal= {arXiv preprint arXiv:1708.09094},
  year   = {2017}
}
R2 v1 2026-06-22T21:27:28.828Z