TY - JOUR
T1 - Error Estimates for Sparse Optimal Control Problems by Piecewise Linear Finite Element Approximation
AU - Song , Xiaoliang
AU - Chen , Bo
AU - Yu , Bo
JO - Journal of Computational Mathematics
VL - 3
SP - 471
EP - 492
PY - 2021
DA - 2021/04
SN - 39
DO - http://doi.org/10.4208/jcm.2003-m2017-0213
UR - https://global-sci.org/intro/article_detail/jcm/18748.html
KW - Finite element method, ABCD method, Approximate discretization, Error
estimates.
AB - <p style="text-align: justify;">Optimization problems with $L^1$-control cost functional subject to an elliptic partial
differential equation (PDE) are considered. However, different from the finite dimensional $l^1$-regularization optimization, the resulting discretized $L^1$-norm does not have a decoupled form when the standard piecewise linear finite element is employed to discretize the
continuous problem. A common approach to overcome this difficulty is employing a nodal
quadrature formula to approximately discretize the $L^1$-norm. In this paper, a new discretized scheme for the $L^1$-norm is presented. Compared to the new discretized scheme for
$L^1$-norm with the nodal quadrature formula, the advantages of our new discretized scheme
can be demonstrated in terms of the order of approximation. Moreover, finite element
error estimates results for the primal problem with the new discretized scheme for the
$L^1$-norm are provided, which confirms that this approximation scheme will not change the
order of error estimates. To solve the new discretized problem, a symmetric Gauss-Seidel
based majorized accelerated block coordinate descent (sGS-mABCD) method is introduced
to solve it via its dual. The proposed sGS-mABCD algorithm is illustrated at two numerical examples. Numerical results not only confirm the finite element error estimates, but
also show that our proposed algorithm is efficient.</p>