First-order least-squares method for the obstacle problem

Abstract: We define and analyse a least-squares finite element method for a first-order reformulation of the obstacle problem. Moreover, we derive variational inequalities that are based on similar but non-symmetric bilinear forms. A priori error estimates including the case of non-conforming convex sets are given and optimal convergence rates are shown for the lowest-order case. We provide also a posteriori bounds that can be be used as error indicators in an adaptive algorithm. Numerical studies are presented.Date: Oc… Show more

“…7 3.2. Proof of upper bound in (8). Let φ ∈ P 0 (T ) and let φ E ∈ X E be arbitrary such that φ = E∈E φ E .…”

“…A second motivation is the approximation of obstacle problems by least-squares finite elements. In [8], a first-order reformulation with Lagrangian multiplier λ was analyzed. The functional to be minimized there, includes a residual term measured in the L 2 (Ω) norm.…”

Optimal Quasi-diagonal Preconditioners for Pseudodifferential Operators of Order Minus Two

“…7 3.2. Proof of upper bound in (8). Let φ ∈ P 0 (T ) and let φ E ∈ X E be arbitrary such that φ = E∈E φ E .…”

“…A second motivation is the approximation of obstacle problems by least-squares finite elements. In [8], a first-order reformulation with Lagrangian multiplier λ was analyzed. The functional to be minimized there, includes a residual term measured in the L 2 (Ω) norm.…”

Optimal Quasi-diagonal Preconditioners for Pseudodifferential Operators of Order Minus Two

A Deep Learning Approach for the Obstacle Problem

Review and computational comparison of adaptive least-squares finite element schemes