Energy Space Newton Differentiability for Solution Maps of Unilateral and Bilateral Obstacle Problems

Abstract

We prove that the solution operator of the classical unilateral obstacle problem on a nonempty open bounded set ⊂ Rd, d ∈ N, is Newton differentiable as a function from Lp() to H01() whenever (1, 2d/(d+2)) < p ≤ ∞. By exploiting this Newton differentiability property, results on angled subspaces in H-1(), and a formula for orthogonal projections onto direct sums, we further show that the solution map of the classical bilateral obstacle problem is Newton differentiable as a function from Lp() to H01() Lq() whenever (1, d/2) < p ≤ ∞ and 1 ≤ q <∞. For both the unilateral and the bilateral case, we provide explicit formulas for the Newton derivative. As a concrete application example for our results, we consider the numerical solution of an optimal control problem with H01()-controls and box-constraints by means of a semismooth Newton method.