Analysis of the magnetization control problem for the 2D evolutionary Landau-Lifshitz-Gilbert equation
Abstract
The magnetization control problem for the Landau-Lifshitz-Gilbert (LLG) equation mt= m × ( m +u)- m × (m × ( m +u)),\ (x,t) ∈ × (0,T] with zero Neumann boundary data on a two-dimensional bounded domain is studied when the control energy u is applied on the effective field. First, we show the existence of a weak solution, and the magnetization vector field m satisfies an energy inequality. If a weak solution m obeys the condition that ∇ m∈ L4(0,T;L4()), then we show that it is a regular solution. The classical cost functional is modified by incorporating L4(0,T;L4())-norm of ∇ m so that a rigorous study of the optimal control problem is established. Then, we justified the existence of an optimal control and derived first-order necessary optimality conditions using an adjoint problem approach. We have established the continuous dependency and Fr\'echet differentiability of the control-to-state and control-to-costate operators and shown the Lipschitz continuity of their Fr\'echet derivatives. Using these postulates, we derived a local second-order sufficient optimality condition when a control belongs to a critical cone. Finally, we also obtain another remarkable global optimality condition posed only in terms of the adjoint state associated with the control problem.
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