Memory-Type Null Controllability of Heat Equations with Delay Effects

TL;DR

This paper investigates the complex problem of controlling heat equations with delay and memory effects, establishing new controllability conditions using advanced mathematical tools and validating them through numerical simulations.

Contribution

It introduces a novel notion of delay and memory-type null controllability for heat equations with delay effects and develops criteria using Carleman estimates and duality arguments.

Findings

Established rank-type controllability conditions for finite-dimensional systems.

Extended controllability results to PDEs with delay and memory terms.

Numerical simulations demonstrate the effectiveness of moving control regions.

Abstract

This article is devoted to the study of null controllability for evolution equations that incorporate both memory and delay effects. The problem is particularly challenging due to the presence of memory integrals and delayed states, which necessitate strengthening the classical controllability requirement to ensure complete rest at the final time. To address this, we adopt the notion of Delay and memory-type null controllability, which demands the vanishing of the state, the accumulated memory term, and the influence of delay at the terminal time. Utilizing duality arguments, we reduce the controllability analysis to proving suitable observability inequalities for the corresponding adjoint system. We begin with finite-dimensional systems and establish rank-type conditions characterizing controllability. These insights are then extended to parabolic partial differential equations with delay and memory terms. By leveraging Carleman estimates and time-dependent control strategies, we derive sufficient conditions under which controllability can be achieved. Numerical simulations validate the theoretical results and illustrate the critical role of moving control regions in neutralizing the effects of memory and delay.