Feedback Stabilization and Tracking for Heat Equations Using Thermo-Plasmonic Nanoparticles as Actuators

TL;DR

This paper develops a feedback control method to precisely track heat profiles in a domain using plasmonic nanoparticles as actuators, based on a thermo-plasmonic Maxwell-heat model and a novel mathematical stabilization approach.

Contribution

It introduces a new feedback strategy for heat profile tracking using point actuators derived from a thermo-plasmonic model, with proven exponential stabilization and explicit error bounds.

Findings

Proves exponential stabilization of the heat tracking error.

Designs a feedback control with explicit bounds on residual mismatch.

Extends the method to non-equilibrium profiles with steady matching.

Abstract

We propose a feedback strategy to track prescribed heat profiles using plasmonic nanoparticles as actuators. Starting from a thermo--plasmonic Maxwell--heat model, we use a time-domain discrete effective description in which the generated heat is approximated by a superposition of heat kernels centered at particle locations with amplitudes governed by a coupled Volterra system. We recast this dynamics as a heat equation on a bounded domain with finitely many point actuators and design a tracking feedback based on pointwise evaluations of $\mathcal A^{-1}y$, where $\mathcal A=I-A_0$ and $A_0$ is the Neumann diffusion operator. Working in the natural $V'$ setting with $V=D(\mathcal A)$, we prove exponential stabilization of the tracking error via distribution-actuator theory. For non-equilibrium reference profiles, we add a constant feedforward term and a low-mode fixed-point pre-compensation on $X_N$, ensuring exact steady matching on $X_N$ and an explicit bound on the residual tail mismatch.