Localization of sources in weakly nonlinear fluid systems using linear and quadratic sensitivity analysis

TL;DR

This paper introduces a novel quadratic sensitivity analysis framework for localizing sources in nonlinear fluid systems, improving accuracy over traditional linear methods.

Contribution

It develops a quadratic positional embedding approach that enhances source localization by capturing weak nonlinear effects without iterative procedures.

Findings

Quadratic embeddings significantly improve localization accuracy.

The method effectively detects sources where linear sensitivity vanishes.

Demonstrations include Burgers equation and heat-source problems.

Abstract

We develop a framework for localized source detection in dynamical systems governed by nonlinear partial differential equations based on first and second-order sensitivity analysis. Building on the standard adjoint formulation, which relates multiple measurements to external sources through a linear duality relation, we first introduce a linear positional embedding that identifies the source location by aligning the measurement vector with the embedding. To capture weakly nonlinear effects that arise when the source intensity is finite, we then incorporate a quadratic correction represented as a symmetric bilinear operator and approximated via a truncated eigen-expansion obtained with Krylov subspace iterations. This yields quadratic positional embeddings that augment the linear adjoint field, enabling measurement data to be projected onto a higher-dimensional hyperplane, spanned by the linear and quadratic embeddings. A source search algorithm is formulated based on principal angle minimization between this hyperplane and the observation vector, providing a natural probabilistic interpretation of source location. The method operates in a one-shot fashion without iterative updates of candidate source positions, and it can be readily extended to scenarios involving multiple sources. Demonstrations on benchmark inverse problems include perturbation-source identification in the viscous Burgers equation and heat-source detection in a two-dimensional laminar stratified channel. The results with quadratic embeddings show significant improvements in localization accuracy compared with linear adjoint-based sensitivity methods, especially in the region where linear adjoint sensitivity vanishes.