Detection of a Moving Rigid Solid in a Perfect Fluid

TL;DR

This paper investigates the inverse problem of detecting a moving rigid solid in a potential fluid, revealing conditions for uniqueness and methods for tracking the solid's position and velocity using potential measurements.

Contribution

It establishes conditions for the well-posedness of the detection problem, including shape and symmetry considerations, and demonstrates how continuous measurements enable tracking.

Findings

Counterexamples show non-uniqueness in general cases.

Unique detection possible for specific shapes like ellipses.

Continuous potential measurements allow tracking of the solid's position.

Abstract

In this paper, we consider a moving rigid solid immersed in a potential fluid. The fluid-solid system fills the whole two dimensional space and the fluid is assumed to be at rest at infinity. Our aim is to study the inverse problem, initially introduced in [3], that consists in recovering the position and the velocity of the solid assuming that the potential function is known at a given time. We show that this problem is in general ill-posed by providing counterexamples for which the same potential corresponds to different positions and velocities of a same solid. However, it is also possible to find solids having a specific shape, like ellipses for instance, for which the problem of detection admits a unique solution. Using complex analysis, we prove that the well-posedness of the inverse problem is equivalent to the solvability of an infinite set of nonlinear equations. This result allows us to show that when the solid enjoys some symmetry properties, it can be partially detected. Besides, for any solid, the velocity can always be recovered when both the potential function and the position are supposed to be known. Finally, we prove that by performing continuous measurements of the fluid potential over a time interval, we can always track the position of the solid.