Point spread function approximation of high rank Hessians with locally supported non-negative integral kernels

TL;DR

This paper introduces a matrix-free point spread function method for approximating high-rank Hessians with locally supported kernels, enabling efficient preconditioning in PDE-constrained inverse problems.

Contribution

The paper presents a novel PSF approximation technique that efficiently constructs hierarchical matrix approximations of high-rank Hessians using impulse responses and interpolation.

Findings

PSF preconditioners significantly reduce PDE solves by 5-10x.

The method effectively approximates high-rank Hessians with few operator applications.

Impulse response locality improves as Hessian rank increases.

Abstract

We present an efficient matrix-free point spread function (PSF) method for approximating operators that have locally supported non-negative integral kernels. The method computes impulse responses at scattered points, and interpolates these impulse responses to approximate integral kernel entries. Impulse responses are computed by applying the operator to Dirac comb batches of point sources, which are chosen via an ellipsoid packing procedure. Evaluation of kernel entries allows us to construct a hierarchical matrix approximation of the operator, which is used for further matrix computations. We illustrate the end-to-end method on a blur problem, then use the method to build preconditioners for the Hessian in two inverse problems governed by partial differential equations (PDEs): inversion for the basal friction coefficient in an ice sheet flow problem and for the initial condition in an advective-diffusive transport problem. While for many ill-posed inverse problems the Hessian of the data misfit term exhibits a low rank structure, and hence a low rank approximation is suitable, for many problems of practical interest the numerical rank of the Hessian is still large. But Hessian impulse responses typically become more local as the numerical rank increases, which benefits the PSF method. Numerical results reveal that the PSF preconditioner clusters the spectrum of the preconditioned Hessian near one, yielding roughly 5x-10x reductions in the required number of PDE solves, as compared to regularization preconditioning and no preconditioning. We also present a numerical study for the influence of various parameters (that control the shape of the impulse responses) on the effectiveness of the advection-diffusion Hessian approximation. The results show that the PSF-based preconditioners are able to form good approximations of high-rank Hessians using a small number of operator applications.