English

Universal Scalable Robust Solvers from Computational Information Games and fast eigenspace adapted Multiresolution Analysis

Numerical Analysis 2017-05-31 v2 Analysis of PDEs Machine Learning

Abstract

We show how the discovery of robust scalable numerical solvers for arbitrary bounded linear operators can be automated as a Game Theory problem by reformulating the process of computing with partial information and limited resources as that of playing underlying hierarchies of adversarial information games. When the solution space is a Banach space BB endowed with a quadratic norm \|\cdot\|, the optimal measure (mixed strategy) for such games (e.g. the adversarial recovery of uBu\in B, given partial measurements [ϕi,u][\phi_i, u] with ϕiB\phi_i\in B^*, using relative error in \|\cdot\|-norm as a loss) is a centered Gaussian field ξ\xi solely determined by the norm \|\cdot\|, whose conditioning (on measurements) produces optimal bets. When measurements are hierarchical, the process of conditioning this Gaussian field produces a hierarchy of elementary bets (gamblets). These gamblets generalize the notion of Wavelets and Wannier functions in the sense that they are adapted to the norm \|\cdot\| and induce a multi-resolution decomposition of BB that is adapted to the eigensubspaces of the operator defining the norm \|\cdot\|. When the operator is localized, we show that the resulting gamblets are localized both in space and frequency and introduce the Fast Gamblet Transform (FGT) with rigorous accuracy and (near-linear) complexity estimates. As the FFT can be used to solve and diagonalize arbitrary PDEs with constant coefficients, the FGT can be used to decompose a wide range of continuous linear operators (including arbitrary continuous linear bijections from H0sH^s_0 to HsH^{-s} or to L2L^2) into a sequence of independent linear systems with uniformly bounded condition numbers and leads to O(NpolylogN)\mathcal{O}(N \operatorname{polylog} N) solvers and eigenspace adapted Multiresolution Analysis (resulting in near linear complexity approximation of all eigensubspaces).

Keywords

Cite

@article{arxiv.1703.10761,
  title  = {Universal Scalable Robust Solvers from Computational Information Games and fast eigenspace adapted Multiresolution Analysis},
  author = {Houman Owhadi and Clint Scovel},
  journal= {arXiv preprint arXiv:1703.10761},
  year   = {2017}
}

Comments

142 pages. 14 Figures. Presented at AFOSR (Aug 2016), DARPA (Sep 2016), IPAM (Apr 3, 2017), Hausdorff (April 13, 2017) and ICERM (June 5, 2017)

R2 v1 2026-06-22T19:03:13.173Z