English

Approximating Operator Norms via Generalized Krivine Rounding

Data Structures and Algorithms 2019-11-07 v2 Functional Analysis

Abstract

We consider the (p,r)(\ell_p,\ell_r)-Grothendieck problem, which seeks to maximize the bilinear form yTAxy^T A x for an input matrix AA over vectors x,yx,y with xp=yr=1\|x\|_p=\|y\|_r=1. The problem is equivalent to computing the prp \to r^* operator norm of AA. The case p=r=p=r=\infty corresponds to the classical Grothendieck problem. Our main result is an algorithm for arbitrary p,r2p,r \ge 2 with approximation ratio (1+ϵ0)/(sinh1(1)γpγr)(1+\epsilon_0)/(\sinh^{-1}(1)\cdot \gamma_{p^*} \,\gamma_{r^*}) for some fixed ϵ00.00863\epsilon_0 \le 0.00863. Comparing this with Krivine's approximation ratio of (π/2)/sinh1(1)(\pi/2)/\sinh^{-1}(1) for the original Grothendieck problem, our guarantee is off from the best known hardness factor of (γpγr)1(\gamma_{p^*} \gamma_{r^*})^{-1} for the problem by a factor similar to Krivine's defect. Our approximation follows by bounding the value of the natural vector relaxation for the problem which is convex when p,r2p,r \ge 2. We give a generalization of random hyperplane rounding and relate the performance of this rounding to certain hypergeometric functions, which prescribe necessary transformations to the vector solution before the rounding is applied. Unlike Krivine's Rounding where the relevant hypergeometric function was arcsin\arcsin, we have to study a family of hypergeometric functions. The bulk of our technical work then involves methods from complex analysis to gain detailed information about the Taylor series coefficients of the inverses of these hypergeometric functions, which then dictate our approximation factor. Our result also implies improved bounds for "factorization through 2n\ell_{2}^{\,n}" of operators from pn\ell_{p}^{\,n} to qm\ell_{q}^{\,m} (when p2qp\geq 2 \geq q)--- such bounds are of significant interest in functional analysis and our work provides modest supplementary evidence for an intriguing parallel between factorizability, and constant-factor approximability.

Keywords

Cite

@article{arxiv.1804.03644,
  title  = {Approximating Operator Norms via Generalized Krivine Rounding},
  author = {Vijay Bhattiprolu and Mrinalkanti Ghosh and Venkatesan Guruswami and Euiwoong Lee and Madhur Tulsiani},
  journal= {arXiv preprint arXiv:1804.03644},
  year   = {2019}
}
R2 v1 2026-06-23T01:19:38.479Z