Sparsity and p-Restricted Isometry

Abstract

A matrix A is said to have the p-Restricted Isometry Property (p-RIP) if for all vectors x of up to some sparsity k, \|Ax\|p is roughly proportional to \|x\|p. We study this property for m × n matrices of rank proportional to n and k = (n). In this parameter regime, p-RIP matrices are closely connected to Euclidean sections, and are "real analogs" of testing matrices for locally testable codes. It is known that with high probability, random dense m× n matrices (e.g., with i.i.d. 1 entries) are 2-RIP with k ≈ m/ n, and sparse random matrices are p-RIP for p ∈ [1,2) when k, m = (n). However, when m = (n), sparse random matrices are known to not be 2-RIP with high probability. Against this backdrop, we show that sparse matrices cannot be 2-RIP in our parameter regime. On the other hand, for p ≠ 2, we show that every p-RIP matrix must be sparse. Thus, sparsity is incompatible with 2-RIP, but necessary for p-RIP for p ≠ 2. Under a suitable interpretation, our negative result about 2-RIP gives an impossibility result for a certain continuous analog of "c3-LTCs": locally testable codes of constant rate, constant distance and constant locality that were constructed in recent breakthroughs.

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