Semirandom Planted Clique via 1-norm Isometry Property

Abstract

We give a polynomial-time algorithm that finds a planted clique of size k n n in the semirandom model, improving the state-of-the-art n ( n)2 bound. This semirandom planted clique problem concerns finding the planted subset S of k vertices of a graph G on V, where the induced subgraph G[S] is complete, the cut edges in G[S; V S] are random, and the remaining edges in G[V S] are adversarial. An elegant greedy algorithm by Blasiok, Buhai, Kothari, and Steurer [BBK24] finds S by sampling inner products of the columns of the adjacency matrix of G, and checking if they deviate significantly from typical inner products of random vectors. Their analysis uses a suitably random matrix that, with high probability, satisfies a certain restricted isometry property. Inspired by Wootters's work on list decoding, we put forth and implement the 1-norm analog of this argument, and quantitatively improve their analysis to work all the way up to the conjectured optimal n n bound on clique size, answering one of the main open questions posed in [BBK24].