Multiple Planted Structures Below n: An SoS Integrality Gap and an SQ Lower Bound

Abstract

We study computational limitations in multi-plant average-case inference problems, in which t disjoint planted structures of size k are embedded in a random background on n elements. A natural parameter in this setting is the total planted size K := kt. For several classic planted-subgraph problems, including planted clique, existing algorithmic and lower-bound evidence suggests a characteristic computational threshold near n in the single-plant setting. Our main result is a Sum-of-Squares (SoS) integrality gap for refuting the presence of multiple planted cliques. Specifically, for G G(n,1/2), we construct a degree-d SoS pseudoexpectation for the natural relaxation that maximizes the total size of up to t disjoint cliques. Throughout the regime kt n1/2 - cd/ n, for a universal constant c>0, this relaxation achieves objective value kt(1-o(1)), and therefore degree-d SoS cannot certify an upper bound below kt. This extends the planted-clique SoS lower bounds of~BarakHKKMP19 to a multi-plant setting with explicit disjointness constraints. As complementary evidence from a different computational model, we prove a lower bound in the statistical query (SQ) framework, extending the results of~FeldmanGRVX17. We show that for detecting t disjoint planted k × k bicliques (equivalently, a row-mixture distribution), when kt = O(n1/2-δ) for any fixed δ>0, no polynomial-time SQ algorithm can distinguish the planted and null distributions with constant advantage.