A Fast Hierarchical Splitting Approach for Non-Adaptive Learning of Random Hypergraphs

Abstract

This work focuses on the problem of learning an unknown 3-uniform hypergraph using edge-detecting queries. Our goal is to design a querying strategy that recovers the hyperedge set using as few queries as possible. We restrict our attention to random hypergraphs under the Erdos--R\'enyi (ER) model, in which each potential hyperedge appears independently with probability q = (n-3(1-θ)) for θ ∈ (0;1). Prior work [Austhof-Reyzin-Tani, ISIT 2025] presents a testing-decoding scheme that uses O(m n) tests but requires a decoding time of (n3), where m = qn3 denotes the expected number of hyperedges. In this work, we extend the binary splitting framework and adapt it to the 3-uniform hypergraph setting. We obtain a testing-decoding scheme that recovers the hyperedge set with high probability using O(m n) tests and achieves decoding time O(m5/3 n) for the case θ > 23 and O(m5/32m n) for the case θ ≤ 23. Thus, compared with prior work, our result significantly improves the decoding complexity while maintaining optimal query complexity.