Optimal Non-Adaptive Probabilistic Group Testing in General Sparsity Regimes

Abstract

In this paper, we consider the problem of noiseless non-adaptive probabilistic group testing, in which the goal is high-probability recovery of the defective set. We show that in the case of n items among which k are defective, the smallest possible number of tests equals \ Ck,n k n, n\ up to lower-order asymptotic terms, where Ck,n is a uniformly bounded constant (varying depending on the scaling of k with respect to n) with a simple explicit expression. The algorithmic upper bound follows from a minor adaptation of an existing analysis of the Definite Defectives (DD) algorithm, and the algorithm-independent lower bound builds on existing works for the regimes k n1-(1) and k = (n). In sufficiently sparse regimes (including k = o( n n )), our main result generalizes that of Coja-Oghlan et al. (2020) by avoiding the assumption k n1-(1), whereas in sufficiently dense regimes (including k = ω( n n )), our main result shows that individual testing is asymptotically optimal for any non-zero target success probability, thus strengthening an existing result of Aldridge (2019) in terms of both the error probability and the assumed scaling of k.