Sparse Graph Codes for Non-adaptive Quantitative Group Testing

Abstract

This paper considers the problem of Quantitative Group Testing (QGT). Consider a set of N items among which K items are defective. The QGT problem is to identify (all or a sufficiently large fraction of) the defective items, where the result of a test reveals the number of defective items in the tested group. In this work, we propose a non-adaptive QGT algorithm using sparse graph codes over bi-regular bipartite graphs with left-degree and right degree r and binary t-error-correcting BCH codes. The proposed scheme provides exact recovery with probabilistic guarantee, i.e. recovers all the defective items with high probability. In particular, we show that for the sub-linear regime where KN vanishes as K,N→∞, the proposed algorithm requires at most m=c(t)K(t2( Nc(t)K+1)+1)+1 tests to recover all the defective items with probability approaching one as K,N→∞, where c(t) depends only on t. The results of our theoretical analysis reveal that the minimum number of required tests is achieved by t=2. The encoding and decoding of the proposed algorithm for any t≤ 4 have the computational complexity of O(K2 NK) and O(K NK), respectively. Our simulation results also show that the proposed algorithm significantly outperforms a non-adaptive semi-quantitative group testing algorithm recently proposed by Abdalla et al. in terms of the required number of tests for identifying all the defective items with high probability.