Lower bounds for identifying subset members with subset queries
Abstract
An instance of a group testing problem is a set of objects and an unknown subset P of . The task is to determine P by using queries of the type ``does P intersect Q'', where Q is a subset of . This problem occurs in areas such as fault detection, multiaccess communications, optimal search, blood testing and chromosome mapping. Consider the two stage algorithm for solving a group testing problem. In the first stage a predetermined set of queries are asked in parallel and in the second stage, P is determined by testing individual objects. Let n=. Suppose that P is generated by independently adding each x∈ to P with probability p/n. Let q1 (q2) be the number of queries asked in the first (second) stage of this algorithm. We show that if q1=o((n)(n)/(n)), then (q2) = n1-o(1), while there exist algorithms with q1 = O((n)(n)/(n)) and (q2) = o(1). The proof involves a relaxation technique which can be used with arbitrary distributions. The best previously known bound is q1+(q2) = (p(n)). For general group testing algorithms, our results imply that if the average number of queries over the course of nγ (γ>0) independent experiments is O(n1-ε), then with high probability ((n)(n)/(n)) non-singleton subsets are queried. This settles a conjecture of Bill Bruno and David Torney and has important consequences for the use of group testing in screening DNA libraries and other applications where it is more cost effective to use non-adaptive algorithms and/or too expensive to prepare a subset Q for its first test.
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