Generalized Group Testing

Abstract

In the problem of classical group testing one aims to identify a small subset (of size d) diseased individuals/defective items in a large population (of size n). This process is based on a minimal number of suitably-designed group tests on subsets of items, where the test outcome is positive iff the given test contains at least one defective item. Motivated by physical considerations, we consider a generalized setting that includes as special cases multiple other group-testing-like models in the literature. In our setting, which subsumes as special cases a variety of noiseless and noisy group-testing models in the literature, the test outcome is positive with probability f(x), where x is the number of defectives tested in a pool, and f(·) is an arbitrary monotonically increasing (stochastic) test function. Our main contributions are as follows. 1. We present a non-adaptive scheme that with probability 1- identifies all defective items. Our scheme requires at most O( H(f) d(n)) tests, where H(f) is a suitably defined "sensitivity parameter" of f(·), and is never larger than O(d1+o(1)), but may be substantially smaller for many f(·). 2. We argue that any non-adaptive group testing scheme needs at least ((1-)h(f) d( n d)) tests to ensure reliable recovery. Here h(f) ≥ 1 is a suitably defined "concentration parameter" of f(·). 3. We prove that H(f)h(f)∈(1) for a variety of sparse-recovery group-testing models in the literature, and H(f) h(f) ∈ O(d1+o(1)) for any other test function.