An Improved Adaptive Algorithm for Competitive Group Testing

In many fault-detection problems, its objective lies in discerning all the defective items from a set of $n$ items with a binary characteristic by utilizing the minimum number of tests. Group testing (i.e., testing a subset of items with a single test) plays a pivotal role in classifying a large population of items. We study a central problem in the combinatorial group testing model for the situation where the number $d$ of defectives is unknown in advance. Let $M(d,n)=\min_{\alpha}M_\alpha(d|n)$, where $M_\alpha(d|n)$ is the maximum number of tests required by an algorithm $\alpha$ for the problem. An algorithm $\alpha$ is called a $c$\emph{-competitive algorithm} if there exist constants $c$ and $a$ such that for $0\le d < n$, $M_{\alpha}(d|n)\le cM(d,n)+a$. We design a new adaptive algorithm with competitive constant $c \le 1.431$, thus pushing the competitive ratio below the best-known one of $1.452$. The new algorithm is a novel solution framework based on a strongly competitive algorithm and an up-zig-zag strategy that has not yet been investigated.