In comparison with individual testing, group testing (also known as pooled testing) is more efficient in reducing the number of tests and potentially leading to tremendous cost reduction. As indicated in the recent article posted on the US FDA website, the group testing approach for COVID-19 has received a lot of interest lately. There are two key elements in a group testing technique: (i) the pooling matrix that directs samples to be pooled into groups, and (ii) the decoding algorithm that uses the group test results to reconstruct the status of each sample. In this paper, we propose a new family of pooling matrices from packing the pencil of lines (PPoL) in a finite projective plane. We compare their performance with various pooling matrices proposed in the literature, including 2D-pooling, P-BEST, and Tapestry, using the two-stage definite defectives (DD) decoding algorithm. By conducting extensive simulations for a range of prevalence rates up to 5%, our numerical results show that there is no pooling matrix with the lowest relative cost in the whole range of the prevalence rates. To optimize the performance, one should choose the right pooling matrix, depending on the prevalence rate. The family of PPoL matrices can dynamically adjust their column weights according to the prevalence rates and could be a better alternative than using a fixed pooling matrix.
翻译:与个人测试相比,群体测试(也称为集合测试)在减少测试数量方面效率更高,并有可能导致巨大的成本削减。正如美国林业发展局网站最近刊登的文章所示,对COVID-19的团体测试方法最近引起了很大的兴趣。在集体测试技术中,有两个关键要素:(一) 将样本集中成一组的集合矩阵,以及(二) 使用群体测试结果来重建每个样本状况的组测试结果的解码算法。在本文件中,我们建议从一个有限的投影平面中包装线铅笔(PPOL)的集合矩阵进行新的组合。我们应将其性能与文献中提议的各种集合矩阵进行比较,包括2D集合、P-BEST和Tapestry。使用两阶段明确的缺陷解码算法进行广泛的模拟,将流行率范围扩大到5%以下。我们的数字结果显示,整个流行率范围内没有具有最低相对成本的集合矩阵。为了优化性能,我们应选择正确的组合矩阵,根据动态基质率调整一个比动态基质的基质。