scholarly journals A Recovery Algorithm and Pooling Designs for One-Stage Noisy Group Testing Under the Probabilistic Framework

2021 ◽  
pp. 42-53
Author(s):  
Yining Liu ◽  
Sachin Kadyan ◽  
Itsik Pe’er
Keyword(s):  
Group Testing ◽  
Probabilistic Framework ◽  
Pooling Designs ◽  
Recovery Algorithm ◽  
One Stage

scholarly journals A Recovery Algorithm and Pooling Designs for One-Stage Noisy Group Testing under the Probabilistic Framework

2021 ◽  
Author(s):  
Yining Liu ◽  
Sachin Kadyan ◽  
Itsik Pe’er
Keyword(s):  
Practical Problem ◽  
Group Testing ◽  
High Light ◽  
Combinatorial Structure ◽  
Probabilistic Framework ◽  
Pooling Designs ◽  
Recovery Algorithm ◽  
One Stage ◽  
Testing Protocol ◽  
Practical Challenge

AbstractGroup testing saves time and resources by testing each pre-assigned group instead of each individual, and one-stage group testing emerged as essential for cost-effectively controlling the current COVID-19 pandemic. Yet, the practical challenge of adjusting pooling designs based on infection rate has not been systematically addressed. In particular, there are both theoretical interests and practical motivation to analyze one-stage group testing at finite, practical problem sizes, rather than asymptotic ones, under noisy, rather than perfect tests, and when the number of positives is randomly distributed, rather than fixed.Here, we study noisy group testing under the probabilistic framework by modeling the infection vector as a random vector with Bernoulli entries. Our main contributions include a practical one-stage group testing protocol guided by maximizing pool entropy and a maximum-likelihood recovery algorithm under the probabilistic framework. Our findings high-light the implications of introducing randomness to the infection vectors – we find that the combinatorial structure of the pooling designs plays a less important role than the parameters such as pool size and redundancy.

Asymptotics of pooling design performance

1999 ◽  
Vol 36 (04) ◽  
pp. 951-964
Author(s):  
J. K. Percus ◽  
O. E. Percus ◽  
W. J. Bruno ◽  
D. C. Torney
Keyword(s):  
Group Testing ◽  
Performance Criterion ◽  
Expected Number ◽  
Pooling Design ◽  
Pooling Designs ◽  
Parametric Control ◽  
Expected Performance ◽  
Qualitative Effect ◽  
Pooling Strategy ◽  
Asymptotic Forms

We analyse the expected performance of various group testing, or pooling, designs. The context is that of identifying characterized clones in a large collection of clones. Here we choose as performance criterion the expected number of unresolved ‘negative’ clones, and we aim to minimize this quantity. Technically, long inclusion–exclusion summations are encountered which, aside from being computationally demanding, give little inkling of the qualitative effect of parametric control on the pooling strategy. We show that readily-interpreted re-summation can be performed, leading to asymptotic forms and systematic corrections. We apply our results to randomized designs, illustrating how they might be implemented for approximating combinatorial formulae.

Asymptotics of pooling design performance

1999 ◽  
Vol 36 (4) ◽  
pp. 951-964 ◽  
Author(s):  
J. K. Percus ◽  
O. E. Percus ◽  
W. J. Bruno ◽  
D. C. Torney
Keyword(s):  
Group Testing ◽  
Performance Criterion ◽  
Expected Number ◽  
Pooling Design ◽  
Pooling Designs ◽  
Parametric Control ◽  
Expected Performance ◽  
Qualitative Effect ◽  
Pooling Strategy ◽  
Asymptotic Forms

We analyse the expected performance of various group testing, or pooling, designs. The context is that of identifying characterized clones in a large collection of clones. Here we choose as performance criterion the expected number of unresolved ‘negative’ clones, and we aim to minimize this quantity. Technically, long inclusion–exclusion summations are encountered which, aside from being computationally demanding, give little inkling of the qualitative effect of parametric control on the pooling strategy. We show that readily-interpreted re-summation can be performed, leading to asymptotic forms and systematic corrections. We apply our results to randomized designs, illustrating how they might be implemented for approximating combinatorial formulae.

A Group Testing-Based Distributed Network Traffic Monitoring Approach for Smart Grid

2013 ◽  
Vol 791-793 ◽  
pp. 892-896
Author(s):  
Hong Hao Zhao ◽  
Fan Bo Meng ◽  
Qing Qi Zhao ◽  
Wei Zhe Ma ◽  
Zhi Chao Lin ◽  
...  
Keyword(s):  
Communication Network ◽  
Smart Grid ◽  
Network Traffic ◽  
Group Testing ◽  
Traffic Monitoring ◽  
Network Data ◽  
Distributed Network ◽  
Recovery Algorithm ◽  
Network Traffic Monitoring ◽  
Real Network Data

In this paper, we address the problem of real-time network traffic monitoring in the communication network of smart grid. And we propose an effective distributed network traffic monitoring approach. In our algorithm, instead of measuring all the origin-destination pairs, we just need to measure partial origin-destination pairs that flows our communication network. From the measured origin-destination pairs, we can obtain all the origin-destination pairs via our recovery algorithm. Finally, we validate the properties of our method by real network data.

ERROR-TOLERANT TRIVIAL TWO-STAGE GROUP TESTING FOR COMPLEXES USING ALMOST SEPARABLE AND ALMOST DISJUNCT MATRICES

2009 ◽  
Vol 01 (02) ◽  
pp. 235-251 ◽  
Author(s):  
WEIWEI LANG ◽  
YUEXUAN WANG ◽  
JAMES YU ◽  
SUOGANG GAO ◽  
WEILI WU
Keyword(s):  
Fault Tolerant ◽  
Group Testing ◽  
Pooling Designs ◽  
Two Stage ◽  
Disjunct Matrix ◽  
Expected Values ◽  
Disjunct Matrices ◽  
Separable Matrix ◽  
The Given

In this paper, we define an α-almost (k; 2e + 1)-separable matrix and an α-almostke-disjunct matrix. Using their complements, we devise algorithms for fault-tolerant trivial two-stage group tests (pooling designs) for k-complexes. We derive the expected values for the given algorithms to identify all such positive complexes.

scholarly journals Using viral load and epidemic dynamics to optimize pooled testing in resource-constrained settings

2021 ◽  
Vol 13 (589) ◽  
pp. eabf1568 ◽  
Author(s):  
Brian Cleary ◽  
James A. Hay ◽  
Brendan Blumenstiel ◽  
Maegan Harden ◽  
Michelle Cipicchio ◽  
...  
Keyword(s):  
Time Course ◽  
Resource Constraints ◽  
Group Testing ◽  
Individual Identification ◽  
Pooling Designs ◽  
Viral Kinetics ◽  
Viral Loads ◽  
Pooled Testing ◽  
Epidemic Dynamics ◽  
Resource Limited

Virological testing is central to severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) containment, but many settings face severe limitations on testing. Group testing offers a way to increase throughput by testing pools of combined samples; however, most proposed designs have not yet addressed key concerns over sensitivity loss and implementation feasibility. Here, we combined a mathematical model of epidemic spread and empirically derived viral kinetics for SARS-CoV-2 infections to identify pooling designs that are robust to changes in prevalence and to ratify sensitivity losses against the time course of individual infections. We show that prevalence can be accurately estimated across a broad range, from 0.02 to 20%, using only a few dozen pooled tests and using up to 400 times fewer tests than would be needed for individual identification. We then exhaustively evaluated the ability of different pooling designs to maximize the number of detected infections under various resource constraints, finding that simple pooling designs can identify up to 20 times as many true positives as individual testing with a given budget. Crucially, we confirmed that our theoretical results can be translated into practice using pooled human nasopharyngeal specimens by accurately estimating a 1% prevalence among 2304 samples using only 48 tests and through pooled sample identification in a panel of 960 samples. Our results show that accounting for variation in sampled viral loads provides a nuanced picture of how pooling affects sensitivity to detect infections. Using simple, practical group testing designs can vastly increase surveillance capabilities in resource-limited settings.

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