Improved bounds for noisy group testing with constant tests per item

Oliver Gebhard; Oliver T Johnson; Philipp Loick; Maurice Rolvien

doi:10.1109/TIT.2021.3138489

Improved bounds for noisy group testing with constant tests per item

Oliver Gebhard, Oliver T Johnson^*, Philipp Loick, Maurice Rolvien

^*Corresponding author for this work

Research output: Contribution to journal › Article (Academic Journal) › peer-review

7 Citations (Scopus)

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Abstract

The group testing problem is concerned with identifying a small set of infected individuals in a large population. At our disposal is a testing procedure that allows us to test several individuals together. In an idealized setting, a test is positive if and only if at least one infected individual is included and negative otherwise. Significant progress was made in recent years towards understanding the information-theoretic and algorithmic properties in this noiseless setting. In this paper, we consider a noisy variant of group testing where test results are flipped with certain probability, including the realistic scenario where sensitivity and specificity can take arbitrary values. Using a test design where each individual is assigned to a fixed number of tests, we derive explicit algorithmic bounds for two commonly considered inference algorithms and thereby improve on results by Scarlett & Cevher (SODA 2016) and Scarlett & Johnson (2020) and providing the strongest performance guarantees currently proved for efficient algorithms in these noisy group testing models.

Original language	English
Pages (from-to)	2604-2621
Number of pages	18
Journal	IEEE Transactions on Information Theory
Volume	68
Issue number	4
Early online date	24 Dec 2021
DOIs	https://doi.org/10.1109/TIT.2021.3138489
Publication status	Published - 19 Mar 2022

Bibliographical note

Funding Information:
The work of Oliver Gebhard and Philipp Loick was supported by Deutsche Forschungsgesellschaft (DFG) under Grant CO 646/3.

Publisher Copyright:
IEEE

Keywords

testing
noise measurement
inference algorithms
sensitivity
analytical models
pandemics
coronaviruses
group testing problem
recovery from noisy measurements
efficient algorithm

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10.1109/TIT.2021.3138489

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Accepted author manuscript, 764 KB

https://arxiv.org/abs/2007.01376

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title = "Improved bounds for noisy group testing with constant tests per item",

abstract = "The group testing problem is concerned with identifying a small set of infected individuals in a large population. At our disposal is a testing procedure that allows us to test several individuals together. In an idealized setting, a test is positive if and only if at least one infected individual is included and negative otherwise. Significant progress was made in recent years towards understanding the information-theoretic and algorithmic properties in this noiseless setting. In this paper, we consider a noisy variant of group testing where test results are flipped with certain probability, including the realistic scenario where sensitivity and specificity can take arbitrary values. Using a test design where each individual is assigned to a fixed number of tests, we derive explicit algorithmic bounds for two commonly considered inference algorithms and thereby improve on results by Scarlett \& Cevher (SODA 2016) and Scarlett \& Johnson (2020) and providing the strongest performance guarantees currently proved for efficient algorithms in these noisy group testing models.",

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author = "Oliver Gebhard and Johnson, \{Oliver T\} and Philipp Loick and Maurice Rolvien",

note = "Funding Information: The work of Oliver Gebhard and Philipp Loick was supported by Deutsche Forschungsgesellschaft (DFG) under Grant CO 646/3. Publisher Copyright: IEEE",

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AU - Johnson, Oliver T

AU - Loick, Philipp

AU - Rolvien, Maurice

N1 - Funding Information: The work of Oliver Gebhard and Philipp Loick was supported by Deutsche Forschungsgesellschaft (DFG) under Grant CO 646/3. Publisher Copyright: IEEE

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N2 - The group testing problem is concerned with identifying a small set of infected individuals in a large population. At our disposal is a testing procedure that allows us to test several individuals together. In an idealized setting, a test is positive if and only if at least one infected individual is included and negative otherwise. Significant progress was made in recent years towards understanding the information-theoretic and algorithmic properties in this noiseless setting. In this paper, we consider a noisy variant of group testing where test results are flipped with certain probability, including the realistic scenario where sensitivity and specificity can take arbitrary values. Using a test design where each individual is assigned to a fixed number of tests, we derive explicit algorithmic bounds for two commonly considered inference algorithms and thereby improve on results by Scarlett & Cevher (SODA 2016) and Scarlett & Johnson (2020) and providing the strongest performance guarantees currently proved for efficient algorithms in these noisy group testing models.

AB - The group testing problem is concerned with identifying a small set of infected individuals in a large population. At our disposal is a testing procedure that allows us to test several individuals together. In an idealized setting, a test is positive if and only if at least one infected individual is included and negative otherwise. Significant progress was made in recent years towards understanding the information-theoretic and algorithmic properties in this noiseless setting. In this paper, we consider a noisy variant of group testing where test results are flipped with certain probability, including the realistic scenario where sensitivity and specificity can take arbitrary values. Using a test design where each individual is assigned to a fixed number of tests, we derive explicit algorithmic bounds for two commonly considered inference algorithms and thereby improve on results by Scarlett & Cevher (SODA 2016) and Scarlett & Johnson (2020) and providing the strongest performance guarantees currently proved for efficient algorithms in these noisy group testing models.

KW - testing

KW - noise measurement

KW - inference algorithms

KW - sensitivity

KW - analytical models

KW - pandemics

KW - coronaviruses

KW - group testing problem

KW - recovery from noisy measurements

KW - efficient algorithm

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DO - 10.1109/TIT.2021.3138489

M3 - Article (Academic Journal)

SN - 0018-9448

VL - 68

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EP - 2621

JO - IEEE Transactions on Information Theory

JF - IEEE Transactions on Information Theory

IS - 4

ER -

Improved bounds for noisy group testing with constant tests per item

Abstract

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Keywords

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