Density-Dependent Group Testing

Rahil D Morjaria; Sidharth (Sid) Jaggi; Venkata Gandikota; Saikiran Bulusu

Density-Dependent Group Testing

Rahil D Morjaria^*, Sidharth (Sid) Jaggi, Venkata Gandikota, Saikiran Bulusu

^*Corresponding author for this work

Research output: Contribution to conference › Conference Paper › peer-review

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Abstract

Group testing is the problem of identifying a small subset of defectives from a large set using as few binary tests as possible. In most current literature on group testing the binary test outcome is $1$ if the pool contains at least one defective, and $0$ otherwise. In this work we initiate the study of a generalized model of group testing that accommodates the physical effects of dilution of infected samples in large pools. In this model the binary test outcome is $1$ with probability $f(\rho)$, where $\rho$ is the density of the defectives in the test, and $f:[0,1]\rightarrow [0,1]$ is a given "test function" that models this dilution process. For a large class of test functions our results establish near-optimal sample complexity bounds, by providing information-theoretic lower bounds on the number of tests necessary to recover the set of defective items, and providing computationally efficient algorithms with sample complexities that match these lower bounds up to constant or logarithmic factors. Furthermore, using tools from real analysis, we extend our results to any "sufficiently well-behaved function" $f:[0,1]\rightarrow [0,1]$.

Original language	English
Pages	1-50
Number of pages	50
Publication status	Accepted/In press - 11 Mar 2025
Event	The 28th International Conference on Artificial Intelligence and Statistics - Mai Khao, Thailand Duration: 3 May 2025 → 5 May 2025 https://aistats.org/aistats2025//

Conference

Conference	The 28th International Conference on Artificial Intelligence and Statistics
Abbreviated title	AISTATS 2025
Country/Territory	Thailand
City	Mai Khao
Period	3/05/25 → 5/05/25
Internet address	https://aistats.org/aistats2025//

Research Groups and Themes

Applied Mathematics
Information Theory
Group Testing
Probability, Analysis and Dynamics
Information Theory
Group Testing
fractional derivatives
fractional taylor series
Statistical Science
Information Theory
Group Testing

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title = "Density-Dependent Group Testing",

abstract = "Group testing is the problem of identifying a small subset of defectives from a large set using as few binary tests as possible. In most current literature on group testing the binary test outcome is $1$ if the pool contains at least one defective, and $0$ otherwise. In this work we initiate the study of a generalized model of group testing that accommodates the physical effects of dilution of infected samples in large pools. In this model the binary test outcome is $1$ with probability $f(\rho)$, where $\rho$ is the density of the defectives in the test, and $f:[0,1]\rightarrow [0,1]$ is a given {"}test function{"} that models this dilution process. For a large class of test functions our results establish near-optimal sample complexity bounds, by providing information-theoretic lower bounds on the number of tests necessary to recover the set of defective items, and providing computationally efficient algorithms with sample complexities that match these lower bounds up to constant or logarithmic factors. Furthermore, using tools from real analysis, we extend our results to any {"}sufficiently well-behaved function{"} $f:[0,1]\rightarrow [0,1]$.",

author = "Morjaria, {Rahil D} and Jaggi, {Sidharth (Sid)} and Venkata Gandikota and Saikiran Bulusu",

year = "2025",

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TY - CONF

T1 - Density-Dependent Group Testing

AU - Morjaria, Rahil D

AU - Jaggi, Sidharth (Sid)

AU - Gandikota, Venkata

AU - Bulusu, Saikiran

PY - 2025/3/11

Y1 - 2025/3/11

N2 - Group testing is the problem of identifying a small subset of defectives from a large set using as few binary tests as possible. In most current literature on group testing the binary test outcome is $1$ if the pool contains at least one defective, and $0$ otherwise. In this work we initiate the study of a generalized model of group testing that accommodates the physical effects of dilution of infected samples in large pools. In this model the binary test outcome is $1$ with probability $f(\rho)$, where $\rho$ is the density of the defectives in the test, and $f:[0,1]\rightarrow [0,1]$ is a given "test function" that models this dilution process. For a large class of test functions our results establish near-optimal sample complexity bounds, by providing information-theoretic lower bounds on the number of tests necessary to recover the set of defective items, and providing computationally efficient algorithms with sample complexities that match these lower bounds up to constant or logarithmic factors. Furthermore, using tools from real analysis, we extend our results to any "sufficiently well-behaved function" $f:[0,1]\rightarrow [0,1]$.

AB - Group testing is the problem of identifying a small subset of defectives from a large set using as few binary tests as possible. In most current literature on group testing the binary test outcome is $1$ if the pool contains at least one defective, and $0$ otherwise. In this work we initiate the study of a generalized model of group testing that accommodates the physical effects of dilution of infected samples in large pools. In this model the binary test outcome is $1$ with probability $f(\rho)$, where $\rho$ is the density of the defectives in the test, and $f:[0,1]\rightarrow [0,1]$ is a given "test function" that models this dilution process. For a large class of test functions our results establish near-optimal sample complexity bounds, by providing information-theoretic lower bounds on the number of tests necessary to recover the set of defective items, and providing computationally efficient algorithms with sample complexities that match these lower bounds up to constant or logarithmic factors. Furthermore, using tools from real analysis, we extend our results to any "sufficiently well-behaved function" $f:[0,1]\rightarrow [0,1]$.

UR - https://aistats.org/aistats2025//

M3 - Conference Paper

SP - 1

EP - 50

T2 - The 28th International Conference on Artificial Intelligence and Statistics

Y2 - 3 May 2025 through 5 May 2025

ER -

Density-Dependent Group Testing

Abstract

Conference

Research Groups and Themes

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