Intrinsic Fluctuations and Driven Response of Insect Swarms

Rui Ni; James G. Puckett; Eric R. Dufresne; Nicholas T. Ouellette

doi:10.1103/PhysRevLett.115.118104

Intrinsic Fluctuations and Driven Response of Insect Swarms

Rui Ni
, James G. Puckett
, Eric R. Dufresne
, Nicholas T. Ouellette

Materials Research Institute (MRI)

Research output: Contribution to journal › Article › peer-review

42 Scopus citations

Abstract

Animals of all sizes form groups, as acting together can convey advantages over acting alone; thus, collective animal behavior has been identified as a promising template for designing engineered systems. However, models and observations have focused predominantly on characterizing the overall group morphology, and often focus on highly ordered groups such as bird flocks. We instead study a disorganized aggregation (an insect mating swarm), and compare its natural fluctuations with the group-level response to an external stimulus. We quantify the swarm's frequency-dependent linear response and its spectrum of intrinsic fluctuations, and show that the ratio of these two quantities has a simple scaling with frequency. Our results provide a new way of comparing models of collective behavior with experimental data.

Original language	English (US)
Article number	118104
Journal	Physical review letters
Volume	115
Issue number	11
DOIs	https://doi.org/10.1103/PhysRevLett.115.118104
State	Published - Sep 10 2015

All Science Journal Classification (ASJC) codes

General Physics and Astronomy

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10.1103/PhysRevLett.115.118104

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title = "Intrinsic Fluctuations and Driven Response of Insect Swarms",

abstract = "Animals of all sizes form groups, as acting together can convey advantages over acting alone; thus, collective animal behavior has been identified as a promising template for designing engineered systems. However, models and observations have focused predominantly on characterizing the overall group morphology, and often focus on highly ordered groups such as bird flocks. We instead study a disorganized aggregation (an insect mating swarm), and compare its natural fluctuations with the group-level response to an external stimulus. We quantify the swarm's frequency-dependent linear response and its spectrum of intrinsic fluctuations, and show that the ratio of these two quantities has a simple scaling with frequency. Our results provide a new way of comparing models of collective behavior with experimental data.",

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note = "Publisher Copyright: {\textcopyright} 2015 American Physical Society.",

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AB - Animals of all sizes form groups, as acting together can convey advantages over acting alone; thus, collective animal behavior has been identified as a promising template for designing engineered systems. However, models and observations have focused predominantly on characterizing the overall group morphology, and often focus on highly ordered groups such as bird flocks. We instead study a disorganized aggregation (an insect mating swarm), and compare its natural fluctuations with the group-level response to an external stimulus. We quantify the swarm's frequency-dependent linear response and its spectrum of intrinsic fluctuations, and show that the ratio of these two quantities has a simple scaling with frequency. Our results provide a new way of comparing models of collective behavior with experimental data.

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ER -

Intrinsic Fluctuations and Driven Response of Insect Swarms

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