Leader-Follower 3D Formation for Underwater Robots

Di Ni; Hungtang Ko; Radhika Nagpal

doi:10.1007/978-3-032-04584-3_17

Leader-Follower 3D Formation for Underwater Robots

Di Ni
, Hungtang Ko
, Radhika Nagpal

Mechanical & Aerospace Engineering

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution

Abstract

The schooling behavior of fish is hypothesized to confer many survival benefits, including foraging success, safety from predators, and energy savings through hydrodynamic interactions when swimming in formation. Underwater robot collectives may be able to achieve similar benefits in future applications, e.g. using formation control to achieve efficient spatial sampling for environmental monitoring. Although many theoretical algorithms exist for multi-robot formation control, they have not been tested in the underwater domain due to the fundamental challenges in underwater communication. Here we introduce a leader-follower strategy for underwater formation control that allows us to realize complex 3D formations, using purely vision-based perception and a reactive control algorithm that is low computation. We use a physical platform, BlueSwarm, to demonstrate for the first time an experimental realization of inline, side-by-side, and staggered swimming 3D formations. More complex formations are studied in a physics-based simulator, providing new insights into the convergence and stability of formations given underwater inertial/drag conditions. Our findings lay the groundwork for future applications of underwater robot swarms in aquatic environments with minimal communication.

Original language	English (US)
Title of host publication	Distributed Autonomous Robotic Systems - 17th International Symposium
Editors	Alexandra Nilles, Kirstin H. Petersen, Tin Lun Lam, Amanda Prorok, Michael Rubenstein, Michael Otte
Publisher	Springer Nature
Pages	243-258
Number of pages	16
ISBN (Print)	9783032045836
DOIs	https://doi.org/10.1007/978-3-032-04584-3_17
State	Published - 2026
Event	17th International Symposium on Distributed Autonomous Robotic Systems, DARS 2024 - Roosevelt Island , United States Duration: Oct 28 2024 → Oct 30 2024

Publication series

Name	Springer Proceedings in Advanced Robotics
Volume	34
ISSN (Print)	2511-1256
ISSN (Electronic)	2511-1264

Conference

Conference	17th International Symposium on Distributed Autonomous Robotic Systems, DARS 2024
Country/Territory	United States
City	Roosevelt Island
Period	10/28/24 → 10/30/24

All Science Journal Classification (ASJC) codes

Control and Systems Engineering
Engineering (miscellaneous)
Mechanical Engineering
Computer Science Applications
Artificial Intelligence
Applied Mathematics
Electrical and Electronic Engineering

Keywords

Bio-inspired Robots
Formation control
Swarm Robotics

Access to Document

10.1007/978-3-032-04584-3_17

Cite this

Ni, D., Ko, H., & Nagpal, R. (2026). Leader-Follower 3D Formation for Underwater Robots. In A. Nilles, K. H. Petersen, T. L. Lam, A. Prorok, M. Rubenstein, & M. Otte (Eds.), Distributed Autonomous Robotic Systems - 17th International Symposium (pp. 243-258). (Springer Proceedings in Advanced Robotics; Vol. 34). Springer Nature. https://doi.org/10.1007/978-3-032-04584-3_17

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title = "Leader-Follower 3D Formation for Underwater Robots",

abstract = "The schooling behavior of fish is hypothesized to confer many survival benefits, including foraging success, safety from predators, and energy savings through hydrodynamic interactions when swimming in formation. Underwater robot collectives may be able to achieve similar benefits in future applications, e.g. using formation control to achieve efficient spatial sampling for environmental monitoring. Although many theoretical algorithms exist for multi-robot formation control, they have not been tested in the underwater domain due to the fundamental challenges in underwater communication. Here we introduce a leader-follower strategy for underwater formation control that allows us to realize complex 3D formations, using purely vision-based perception and a reactive control algorithm that is low computation. We use a physical platform, BlueSwarm, to demonstrate for the first time an experimental realization of inline, side-by-side, and staggered swimming 3D formations. More complex formations are studied in a physics-based simulator, providing new insights into the convergence and stability of formations given underwater inertial/drag conditions. Our findings lay the groundwork for future applications of underwater robot swarms in aquatic environments with minimal communication.",

keywords = "Bio-inspired Robots, Formation control, Swarm Robotics",

author = "Di Ni and Hungtang Ko and Radhika Nagpal",

note = "Publisher Copyright: {\textcopyright} The Author(s), under exclusive license to Springer Nature Switzerland AG 2026.; 17th International Symposium on Distributed Autonomous Robotic Systems, DARS 2024 ; Conference date: 28-10-2024 Through 30-10-2024",

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doi = "10.1007/978-3-032-04584-3\_17",

language = "English (US)",

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Ni, D, Ko, H & Nagpal, R 2026, Leader-Follower 3D Formation for Underwater Robots. in A Nilles, KH Petersen, TL Lam, A Prorok, M Rubenstein & M Otte (eds), Distributed Autonomous Robotic Systems - 17th International Symposium. Springer Proceedings in Advanced Robotics, vol. 34, Springer Nature, pp. 243-258, 17th International Symposium on Distributed Autonomous Robotic Systems, DARS 2024, Roosevelt Island , United States, 10/28/24. https://doi.org/10.1007/978-3-032-04584-3_17

Leader-Follower 3D Formation for Underwater Robots. / Ni, Di; Ko, Hungtang; Nagpal, Radhika.
Distributed Autonomous Robotic Systems - 17th International Symposium. ed. / Alexandra Nilles; Kirstin H. Petersen; Tin Lun Lam; Amanda Prorok; Michael Rubenstein; Michael Otte. Springer Nature, 2026. p. 243-258 (Springer Proceedings in Advanced Robotics; Vol. 34).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution

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T1 - Leader-Follower 3D Formation for Underwater Robots

AU - Ni, Di

AU - Ko, Hungtang

AU - Nagpal, Radhika

N1 - Publisher Copyright: © The Author(s), under exclusive license to Springer Nature Switzerland AG 2026.

PY - 2026

Y1 - 2026

N2 - The schooling behavior of fish is hypothesized to confer many survival benefits, including foraging success, safety from predators, and energy savings through hydrodynamic interactions when swimming in formation. Underwater robot collectives may be able to achieve similar benefits in future applications, e.g. using formation control to achieve efficient spatial sampling for environmental monitoring. Although many theoretical algorithms exist for multi-robot formation control, they have not been tested in the underwater domain due to the fundamental challenges in underwater communication. Here we introduce a leader-follower strategy for underwater formation control that allows us to realize complex 3D formations, using purely vision-based perception and a reactive control algorithm that is low computation. We use a physical platform, BlueSwarm, to demonstrate for the first time an experimental realization of inline, side-by-side, and staggered swimming 3D formations. More complex formations are studied in a physics-based simulator, providing new insights into the convergence and stability of formations given underwater inertial/drag conditions. Our findings lay the groundwork for future applications of underwater robot swarms in aquatic environments with minimal communication.

AB - The schooling behavior of fish is hypothesized to confer many survival benefits, including foraging success, safety from predators, and energy savings through hydrodynamic interactions when swimming in formation. Underwater robot collectives may be able to achieve similar benefits in future applications, e.g. using formation control to achieve efficient spatial sampling for environmental monitoring. Although many theoretical algorithms exist for multi-robot formation control, they have not been tested in the underwater domain due to the fundamental challenges in underwater communication. Here we introduce a leader-follower strategy for underwater formation control that allows us to realize complex 3D formations, using purely vision-based perception and a reactive control algorithm that is low computation. We use a physical platform, BlueSwarm, to demonstrate for the first time an experimental realization of inline, side-by-side, and staggered swimming 3D formations. More complex formations are studied in a physics-based simulator, providing new insights into the convergence and stability of formations given underwater inertial/drag conditions. Our findings lay the groundwork for future applications of underwater robot swarms in aquatic environments with minimal communication.

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A2 - Prorok, Amanda

A2 - Rubenstein, Michael

A2 - Otte, Michael

PB - Springer Nature

T2 - 17th International Symposium on Distributed Autonomous Robotic Systems, DARS 2024

Y2 - 28 October 2024 through 30 October 2024

ER -

Leader-Follower 3D Formation for Underwater Robots

Abstract

Publication series

Conference

All Science Journal Classification (ASJC) codes

Keywords

Access to Document

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