Two-dimensionally stable self-organisation arises in simple schooling swimmers through hydrodynamic interactions
Two-dimensionally stable self-organisation arises in simple schooling swimmers through hydrodynamic interactions
We present new constrained and free-swimming experiments and simulations in the inertial regime, with Reynolds number Re = O(104), of a pair of two-dimensional and three-dimensional pitching hydrofoils interacting in a minimal school. The hydrofoils have an out-of-phase synchronisation, and they are varied through in-line, staggered and side-by-side formations within the two-dimensional interaction plane. It is discovered that there is a two-dimensionally stable equilibrium point for a side-by-side formation. This formation is super-stable, meaning that hydrodynamic forces will passively maintain this formation even under external perturbations, and the school as a whole has no net forces acting on it that cause it to drift to one side or the other. Previously discovered one-dimensionally stable equilibria driven by wake vortex interactions are shown to be, in fact, two-dimensionally unstable, at least for an out-of-phase synchronisation. Additionally, it is discovered that a trailing-edge vortex mechanism provides the restorative force to stabilise a side-by-side formation. The stable equilibrium is further verified by experiments and simulations for freely swimming foils where dynamic recoil motions are present. When constrained, swimmers in compact side-by-side formations experience collective efficiency and thrust increases up to 40% and 100%, respectively, whereas slightly staggered formations output an even higher efficiency improvement of 84 %, with an 87 % increase in thrust. Freely swimming foils in a stable side-by-side formation show efficiency and speed enhancements of up to 9 % and 15 %, respectively. These newfound schooling performance and stability characteristics suggest that fluid-mediated equilibria may play a role in the control strategies of schooling fish and fish-inspired robots.
flying, swimming
Ormonde, Pedro C.
6bda527d-bf60-40d6-97b6-d3303fc12ab8
Kurt, Melike
15dea522-b5e5-4360-8b03-7a68e543c873
Mivehchi, Amin
e3cd21f8-2efd-4b02-9c02-c0fe320e3d24
Moored, Keith W.
9c89d06c-a49a-4ff0-bd32-37d9d143d39a
Ormonde, Pedro C.
6bda527d-bf60-40d6-97b6-d3303fc12ab8
Kurt, Melike
15dea522-b5e5-4360-8b03-7a68e543c873
Mivehchi, Amin
e3cd21f8-2efd-4b02-9c02-c0fe320e3d24
Moored, Keith W.
9c89d06c-a49a-4ff0-bd32-37d9d143d39a
Ormonde, Pedro C., Kurt, Melike, Mivehchi, Amin and Moored, Keith W.
(2024)
Two-dimensionally stable self-organisation arises in simple schooling swimmers through hydrodynamic interactions.
Journal of Fluid Mechanics, 1000, [A90].
(doi:10.1017/jfm.2024.1086).
Abstract
We present new constrained and free-swimming experiments and simulations in the inertial regime, with Reynolds number Re = O(104), of a pair of two-dimensional and three-dimensional pitching hydrofoils interacting in a minimal school. The hydrofoils have an out-of-phase synchronisation, and they are varied through in-line, staggered and side-by-side formations within the two-dimensional interaction plane. It is discovered that there is a two-dimensionally stable equilibrium point for a side-by-side formation. This formation is super-stable, meaning that hydrodynamic forces will passively maintain this formation even under external perturbations, and the school as a whole has no net forces acting on it that cause it to drift to one side or the other. Previously discovered one-dimensionally stable equilibria driven by wake vortex interactions are shown to be, in fact, two-dimensionally unstable, at least for an out-of-phase synchronisation. Additionally, it is discovered that a trailing-edge vortex mechanism provides the restorative force to stabilise a side-by-side formation. The stable equilibrium is further verified by experiments and simulations for freely swimming foils where dynamic recoil motions are present. When constrained, swimmers in compact side-by-side formations experience collective efficiency and thrust increases up to 40% and 100%, respectively, whereas slightly staggered formations output an even higher efficiency improvement of 84 %, with an 87 % increase in thrust. Freely swimming foils in a stable side-by-side formation show efficiency and speed enhancements of up to 9 % and 15 %, respectively. These newfound schooling performance and stability characteristics suggest that fluid-mediated equilibria may play a role in the control strategies of schooling fish and fish-inspired robots.
Text
two-dimensionally-stable-self-organisation-arises-in-simple-schooling-swimmers-through-hydrodynamic-interactions
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Accepted/In Press date: 5 November 2024
e-pub ahead of print date: 2 December 2024
Keywords:
flying, swimming
Identifiers
Local EPrints ID: 497336
URI: http://eprints.soton.ac.uk/id/eprint/497336
ISSN: 0022-1120
PURE UUID: d0282acd-43b3-41e7-9e76-c665ea3803f8
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Date deposited: 20 Jan 2025 17:43
Last modified: 22 Aug 2025 02:31
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Author:
Pedro C. Ormonde
Author:
Melike Kurt
Author:
Amin Mivehchi
Author:
Keith W. Moored
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