Saved in:
Bibliographic Details
Main Authors: Li, Tao, Zhang, Chunze, Yao, Weiwei, He, Junzhao, Hou, Ji, Zhou, Qin, Zhang, Lu
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2512.01218
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866912740312875008
author Li, Tao
Zhang, Chunze
Yao, Weiwei
He, Junzhao
Hou, Ji
Zhou, Qin
Zhang, Lu
author_facet Li, Tao
Zhang, Chunze
Yao, Weiwei
He, Junzhao
Hou, Ji
Zhou, Qin
Zhang, Lu
contents Understanding efficient fish locomotion offers insights for biomechanics, fluid dynamics, and engineering. Traditional studies often miss the link between neuromuscular control and whole-body movement. To explore energy transfer in carangiform swimming, we created a bio-inspired digital trout. This model combined multibody dynamics, Hill-type muscle modeling, and a high-fidelity fluid-structure interaction algorithm, accurately replicating a real trout's form and properties. Using deep reinforcement learning, the trout's neural system achieved hierarchical spatiotemporal control of muscle activation. We systematically examined how activation strategies affect speed and energy use. Results show that axial myomere coupling-with activation spanning over 0.5 body lengths-is crucial for stable body wave propagation. Moderate muscle contraction duration ([0.1,0.3] of a tail-beat cycle) lets the body and fluid act as a passive damping system, cutting energy use. Additionally, the activation phase lag of myomeres shapes the body wave; if too large, it causes antagonistic contractions that hinder thrust. These findings advance bio-inspired locomotion understanding and aid energy-efficient underwater system design.
format Preprint
id arxiv_https___arxiv_org_abs_2512_01218
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle How do trout regulate patterns of muscle contraction to optimize propulsive efficiency during steady swimming
Li, Tao
Zhang, Chunze
Yao, Weiwei
He, Junzhao
Hou, Ji
Zhou, Qin
Zhang, Lu
Fluid Dynamics
Artificial Intelligence
Robotics
Understanding efficient fish locomotion offers insights for biomechanics, fluid dynamics, and engineering. Traditional studies often miss the link between neuromuscular control and whole-body movement. To explore energy transfer in carangiform swimming, we created a bio-inspired digital trout. This model combined multibody dynamics, Hill-type muscle modeling, and a high-fidelity fluid-structure interaction algorithm, accurately replicating a real trout's form and properties. Using deep reinforcement learning, the trout's neural system achieved hierarchical spatiotemporal control of muscle activation. We systematically examined how activation strategies affect speed and energy use. Results show that axial myomere coupling-with activation spanning over 0.5 body lengths-is crucial for stable body wave propagation. Moderate muscle contraction duration ([0.1,0.3] of a tail-beat cycle) lets the body and fluid act as a passive damping system, cutting energy use. Additionally, the activation phase lag of myomeres shapes the body wave; if too large, it causes antagonistic contractions that hinder thrust. These findings advance bio-inspired locomotion understanding and aid energy-efficient underwater system design.
title How do trout regulate patterns of muscle contraction to optimize propulsive efficiency during steady swimming
topic Fluid Dynamics
Artificial Intelligence
Robotics
url https://arxiv.org/abs/2512.01218