Saved in:
Bibliographic Details
Main Authors: Wang, Wei-Chen, De Comite, Antoine, Voloshina, Alexandra, Daley, Monica, Seethapathi, Nidhi
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2503.16340
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866912555821170688
author Wang, Wei-Chen
De Comite, Antoine
Voloshina, Alexandra
Daley, Monica
Seethapathi, Nidhi
author_facet Wang, Wei-Chen
De Comite, Antoine
Voloshina, Alexandra
Daley, Monica
Seethapathi, Nidhi
contents Everyday locomotion is a complex sensorimotor process that can unfold over multiple timescales, from long-term path planning to rapid, reactive adjustments. However, we lack an understanding of how factors such as environmental demands, or the available sensory information simultaneously influence these control timescales. To address this, we present a unified data-driven framework to quantify the control timescales by identifying how early we can predict future actions from past inputs. We apply this framework across tasks including walking and running, environmental contexts including treadmill, overground, and varied terrains, and sensory input modalities including gaze fixations and body states. We find that deep neural network architectures that effectively handle long-range dependencies, specifically Gated Recurrent Units and Transformers, outperform other architectures and widely used linear models when predicting future actions. Our framework reveals the factors that influence locomotor foot placement control timescales. Across environmental contexts, we discover that humans rely more on fast timescale control in more complex terrain. Across input modalities, we find a hierarchy of control timescales where gaze predicts foot placement before full-body states, which predict before center-of-mass states. Our model also identifies mid-swing as a critical phase when the swing foot's state predicts its future placement, with this timescale adapting across environments. Overall, this work offers data-driven insights into locomotor control in everyday settings, offering models that can be integrated with rehabilitation technologies and movement simulations to improve their applicability in everyday settings.
format Preprint
id arxiv_https___arxiv_org_abs_2503_16340
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Human locomotor control timescales depend on the environmental context and sensory input modality
Wang, Wei-Chen
De Comite, Antoine
Voloshina, Alexandra
Daley, Monica
Seethapathi, Nidhi
Machine Learning
Robotics
Everyday locomotion is a complex sensorimotor process that can unfold over multiple timescales, from long-term path planning to rapid, reactive adjustments. However, we lack an understanding of how factors such as environmental demands, or the available sensory information simultaneously influence these control timescales. To address this, we present a unified data-driven framework to quantify the control timescales by identifying how early we can predict future actions from past inputs. We apply this framework across tasks including walking and running, environmental contexts including treadmill, overground, and varied terrains, and sensory input modalities including gaze fixations and body states. We find that deep neural network architectures that effectively handle long-range dependencies, specifically Gated Recurrent Units and Transformers, outperform other architectures and widely used linear models when predicting future actions. Our framework reveals the factors that influence locomotor foot placement control timescales. Across environmental contexts, we discover that humans rely more on fast timescale control in more complex terrain. Across input modalities, we find a hierarchy of control timescales where gaze predicts foot placement before full-body states, which predict before center-of-mass states. Our model also identifies mid-swing as a critical phase when the swing foot's state predicts its future placement, with this timescale adapting across environments. Overall, this work offers data-driven insights into locomotor control in everyday settings, offering models that can be integrated with rehabilitation technologies and movement simulations to improve their applicability in everyday settings.
title Human locomotor control timescales depend on the environmental context and sensory input modality
topic Machine Learning
Robotics
url https://arxiv.org/abs/2503.16340