<p>The structure of the environment fundamentally shapes how humans see and move. Walking through the city requires the continuous coordination of eyes, head, and body movements, revealing the active role of perception in guiding locomotion. Here, we used wearable eye-tracking, foot-mounted inertial sensors, and GPS to examine how terrain type modulates gaze behaviour and locomotor dynamics during naturalistic urban walking. Twenty young adults walked along routes comprising flat pavements, cobblestones, and dirt paths while their gaze, head orientation, and gait were recorded. Gaze behaviour varied systematically with surface irregularity: cobblestones and dirt paths elicited more frequent downward, proximal gaze and larger downward head-pitch deviations. Gait also adapted, with slower pace, shorter strides, and reduced cadence on uneven surfaces. Spatial correlations revealed tightly coupled adjustments between gaze and gait, indicating continuous sensorimotor coordination. These findings show how the physical structure of urban environments shapes predictive visuomotor strategies during real-world locomotion, providing a multimodal foundation for understanding embodied cognition in motion.</p>

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Gaze and gait dynamics are shaped by terrain type during urban walking

  • Simon Ladouce,
  • C. R. Gillebert

摘要

The structure of the environment fundamentally shapes how humans see and move. Walking through the city requires the continuous coordination of eyes, head, and body movements, revealing the active role of perception in guiding locomotion. Here, we used wearable eye-tracking, foot-mounted inertial sensors, and GPS to examine how terrain type modulates gaze behaviour and locomotor dynamics during naturalistic urban walking. Twenty young adults walked along routes comprising flat pavements, cobblestones, and dirt paths while their gaze, head orientation, and gait were recorded. Gaze behaviour varied systematically with surface irregularity: cobblestones and dirt paths elicited more frequent downward, proximal gaze and larger downward head-pitch deviations. Gait also adapted, with slower pace, shorter strides, and reduced cadence on uneven surfaces. Spatial correlations revealed tightly coupled adjustments between gaze and gait, indicating continuous sensorimotor coordination. These findings show how the physical structure of urban environments shapes predictive visuomotor strategies during real-world locomotion, providing a multimodal foundation for understanding embodied cognition in motion.