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Effects of angular gain transformations between movement and visual feedback on coordination performance in unimanual circling

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Rieger,  Martina
Department Psychology, MPI for Human Cognitive and Brain Sciences, Max Planck Society;
Department for Medical Sciences and Health Systems Management, University for Health Sciences, Medical Informatics and Technology, Hall in Tirol, Austria;

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Dietrich,  Sandra
Department Psychology, MPI for Human Cognitive and Brain Sciences, Max Planck Society;
Faculty of Education, University of Leipzig, Germany;

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Prinz,  Wolfgang
Department Psychology, MPI for Human Cognitive and Brain Sciences, Max Planck Society;

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Citation

Rieger, M., Dietrich, S., & Prinz, W. (2014). Effects of angular gain transformations between movement and visual feedback on coordination performance in unimanual circling. Frontiers in Psychology, 5: 152. doi:10.3389/fpsyg.2014.00152.


Cite as: https://hdl.handle.net/11858/00-001M-0000-0018-A94E-7
Abstract
Tool actions are characterized by a transformation (of spatio-temporal and/or force-related characteristics) between movements and their resulting consequences in the environment. This transformation has to be taken into account, when planning and executing movements and its existence may affect performance. In the present study we investigated how angular gain transformations between movement and visual feedback during circling movements affect coordination performance. Participants coordinated the visual feedback (feedback dot) with a continuously circling stimulus (stimulus dot) on a computer screen in order to produce mirror symmetric trajectories of them. The movement angle was multiplied by a gain factor (0.5–2; nine levels) before it was presented on the screen. Thus, the angular gain transformations changed the spatio-temporal relationship between the movement and its feedback in visual space, and resulted in a non-constant mapping of movement to feedback positions. Coordination performance was best with gain = 1. With high gains the feedback dot was in lead of the stimulus dot, with small gains it lagged behind. Anchoring (reduced movement variability) occurred when the two trajectories were close to each other. Awareness of the transformation depended on the deviation of the gain from 1. In conclusion, the size of an angular gain transformation as well as its mere presence influence performance in a situation in which the mapping of movement positions to visual feedback positions is not constant. When designing machines or tools that involve transformations between movements and their external consequences, one should be aware that the mere presence of angular gains may result in performance decrements and that there can be flaws in the representation of the transformation.