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Investigating the effectiveness of immersive VR skill training and its link to physiological arousal

Published: 14 November 2022 Publication History

Abstract

This paper details the motivations, design, and analysis of a study using a fine motor skill training task in both VR and physical conditions. The objective of this between-subjects study was to (a) investigate the effectiveness of immersive virtual reality for training participants in the ‘buzz-wire’ fine motor skill task compared to physical training and (b) investigate the link between participants’ arousal with their improvements in task performance. Physiological arousal levels in the form of  electro-dermal activity (EDA) and ECG (Electrocardiogram) data were collected from 87 participants, randomly distributed across the two conditions. Results indicated that VR training is as good as, or even slightly better than, training in physical training in improving task performance. Moreover, the participants in the VR condition reported an increase in self-efficacy and immersion, while marginally significant differences were observed in the presence and the temporal demand (retrieved from NASA-TLX measurements). Participants in the VR condition showed on average less arousal than those in the physical condition. Though correlation analyses between performance metrics and arousal levels did not depict any statistically significant results, a closer examination of EDA values revealed that participants with lower arousal levels during training, across conditions, demonstrated better improvements in performance than those with higher arousal. These findings demonstrate the effectiveness of VR in training and the potential of using arousal and training performance data for designing adaptive VR training systems. This paper also discusses implications for researchers who consider using biosensors and VR for motor skill experiments.

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cover image Virtual Reality
Virtual Reality  Volume 27, Issue 2
Jun 2023
1035 pages
ISSN:1359-4338
EISSN:1434-9957
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Springer-Verlag

Berlin, Heidelberg

Publication History

Published: 14 November 2022
Accepted: 13 September 2022
Received: 08 June 2022

Author Tags

  1. Immersive virtual reality
  2. Skill training
  3. Physiological arousal
  4. Electro-dermal activity
  5. Heart rate variability

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