An Adaptive Virtual Reality-Based Training System for Pilots

Reyes, César Iván Aguilar; Wozniak, David; Ham, Angel; Zahabi, Maryam

doi:10.1177/1071181322661063

Cited by 6 publications

(2 citation statements)

References 33 publications

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“…In the military domain, VR technologies facilitate diverse training scenarios in simulated environments with varying weather conditions, terrains and day–night cycles (Varol Arısoy and Küçüksille, 2021; Guy, 2020). Reyes et al used VR to develop an adaptive pilot training system (Iván Aguilar Reyes et al , 2022), maintaining pilots’ cognitive abilities. In addition, VR plays a crucial role in demining, reducing the associated dangers.…”

Section: Virtual Reality Technologymentioning

confidence: 99%

Immersive innovations: an examination of the efficacy and evolution of virtual reality in human movement training

Deng,

Wang,

Dong

et al. 2023

RIA

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Purpose This systematic review, following preferred reporting items for systematic reviews and meta-analysis guidelines, rigorously investigates the emergent role of virtual reality (VR) technology in human movement training. The purpose of this study is to explore the effectiveness and evolution of VR in enhancing movement training experiences. Design/methodology/approach Acknowledging its pivotal role in diverse applications, such as sports and rehabilitation, human movement training is currently experiencing accelerated evolution, facilitated by the proliferation of wearable devices and mobile applications. This review conducted an exhaustive search across five different electronic databases, such as Web of Science, PubMed and ProQuest, resulting in the selection of 69 eligible articles published within the past five years. It also integrates 40 studies into a narrative summary, categorized based on the level of immersion offered by respective VR systems. Findings Enhanced immersion in VR potentially augments the effectiveness of movement training by engendering more realistic and captivating experiences for users. The immersive and interactive environments provided by VR technology enable tailored training experiences accompanied by precise, objective feedback. This review highlights the benefits of VR in human movement training and its potential to revolutionize the way training is conducted. Originality/value This systematic review contributes significantly to the existing literature by providing a comprehensive examination of the efficacy and evolution of VR in human movement training. By organizing the findings based on the level of immersion offered by VR systems, it provides valuable insights into the importance of immersion in enhancing training outcomes. In addition, this study identifies the need for future research focusing on the impacts of VR on learning and performance, as well as strategies to optimize its effectiveness and improve accessibility.

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Section: Virtual Reality Technologymentioning

confidence: 99%

Immersive innovations: an examination of the efficacy and evolution of virtual reality in human movement training

Deng,

Wang,

Dong

et al. 2023

RIA

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“…The challenge-point framework suggests that training efficiency is increased by modulating difficulty to account for the skill level of the performer to provide optimal challenge (Guadagnoli and Lee, 2004). Automated training where task difficulty is adaptively matched to skill is known to increase engagement (Missura, 2015;Xue et al, 2017), improve training outcomes (Hunicke, 2005;Lang et al, 2018;Iván Aguilar Reyes et al, 2022), and enhance overall experience and reported stimulation (Schmidt, 1975). However, the effect of personalized rather than standardized progression on training outcomes and flow experience, which depend on how well a training system provides optimal challenge, has not been investigated (Vaughan et al, 2016;Jeelani et al, 2017;Yovanoff et al, 2017).…”

Section: Introductionmentioning

confidence: 99%

Features of adaptive training algorithms for improved complex skill acquisition

Verniani,

Galvin,

Tredinnick

et al. 2024

Front. Virtual Real.

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Training complex skills is typically accomplished by means of a trainer or mediator who tailors instruction to the individual trainee. However, facilitated training is costly and labor intensive, and the use of a mediator is infeasible in remote or extreme environments. Imparting complex skills in applications like long-duration human spaceflight, military field operations, or remote medicine may require automated training algorithms. Virtual reality (VR) is an effective, easily programmable, immersive training medium that has been used widely across fields. However, there remain open questions in the search for the most effective algorithms for guiding automated training progression. This study investigates the effects of responsiveness, personalization, and subtask independence on the efficacy of automated training algorithms in VR for training complex, operationally relevant tasks. Thirty-two subjects (16M/16F, 18–54 years) were trained to pilot and land a spacecraft on Mars within a VR simulation using four different automated training algorithms. Performance was assessed in a physical cockpit mock-up. We found that personalization results in faster skill acquisition on average when compared with a standardized progression built for a median subject (p = 0.0050). The standardized progression may be preferable when consistent results are desired across all subjects. Independence of the difficulty adjustments between subtasks may lead to increased skill acquisition, while lockstep in the progression of each subtask increases self-reported flow experience (p = 0.01), fluency (p = 0.02), and absorption (p = 0.01) on the Flow Short Scale. Data visualization suggests that highly responsive algorithms may lead to faster learning progressions and higher skill acquisition for some subjects. Improving transfer of skills from training to testing may require either high responsiveness or a standardized training progression. Optimizing the design of automated, individually adaptive algorithms around the training needs of a group may be useful to increase skill acquisition for complex operational tasks.

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