Investigating the process of learning with desktop virtual reality: A structural equation modeling approach

Guido Makransky; Gustav Bøg Petersen

doi:10.1016/j.compedu.2019.02.002

Investigating the process of learning with desktop virtual reality: A structural equation modeling approach

Guido Makransky^*, Gustav Bøg Petersen

^*Corresponding author for this work

35 Citations (Scopus)

Abstract

Virtual reality (VR) is gaining attention for having the potential to enrich students’ educational experiences. However, few studies have investigated the process of learning with VR. With the use of structural equation modeling, this study investigated the affective and cognitive factors that play a role in learning with a desktop VR simulation when pre-to post-test changes in motivation, self-efficacy, and knowledge about genetics are used as outcomes. The sample consisted of 199 university students (120 females), who learned from a desktop VR genetics simulation as a mandatory part of an undergraduate medical genetics course. The results indicated that there were two general paths by which desktop VR led to increases in the amount of learning following a VR lesson: an affective path that went through VR features, presence, intrinsic motivation, and self-efficacy; and a cognitive path that went through VR features, usability, cognitive benefits, and self-efficacy. It is concluded that learners may benefit from desktop VR simulations in which efficacious VR features and a high level of usability are emphasized.

Original language	English
Journal	Computers and Education
Volume	134
Pages (from-to)	15-30
Number of pages	16
ISSN	0360-1315
DOIs	https://doi.org/10.1016/j.compedu.2019.02.002
Publication status	Published - 1 Jun 2019

Keywords

Desktop virtual reality
Interactive learning environments
Simulations
Structural equation modeling
Virtual labs

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10.1016/j.compedu.2019.02.002

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title = "Investigating the process of learning with desktop virtual reality: A structural equation modeling approach",

abstract = "Virtual reality (VR) is gaining attention for having the potential to enrich students{\textquoteright} educational experiences. However, few studies have investigated the process of learning with VR. With the use of structural equation modeling, this study investigated the affective and cognitive factors that play a role in learning with a desktop VR simulation when pre-to post-test changes in motivation, self-efficacy, and knowledge about genetics are used as outcomes. The sample consisted of 199 university students (120 females), who learned from a desktop VR genetics simulation as a mandatory part of an undergraduate medical genetics course. The results indicated that there were two general paths by which desktop VR led to increases in the amount of learning following a VR lesson: an affective path that went through VR features, presence, intrinsic motivation, and self-efficacy; and a cognitive path that went through VR features, usability, cognitive benefits, and self-efficacy. It is concluded that learners may benefit from desktop VR simulations in which efficacious VR features and a high level of usability are emphasized.",

keywords = "Desktop virtual reality, Interactive learning environments, Simulations, Structural equation modeling, Virtual labs",

author = "Guido Makransky and Petersen, {Gustav B{\o}g}",

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doi = "10.1016/j.compedu.2019.02.002",

language = "English",

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T2 - A structural equation modeling approach

AU - Makransky, Guido

AU - Petersen, Gustav Bøg

PY - 2019/6/1

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N2 - Virtual reality (VR) is gaining attention for having the potential to enrich students’ educational experiences. However, few studies have investigated the process of learning with VR. With the use of structural equation modeling, this study investigated the affective and cognitive factors that play a role in learning with a desktop VR simulation when pre-to post-test changes in motivation, self-efficacy, and knowledge about genetics are used as outcomes. The sample consisted of 199 university students (120 females), who learned from a desktop VR genetics simulation as a mandatory part of an undergraduate medical genetics course. The results indicated that there were two general paths by which desktop VR led to increases in the amount of learning following a VR lesson: an affective path that went through VR features, presence, intrinsic motivation, and self-efficacy; and a cognitive path that went through VR features, usability, cognitive benefits, and self-efficacy. It is concluded that learners may benefit from desktop VR simulations in which efficacious VR features and a high level of usability are emphasized.

AB - Virtual reality (VR) is gaining attention for having the potential to enrich students’ educational experiences. However, few studies have investigated the process of learning with VR. With the use of structural equation modeling, this study investigated the affective and cognitive factors that play a role in learning with a desktop VR simulation when pre-to post-test changes in motivation, self-efficacy, and knowledge about genetics are used as outcomes. The sample consisted of 199 university students (120 females), who learned from a desktop VR genetics simulation as a mandatory part of an undergraduate medical genetics course. The results indicated that there were two general paths by which desktop VR led to increases in the amount of learning following a VR lesson: an affective path that went through VR features, presence, intrinsic motivation, and self-efficacy; and a cognitive path that went through VR features, usability, cognitive benefits, and self-efficacy. It is concluded that learners may benefit from desktop VR simulations in which efficacious VR features and a high level of usability are emphasized.

KW - Desktop virtual reality

KW - Interactive learning environments

KW - Simulations

KW - Structural equation modeling

KW - Virtual labs

U2 - 10.1016/j.compedu.2019.02.002

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Investigating the process of learning with desktop virtual reality: A structural equation modeling approach

Abstract

Keywords

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