Augmented Reality versus Virtual Reality for 3D Object Manipulation

Virtual Reality (VR) Head-Mounted Displays (HMDs) are on the verge of becoming commodity hardware available to the average user and feasible to use as a tool for 3D work. Some HMDs include front-facing cameras, enabling Augmented Reality (AR) functionality. Apart from avoiding collisions with the en...

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Vydáno v:	IEEE transactions on visualization and computer graphics Ročník 24; číslo 2; s. 1038 - 1048
Hlavní autoři:	Krichenbauer, Max, Yamamoto, Goshiro, Taketom, Takafumi, Sandor, Christian, Kato, Hirokazu
Médium:	Journal Article
Jazyk:	angličtina
Vydáno:	United States IEEE 01.02.2018 The Institute of Electrical and Electronics Engineers, Inc. (IEEE)
Témata:	and virtual realities-multimedia information systems-information interfaces and representation Artificial augmented Augmented reality Completion time Helmet mounted displays interaction techniques-methodology and techniques-computer graphics Mice Mouse devices Performance evaluation Production scheduling Resists Three-dimensional displays Training Virtual environments Virtual reality Visualization
ISSN:	1077-2626, 1941-0506, 1941-0506
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Abstract	Virtual Reality (VR) Head-Mounted Displays (HMDs) are on the verge of becoming commodity hardware available to the average user and feasible to use as a tool for 3D work. Some HMDs include front-facing cameras, enabling Augmented Reality (AR) functionality. Apart from avoiding collisions with the environment, interaction with virtual objects may also be affected by seeing the real environment. However, whether these effects are positive or negative has not yet been studied extensively. For most tasks it is unknown whether AR has any advantage over VR. In this work we present the results of a user study in which we compared user performance measured in task completion time on a 9 degrees of freedom object selection and transformation task performed either in AR or VR, both with a 3D input device and a mouse. Our results show faster task completion time in AR over VR. When using a 3D input device, a purely VR environment increased task completion time by 22.5 percent on average compared to AR (<inline-formula> <tex-math notation="LaTeX">{p}<0.024</tex-math> <inline-graphic xlink:href="krichenbauer-ieq1-2658570.gif"/> </inline-formula>). Surprisingly, a similar effect occurred when using a mouse: users were about 17.3 percent slower in VR than in AR (<inline-formula> <tex-math notation="LaTeX">{p}<0.04</tex-math> <inline-graphic xlink:href="krichenbauer-ieq2-2658570.gif"/> </inline-formula>). Mouse and 3D input device produced similar task completion times in each condition (AR or VR) respectively. We further found no differences in reported comfort.
AbstractList	Virtual Reality (VR) Head-Mounted Displays (HMDs) are on the verge of becoming commodity hardware available to the average user and feasible to use as a tool for 3D work. Some HMDs include front-facing cameras, enabling Augmented Reality (AR) functionality. Apart from avoiding collisions with the environment, interaction with virtual objects may also be affected by seeing the real environment. However, whether these effects are positive or negative has not yet been studied extensively. For most tasks it is unknown whether AR has any advantage over VR. In this work we present the results of a user study in which we compared user performance measured in task completion time on a 9 degrees of freedom object selection and transformation task performed either in AR or VR, both with a 3D input device and a mouse. Our results show faster task completion time in AR over VR. When using a 3D input device, a purely VR environment increased task completion time by 22.5 percent on average compared to AR (<inline-formula> <tex-math notation="LaTeX">{p}<0.024</tex-math> <inline-graphic xlink:href="krichenbauer-ieq1-2658570.gif"/> </inline-formula>). Surprisingly, a similar effect occurred when using a mouse: users were about 17.3 percent slower in VR than in AR (<inline-formula> <tex-math notation="LaTeX">{p}<0.04</tex-math> <inline-graphic xlink:href="krichenbauer-ieq2-2658570.gif"/> </inline-formula>). Mouse and 3D input device produced similar task completion times in each condition (AR or VR) respectively. We further found no differences in reported comfort. Virtual Reality (VR) Head-Mounted Displays (HMDs) are on the verge of becoming commodity hardware available to the average user and feasible to use as a tool for 3D work. Some HMDs include front-facing cameras, enabling Augmented Reality (AR) functionality. Apart from avoiding collisions with the environment, interaction with virtual objects may also be affected by seeing the real environment. However, whether these effects are positive or negative has not yet been studied extensively. For most tasks it is unknown whether AR has any advantage over VR. In this work we present the results of a user study in which we compared user performance measured in task completion time on a 9 degrees of freedom object selection and transformation task performed either in AR or VR, both with a 3D input device and a mouse. Our results show faster task completion time in AR over VR. When using a 3D input device, a purely VR environment increased task completion time by 22.5 percent on average compared to AR ( ). Surprisingly, a similar effect occurred when using a mouse: users were about 17.3 percent slower in VR than in AR ( ). Mouse and 3D input device produced similar task completion times in each condition (AR or VR) respectively. We further found no differences in reported comfort.Virtual Reality (VR) Head-Mounted Displays (HMDs) are on the verge of becoming commodity hardware available to the average user and feasible to use as a tool for 3D work. Some HMDs include front-facing cameras, enabling Augmented Reality (AR) functionality. Apart from avoiding collisions with the environment, interaction with virtual objects may also be affected by seeing the real environment. However, whether these effects are positive or negative has not yet been studied extensively. For most tasks it is unknown whether AR has any advantage over VR. In this work we present the results of a user study in which we compared user performance measured in task completion time on a 9 degrees of freedom object selection and transformation task performed either in AR or VR, both with a 3D input device and a mouse. Our results show faster task completion time in AR over VR. When using a 3D input device, a purely VR environment increased task completion time by 22.5 percent on average compared to AR ( ). Surprisingly, a similar effect occurred when using a mouse: users were about 17.3 percent slower in VR than in AR ( ). Mouse and 3D input device produced similar task completion times in each condition (AR or VR) respectively. We further found no differences in reported comfort. Virtual Reality (VR) Head-Mounted Displays (HMDs) are on the verge of becoming commodity hardware available to the average user and feasible to use as a tool for 3D work. Some HMDs include front-facing cameras, enabling Augmented Reality (AR) functionality. Apart from avoiding collisions with the environment, interaction with virtual objects may also be affected by seeing the real environment. However, whether these effects are positive or negative has not yet been studied extensively. For most tasks it is unknown whether AR has any advantage over VR. In this work we present the results of a user study in which we compared user performance measured in task completion time on a 9 degrees of freedom object selection and transformation task performed either in AR or VR, both with a 3D input device and a mouse. Our results show faster task completion time in AR over VR. When using a 3D input device, a purely VR environment increased task completion time by 22.5 percent on average compared to AR ([Formula Omitted]). Surprisingly, a similar effect occurred when using a mouse: users were about 17.3 percent slower in VR than in AR ([Formula Omitted]). Mouse and 3D input device produced similar task completion times in each condition (AR or VR) respectively. We further found no differences in reported comfort. Virtual Reality (VR) Head-Mounted Displays (HMDs) are on the verge of becoming commodity hardware available to the average user and feasible to use as a tool for 3D work. Some HMDs include front-facing cameras, enabling Augmented Reality (AR) functionality. Apart from avoiding collisions with the environment, interaction with virtual objects may also be affected by seeing the real environment. However, whether these effects are positive or negative has not yet been studied extensively. For most tasks it is unknown whether AR has any advantage over VR. In this work we present the results of a user study in which we compared user performance measured in task completion time on a 9 degrees of freedom object selection and transformation task performed either in AR or VR, both with a 3D input device and a mouse. Our results show faster task completion time in AR over VR. When using a 3D input device, a purely VR environment increased task completion time by 22.5 percent on average compared to AR ( ). Surprisingly, a similar effect occurred when using a mouse: users were about 17.3 percent slower in VR than in AR ( ). Mouse and 3D input device produced similar task completion times in each condition (AR or VR) respectively. We further found no differences in reported comfort.
Author	Yamamoto, Goshiro Sandor, Christian Taketom, Takafumi Kato, Hirokazu Krichenbauer, Max
Author_xml	– sequence: 1 givenname: Max orcidid: 0000-0003-2720-2342 surname: Krichenbauer fullname: Krichenbauer, Max email: max-k@is.naist.jp organization: Department of Information Science, Nara Sentan Kagaku Gijutsu Daigakuin Daigaku, Ikoma, Nara, Japan – sequence: 2 givenname: Goshiro surname: Yamamoto fullname: Yamamoto, Goshiro email: goshiro@is.naist.jp organization: Department of Interactive Media Design Laboratory, Nara Institute of Science and Technology, Ikoma, Nara, Japan – sequence: 3 givenname: Takafumi surname: Taketom fullname: Taketom, Takafumi email: takafumi-t@is.naist.jp organization: Department of Interactive Media Design Laboratory, Nara Institute of Science and Technology, Ikoma, Nara, Japan – sequence: 4 givenname: Christian surname: Sandor fullname: Sandor, Christian email: sandor@is.naist.jp organization: Department of Interactive Media Design Laboratory, Nara Institute of Science and Technology, Ikoma, Nara, Japan – sequence: 5 givenname: Hirokazu surname: Kato fullname: Kato, Hirokazu email: kato@is.naist.jp organization: Graduate School of Information Science, NAIST, Ikoma, Nara, Japan
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SubjectTerms	and virtual realities-multimedia information systems-information interfaces and representation Artificial augmented Augmented reality Completion time Helmet mounted displays interaction techniques-methodology and techniques-computer graphics Mice Mouse devices Performance evaluation Production scheduling Resists Three-dimensional displays Training Virtual environments Virtual reality Visualization
Title	Augmented Reality versus Virtual Reality for 3D Object Manipulation
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