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Using Deformations for Browsing Volumetric Data

Authors:

Michael J. McGuffin,

Ravin BalakrishnanAuthors Info & Claims

VIS '03: Proceedings of the 14th IEEE Visualization 2003 (VIS'03)

Page 53

https://doi.org/10.1109/VISUAL.2003.1250400

Published: 22 October 2003 Publication History

Abstract

Many traditional techniques for "looking inside" volumetric data involve removing portions of the data, for example using various cutting tools, to reveal the interior. This allows the user to see hidden parts of the data, but has the disadvantage of removing potentially important surrounding contextual information. We explore an alternate strategy for browsing that uses deformations, where the user can cut into and open up, spread apart, or peel away parts of the volume in real time, making the interior visible while still retaining surrounding context. We consider various deformation strategies and present a number of interaction techniques based on different metaphors. Our designs pay special attention to the semantic layers that might compose a volume (e.g. the skin, muscle, bone in a scan of a human). Users can apply deformations to only selected layers, or apply a given deformation to a different degree to each layer, making browsing more flexible and facilitating the visualization of relationships between layers. Our interaction techniques are controlled with direct, "in place" manipulation, using pop-up menus and 3D widgets, to avoid the divided attention and awkwardness that would come with panels of traditional widgets. Initial user feedback indicates that our techniques are valuable, especially for showing portions of the data spatially situated in context with surrounding data.

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Published In

cover image Guide Proceedings

VIS '03: Proceedings of the 14th IEEE Visualization 2003 (VIS'03)

October 2003

664 pages

ISBN:0769520308

Publisher

IEEE Computer Society

United States

Publication History

Published: 22 October 2003

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Cited By

Franz RJunuzovic SMott M(2024)A Virtual Reality Scene Taxonomy: Identifying and Designing Accessible Scene-Viewing TechniquesACM Transactions on Computer-Human Interaction10.1145/363514231:2(1-44)Online publication date: 5-Feb-2024
https://dl.acm.org/doi/10.1145/3635142
Pooryousef VCordeil MBesançon LHurter CDwyer TBassed R(2023)Working with Forensic Practitioners to Understand the Opportunities and Challenges for Mixed-Reality Digital AutopsyProceedings of the 2023 CHI Conference on Human Factors in Computing Systems10.1145/3544548.3580768(1-15)Online publication date: 19-Apr-2023
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Bhardwaj AChae JNoeske RKim J(2021)TangibleData: Interactive Data Visualization with Mid-Air HapticsProceedings of the 27th ACM Symposium on Virtual Reality Software and Technology10.1145/3489849.3489890(1-11)Online publication date: 8-Dec-2021
https://dl.acm.org/doi/10.1145/3489849.3489890
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