Multi-touch 3D exploratory analysis of ocean flow models

Modern ocean flow simulations are generating increasingly complex, multi-layer 3D ocean flow models. However, most researchers are still using traditional 2D visualizations to visualize these models one slice at a time. Properly designed 3D visualization tools can be highly effective for revealing the complex, dynamic flow patterns and structures present in these models. However, the transition from visualizing ocean flow patterns in 2D to 3D presents many challenges, including occlusion and depth ambiguity. Further complications arise from the interaction methods required to navigate, explore, and interact with these 3D datasets. We present a system that employs a combination of stereoscopic rendering, to best reveal and illustrate 3D structures and patterns, and multi-touch interaction, to allow for natural and efficient navigation and manipulation within the 3D environment. Exploratory visual analysis is facilitated through the use of a highly-interactive toolset which leverages a smart particle system. Multi-touch gestures allow users to quickly position dye emitting tools within the 3D model. Finally, we illustrate the potential applications of our system through examples of real world significance.

[1]  Steven P. Williams,et al.  New computational control techniques and increased understanding for stereo 3-D displays , 1990, Other Conferences.

[2]  M. Weiser,et al.  An empirical comparison of pie vs. linear menus , 1988, CHI '88.

[3]  Robert S. lramee,et al.  Interactive 3D flow visualization using a streamrunner , 2002, CHI Extended Abstracts.

[4]  Colin Ware,et al.  Strokes for Representing Univariate Vector Field Maps , 1989 .

[5]  Anton L. Fuhrmann,et al.  Real-time techniques for 3D flow visualization , 1998, Proceedings Visualization '98 (Cat. No.98CB36276).

[6]  Bengt Ahlström,et al.  Overcoming touchscreen user fatigue by workplace design , 1992, CHI '92.

[7]  Tovi Grossman,et al.  The design and evaluation of selection techniques for 3D volumetric displays , 2006, UIST.

[8]  Colin Ware,et al.  Haptic-GeoZui3D: Exploring the Use of Haptics in AUV Path Planning , 2003 .

[9]  Laurent Grisoni,et al.  The design and evaluation of 3D positioning techniques for multi-touch displays , 2010, 2010 IEEE Symposium on 3D User Interfaces (3DUI).

[10]  Daniel F. Keefe,et al.  Particle flurries , 2004, IEEE Computer Graphics and Applications.

[11]  S. Martin,et al.  A system for visualizing time varying oceanographic 3D data , 2004, Oceans '04 MTS/IEEE Techno-Ocean '04 (IEEE Cat. No.04CH37600).

[12]  Mike Wu,et al.  Gesture registration, relaxation, and reuse for multi-point direct-touch surfaces , 2006, First IEEE International Workshop on Horizontal Interactive Human-Computer Systems (TABLETOP '06).

[13]  Patrick Baudisch,et al.  Precise selection techniques for multi-touch screens , 2006, CHI.

[14]  Andrew Sears,et al.  Improving Touchscreen Keyboards: Design Issues and a Comparison with Other Devices , 1991, Interact. Comput..

[15]  M. Sheelagh T. Carpendale,et al.  Sticky tools: full 6DOF force-based interaction for multi-touch tables , 2009, ITS '09.

[16]  Kwan-Liu Ma,et al.  Virtual Smoke: an interactive 3D flow visualization technique , 1992, Proceedings Visualization '92.

[17]  Stephen Schaeffer An augmented haptic interface as applied to flow visualization , 2007 .