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Publications of Author

1. Stephen M. Pizer, John M. Gauch, James M. Coggins, Tim J. Cullip, Robin E. Fredericksen, Victoria Interrante
   Multiscale, Geometric Image Descriptions for Interactive Object Definition. [Citation Graph (0, 0)][DBLP]
   DAGM-Symposium, 1989, pp:229-239 [Conf]
   
2. Haleh Hagh-Shenas, Victoria Interrante
   Compositing color with texture for multi-variate visualization. [Citation Graph (0, 0)][DBLP]
   GRAPHITE, 2005, pp:443-446 [Conf]
   
3. Francesca Taponecco, Timothy Urness, Victoria Interrante
   Directional enhancement in texture-based vector field visualization. [Citation Graph (0, 0)][DBLP]
   GRAPHITE, 2006, pp:197-204 [Conf]
   
4. SungHee Kim, Haleh Hagh-Shenas, Victoria Interrante
   Conveying Shape with Texture: an experimental investigation of the impact of texture type on shape categorization judgments. [Citation Graph (0, 0)][DBLP]
   INFOVIS, 2003, pp:- [Conf]
   
5. Ahna Girshick, Victoria Interrante, Steven Haker, Todd Lemoine
   Line direction matters: an argument for the use of principal directions in 3D line drawings. [Citation Graph (0, 0)][DBLP]
   NPAR, 2000, pp:43-52 [Conf]
   
6. Victoria Interrante
   Illustrating surface shape in volume data via principal direction-driven 3D line integral convolution. [Citation Graph (0, 0)][DBLP]
   SIGGRAPH, 1997, pp:109-116 [Conf]
   
7. Timothy Urness, Victoria Interrante, Ellen Longmire, Ivan Marusic, Bharathram Ganapathisubramani
   Techniques for Visualizing Multi-Valued Flow Data. [Citation Graph (0, 0)][DBLP]
   VisSym, 2004, pp:165-172 [Conf]
   
8. Dirk Bartz, Hans Hagen, Victoria Interrante, Kwan-Liu Ma, Bernhard Preim
   Illustrative Rendering Techniques for Visualization: Future of Visualization or Just Another Technique?. [Citation Graph (0, 0)][DBLP]
   IEEE Visualization, 2005, pp:120- [Conf]
   
9. Donald H. House, Victoria Interrante, David H. Laidlaw, Russell M. Taylor II, Colin Ware
   Design and Evaluation in Visualization Research. [Citation Graph (0, 0)][DBLP]
   IEEE Visualization, 2005, pp:117- [Conf]
   
10. Victoria Interrante, Henry Fuchs, Stephen M. Pizer
    Enhancing Transparent Skin Surfaces with Ridge and Valley Lines. [Citation Graph (0, 0)][DBLP]
    IEEE Visualization, 1995, pp:52-0 [Conf]
    
11. Victoria Interrante, Henry Fuchs, Stephen M. Pizer
    Illustrating Transparent Surfaces with Curvature-Directed Strokes. [Citation Graph (0, 0)][DBLP]
    IEEE Visualization, 1996, pp:211-218 [Conf]
    
12. Victoria Interrante, Chester Grosch
    Strategies for effectively visualizing 3D flow with volume LIC. [Citation Graph (0, 0)][DBLP]
    IEEE Visualization, 1997, pp:421-424 [Conf]
    
13. David H. Laidlaw, David Kremers, Felica Frankel, Victoria Interrante, Thomas Banchoff
    Art and visualization: oil and water? [Citation Graph (0, 0)][DBLP]
    IEEE Visualization, 1998, pp:507-509 [Conf]
    
14. Kwan-Liu Ma, Victoria Interrante
    Extracting feature lines from 3D unstructured grids. [Citation Graph (0, 0)][DBLP]
    IEEE Visualization, 1997, pp:285-292 [Conf]
    
15. P. Coleman Saunders, Sean C. Garrick, Victoria Interrante
    Visualization of Nanoparticle Formation in Turbulent Flows. [Citation Graph (0, 0)][DBLP]
    IEEE Visualization, 2004, pp:23- [Conf]
    
16. J. Edward Swan II, Theresa-Marie Rhyne, David H. Laidlaw, Tamara Munzner, Victoria Interrante
    Visualization Needs More Visual Design! [Citation Graph (0, 0)][DBLP]
    IEEE Visualization, 1999, pp:485-490 [Conf]
    
17. Timothy Urness, Victoria Interrante, Ellen Longmire, Ivan Marusic, Bharathram Ganapathisubramani
    Interactive Poster: Illustrating Different Convection Velocities of Turbulent Flow. [Citation Graph (0, 0)][DBLP]
    IEEE Visualization, 2004, pp:24- [Conf]
    
18. Timothy Urness, Victoria Interrante, Ivan Marusic, Ellen Longmire, Bharathram Ganapathisubramani
    Effectively Visualizing Multi-Valued Flow Data Using Color and Texture. [Citation Graph (0, 0)][DBLP]
    IEEE Visualization, 2003, pp:115-121 [Conf]
    
19. Victoria Interrante
    Harnessing Natural Textures for Multivariate Visualization. [Citation Graph (0, 0)][DBLP]
    IEEE Computer Graphics and Applications, 2000, v:20, n:6, pp:6-11 [Journal]
    
20. Robert Kosara, Christopher G. Healey, Victoria Interrante, David H. Laidlaw, Colin Ware
    User Studies: Why, How, and When? [Citation Graph (0, 0)][DBLP]
    IEEE Computer Graphics and Applications, 2003, v:23, n:4, pp:20-25 [Journal]
    
21. Timothy Urness, Victoria Interrante, Ellen Longmire, Ivan Marusic, Sean O'Neill, Thomas W. Jones
    Strategies for the Visualization of Multiple 2D Vector Fields. [Citation Graph (0, 0)][DBLP]
    IEEE Computer Graphics and Applications, 2006, v:26, n:4, pp:74-82 [Journal]
    
22. Victoria Interrante
    Guest Editorial. [Citation Graph (0, 0)][DBLP]
    TAP, 2006, v:3, n:3, pp:153-154 [Journal]
    
23. Jack Goldfeather, Victoria Interrante
    A novel cubic-order algorithm for approximating principal direction vectors. [Citation Graph (0, 0)][DBLP]
    ACM Trans. Graph., 2004, v:23, n:1, pp:45-63 [Journal]
    
24. Gabriele Gorla, Victoria Interrante, Guillermo Sapiro
    Texture Synthesis for 3D Shape Representation. [Citation Graph (0, 0)][DBLP]
    IEEE Trans. Vis. Comput. Graph., 2003, v:9, n:4, pp:512-524 [Journal]
    
25. Victoria Interrante, Henry Fuchs, Stephen M. Pizer
    Conveying the 3D Shape of Smoothly Curving Transparent Surfaces via Texture. [Citation Graph (0, 0)][DBLP]
    IEEE Trans. Vis. Comput. Graph., 1997, v:3, n:2, pp:98-117 [Journal]
    
26. SungHee Kim, Haleh Hagh-Shenas, Victoria Interrante
    Conveying Shape with Texture: Experimental Investigations of Texture's Effects on Shape Categorization Judgments. [Citation Graph (0, 0)][DBLP]
    IEEE Trans. Vis. Comput. Graph., 2004, v:10, n:4, pp:471-483 [Journal]
    
27. P. Coleman Saunders, Victoria Interrante, Sean C. Garrick
    Pointillist and Glyph-based Visualization of Nanoparticles in Formation. [Citation Graph (0, 0)][DBLP]
    EuroVis, 2005, pp:169-176 [Conf]
    
28. Haleh Hagh-Shenas, SungHee Kim, Victoria Interrante, Christopher G. Healey
    Weaving Versus Blending: a quantitative assessment of the information carrying capacities of two alternative methods for conveying multivariate data with color. [Citation Graph (0, 0)][DBLP]
    IEEE Trans. Vis. Comput. Graph., 2007, v:13, n:6, pp:1270-1277 [Journal]
    
29. 
    Elucidating Factors that can Facilitate Veridical Spatial Perception in Immersive Virtual Environments. [Citation Graph (, )][DBLP]
    
    
30. 
    Spatial Perception in Immersive Virtual Environments: New Theories and Current Controversies. [Citation Graph (, )][DBLP]
    
    
31. 
    Avatar self-embodiment enhances distance perception accuracy in non-photorealistic immersive virtual environments. [Citation Graph (, )][DBLP]
    
    
32. 
    The effect of self-embodiment on distance perception in immersive virtual environments. [Citation Graph (, )][DBLP]
    
    
33. 
    Analyzing the effect of a virtual avatar's geometric and motion fidelity on ego-centric spatial perception in immersive virtual environments. [Citation Graph (, )][DBLP]
    
    
34. 
    Experimental investigations into the feasibility of using augmented walking to facilitate the intuitive exploration of large scale immersive virtual environments. [Citation Graph (, )][DBLP]
    
    
35. 
    An experimental investigation of distance perception in real vs. immersive virtual environments via direct blind walking in a high-fidelity model of the same room. [Citation Graph (, )][DBLP]
    
    
36. 
    Conveying three-dimensional shape with texture. [Citation Graph (, )][DBLP]
    
    
37. 
    A closer look at texture metrics. [Citation Graph (, )][DBLP]
    
    
38. 
    Presence, rather than prior exposure, is the more strongly indicated factor in the accurate perception of egocentric distances in real world co-located immersive virtual environments. [Citation Graph (, )][DBLP]
    
    
39. 
    Weaving versus blending: a quantitative assessment of the information carrying capacities of two alternative methods for conveying multivariate data with color. [Citation Graph (, )][DBLP]
    
    
40. 
    Distance perception in NPR immersive virtual environments, revisited. [Citation Graph (, )][DBLP]
    
    
41. 
    Transitional environments enhance distance perception in immersive virtual reality systems. [Citation Graph (, )][DBLP]
    
    
42. 
    Multivariate visualization of 3D turbulent flow data. [Citation Graph (, )][DBLP]
    
    
43. 
    Computational Aesthetics 08. [Citation Graph (, )][DBLP]
    
    
44. 
    FieldVis: A Tool for Visualizing Astrophysical Magnetohydrodynamic Flow. [Citation Graph (, )][DBLP]
    
    
45. 
    Visualizing 3D Flow. [Citation Graph (, )][DBLP]