Frank Dachille
- 1.U. Behrens and R. Ratering. Adding shadows to a texturebased volume renderer. In 1998 Symposium on Volume Visualization, pages 39-46. IEEE, ACM SIGGRAPH, 1998. Google Scholar
Digital Library
- 2.B. Cabral, N. Cam, and J. Foran. Accelerated volume rendering and tomographic reconstruction using texture mapping hardware. In 1994 Symposium on Volume Visualization, pages 91-98. ACM SIGGRAPH, Oct. 1994. Google ScholarDigital Library
- 3.M. F. Cohen, S. E. Chen, J. R. Wallace, and D. P. Greenberg. A progressive refinement approach to fast radiosity image generation. In J. Dill, editor, Computer Graphics (SIG- GRAPH '88 Proceedings), volume 22, pages 75-84, Aug. 1988. Google ScholarDigital Library
- 4.J. Dorsey, A. Edelman, H. W. Jensen, J. Legakis, and H. K. Pedersen. Modeling and rendering of weathered stone. Proceedings of SIGGRAPH 1999, pages 225-234, Aug. 1999. Google ScholarDigital Library
- 5.P. Hanrahan and W. Krueger. Reflection from layered surfaces due to subsurface scattering. In Computer Graphics (SIG- GRAPH '93 Proceedings), volume 27, pages 165-174, Aug. 1993. Google ScholarDigital Library
- 6.H. W. Jensen and P. H. Christensen. Efficient simulation of light transport in scenes with participating media using photon maps. In SIGGRAPH 98 Conference Proceedings, Annual Conference Series, pages 311-320, July 1998. Google ScholarDigital Library
- 7.J. T. Kajiya and B. P. Von Herzen. Ray tracing volume densities. In Computer Graphics (SIGGRAPH '84 Proceedings), volume 18, pages 165-174, July 1984. Google ScholarDigital Library
- 8.A. Keller. Quasi-monte carlo radiosity. In X. Pueyo and P. Schr~der, editors, Eurographics Rendering Workshop 1996, pages 101-110. Springer Wein, June 1996. Google ScholarDigital Library
- 9.A. Keller. Instant radiosity. In SIGGRAPH 97 Conference Proceedings, Annual Conference Series, pages 49-56, Aug. 1997. Google ScholarDigital Library
- 10.K. Kreeger, I. Bitter, F. Dachille, B. Chen, and A. Kaufman. Adaptive perspective ray casting. In IEEE Symposium on Volume Visualization, pages 55-62. IEEE, ACM SIGGRAPH, 1998. Google ScholarDigital Library
- 11.K. N. Kutulakos and S. M. Seitz. A theory of shape by space carving. Technical Report 692, Computer Science Dept., University of Rochester, Rochester, New York, May 1998. Google ScholarDigital Library
- 12.M. Levoy. Display of surfaces from volume data. IEEE Computer Graphics and Applications, 8(3):29-37, May 1988. Google ScholarDigital Library
- 13.N. Max. Optical models for direct volume rendering. IEEE Transactions on Visualization and Computer Graphics, 1(2):99-108, June 1995. Google ScholarDigital Library
- 14.H.-P. Meinzer, K. Meetz, D. Scheppelmann, U. Engelmann, and H. J. Baur. The Heidelberg ray tracing model. IEEE Computer Graphics and Applications, 11(6):34-43, Nov. 1991. Google ScholarDigital Library
- 15.K. Mueller and R. Yagel. On the use of graphics hardware to accelerate algebraic reconstruction methods. In Proceedings of SPIE Medical Imaging Conference 1999, number 3659-62, San Diego, CA, Feb.Google Scholar
- 16.H. Pfister, J. Hardenbergh, J. Knittel, H. Lauer, and L. Seiler. The VolumePro real-time ray-casting system. Proceedings of SIGGRAPH 1999, pages 251-260, Aug. 1999. Google ScholarDigital Library
- 17.H. Pfister and A. E. Kaufman. Cube-4 - A scalable architecture for real-time volume rendering. In 1996 Volume Visualization Symposium, pages 47-54. IEEE, Oct. 1996. Google ScholarDigital Library
- 18.H. E. Rushmeier and K. E. Torrance. The zonal method for calculating light intensities in the presence of a participating medium. In Computer Graphics (SIGGRAPH '87 Proceedings), volume 21, pages 293-302, July 1987. Google ScholarDigital Library
- 19.S. Seitz and C. Dyer. Photorealistic scene reconstruction by voxel coloring. International Journal of Computer Vision, 25(3), November 1999. Google ScholarDigital Library
- 20.L. Sobierajski and A. Kaufman. Volumetric ray tracing. In 1994 Symposium on Volume Visualization, pages 11-18. ACM SIGGRAPH, Oct. 1994. Google ScholarDigital Library
- 21.L. M. Sobierajski. Global Illumination Models for Volume Rendering. Ph.D. thesis, Stony Brook, NY, Aug. 1994. Google ScholarDigital Library
- 22.L. Szirmay-Kalos and W. Purgathofer. Global ray-bundle tracing with hardware acceleration. In Rendering Techniques '98 (Proceedings of Eurographics Rendering Workshop '98), pages 247-258, 1998.Google ScholarCross Ref
Index Terms
- Volumetric backprojection
Recommendations
Image-based rendering of diffuse, specular and glossy surfaces from a single image
SIGGRAPH '01: Proceedings of the 28th annual conference on Computer graphics and interactive techniquesIn this paper, we present a new method to recover an approximation of the bidirectional reflectance distribution function (BRDF) of the surfaces present in a real scene. This is done from a single photograph and a 3D geometric model of the scene. The ...
The State of the Art in Interactive Global Illumination
The interaction of light and matter in the world surrounding us is of striking complexity and beauty. Since the very beginning of computer graphics, adequate modelling of these processes and efficient computation is an intensively studied research topic ...
Approximating dynamic global illumination in image space
I3D '09: Proceedings of the 2009 symposium on Interactive 3D graphics and gamesPhysically plausible illumination at real-time framerates is often achieved using approximations. One popular example is ambient occlusion (AO), for which very simple and efficient implementations are used extensively in production. Recent methods ...
Comments