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References
C. L. Bajaj, V. Pascucci, and D. R. Schikore. The contour spectrum. In Proc. of IEEE Visualzation’ 97, pp. 167–173, 1997.
S. Castro, A. König, H. Löffelmann, and E. Gröller. Transfer function specification for the visualization of medical data. Technical Report TR-186-2-98-12, Vienna University of Technology, 1998. [http://www.cg.tuwien.ac.at/research/TR/98/TR-186-2-98-12Abstract.html].
B. Csébfalvi, L. Mroz, H. Hauser, A. König, and E. Gröller. Fast visualization of object contours by non-photorealistic volume rendering. Computer Graphics Forum, 20(3):452–460, 2001.
D. Cohen-Or, Y. Chrysanthou, C. Silva, and G. Drettakis. Visibility, problems, techniques and applications. Siggraph’ 00 Course Notes, 2000.
H. Carr, J. Snoeyink, and U. Axen. Computing contour trees in all dimensions. Computational Geometry, 24(2):75–94, 2003.
I. Fujishiro, T. Azuma, and Y. Takeshima. Automating transfer function design for comprehensive rendering based on 3D field topology analysis. In Proc. of IEEE Visualization’ 99, pp. 467–470, 563, 1999.
I. Fujishiro, T. Azuma, Y. Takeshima, and S. Takahashi. Volume data mining using 3D field topology analysis. IEEE Computer Graphics & Applications, 20(5):46–51, 2000.
A. T. Fomenko and T. L. Kunii. Topological Modeling for Visualization, chapter 6, pp. 105–125. Springer-Verlag, 1997.
I. Fujishiro, Y. Maeda, and H. Sato. Interval volume: A solid fitting technique for volumetric data display and analysis. In Proc. of IEEE Visualization’ 95, pp. 151–158, CP-18, 1995.
I. Fujishiro, Y. Maeda, H. Sato, and Y. Takeshima. Volumetric data exploration using interval volume. IEEE Transactions on Visualization and Computer Graphics, 2(2):144–155, 1996.
I. Fujishiro, Y. Takeshima, S. Takahashi, and Y. Yamaguchi. Topologically-accentuated volume rendering. In F. H. Post, G. M. Nielson, and G.-P. Bonneau, editors, Data Visualization: The State of the Art, pp. 95–108. Kluwer Academic Publishes, 2002.
J. Hladůvka, A. König, and E. Gröller. Curvature-based transfer functions for direct volume rendering. In Proc. of Spring Conference on Computer Graphics 2000, pp. 58–65, 2000.
V. L. Interrante. Illustrating surface shape in volume data via principal direction-driven 3D line integral convolution. In Computer Graphics (Proc. of Siggraph’ 97), pp. 109–116, 1997.
G. Kindlmann and J. W. Durkin. Semi-automatic generation of transfer functions for direct volume rendering. In Proc. of IEEE Symposium on Volume Visualization, pp. 79–86, 1998.
J. Kniss, G. Kindlmann, and C. Hansen. Interactive volume rendering using multidimensional transfer functions and direct manipulation widgets. In Proc. of IEEE Visualization 2001, pp. 255–262, 2001.
J. Kniss, G. Kindlmann, and C. Hansen. Multidimensional transfer functions for interactive volume rendering. IEEE Transactions on Visualization and Computer Graphics, 8(3):270–285, 2002.
J. T. Klosowski and C. T. Silva. The prioritized-layered projection algorithm for visible set estimation. IEEE Transactions on Visualization and Computer Graphics,6(2):108–123, 2000.
M. Levoy. Display of surfaces form volume data. IEEE Computer Graphics & Applications, 8(5):29–27, 1988.
A. Lu, C. J. Morris, D. S. Ebert, P. Rheingans, and C. Hansen. Non-photorealistic volume rendering using stippling techniques. In Proc. of IEEE Visualization 2002, pp. 211–218, 2002.
M. Meißner. Web Page [http://www.volvis.org/].
G. M. Nielson and B. Hamann. The asymptotic decider: Removing the ambiguity in marching cubes. In Proc. of IEEE Visualization’ 91, pp. 83–91, 1991.
V. Pascucci and K. Cole-McLaughlin. Efficient computation of the topology of level sets. In Proc. of IEEE Visualization 2002, pp. 187–194, 2002.
P. Rheingans and D. Ebert. Volume illustration: Nonphotorealistic rendering of volume models. IEEE Transactions on Visualization and Computer Graphics, 7(3):253–264, 2001.
G. Schaufler, J. Dorsey, X. Decoret, and F. X. Sillion. Conservative volumetric visibility with occluder fusion. In Computer Graphics (Proc. of Siggraph’ 00), pp. 229–238, 2000.
Y. Shinagawa, Y. L. Kergosien, and T. L. Kunii. Surface coding based on morse theory. IEEE Computer Graphics & Applications, 11(5):66–78, 1991.
R. Suzuki, H. Sato, and M. Kimura. Antiproton-Hydrogen atom collision at intermediate energy. IEEE Computing in Science and Engineering, 4(6):24–33, 2002.
S. Treavett and M. Chen. Pen-and-ink rendering in volume visualization. In Proc. of IEEE Visualization 2000, pp. 203–210, 2000.
S. Takahashi, T. Ikeda, Y. Shinagawa, T. L. Kunii, and M. Ueda. Algorithms for extracting correct critical points and constructing topological graphs from discrete geographical elevation data. Computer Graphics Forum, 14(3):181–192, 1995.
S. Takahashi, G. M. Nielson, Y. Takeshima, and I. Fujishiro. Topological volume skeletonization using adaptive tetrahedralization. In Proc. of Geometric Modeling and Processing 2004, pp. 227–236, 2004.
S. Takahashi, Y. Shinagawa, and T. L. Kunii. A feature-based approach for smooth surfaces. In Proc. of the ACM 4th Symposium on Solid Modeling and Applications, pp. 97–110, 1997.
S. Takahashi, Y. Takeshima, and I. Fujishiro. Topological volume skeletonization and its application to transfer function design. Graphical Models, 66(1):24–49, 2004.
M. van Kreveld, R. van Oostrum, C. Bajaj, V. Pascucci, and D. Schikore. Contour trees and small seed sets for isosurface traversal. In Proc. of the 13th ACM Symposium on Computational Geometry, pp. 212–220, 1997.
G. H. Weber, G. Scheuermann, H. Hagen, and B. Hamann. Exploring scalar fields using critical isovalues. In Proc. of IEEE Visualization 2002, pp. 171–178, 2002.
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Takahashi, S., Takeshima, Y., Fujishiro, I., Nielson, G.M. (2006). Emphasizing Isosurface Embeddings in Direct Volume Rendering. In: Bonneau, GP., Ertl, T., Nielson, G.M. (eds) Scientific Visualization: The Visual Extraction of Knowledge from Data. Mathematics and Visualization. Springer, Berlin, Heidelberg. https://doi.org/10.1007/3-540-30790-7_12
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