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Haptic interaction and volume modeling techniques for realistic dental simulation

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Abstract

We present haptic simulation and volume modeling techniques for a virtual dental training system. The system allows dental students to learn dental procedures and master their skills with realistic tactual feelings. It supports various dental procedures, such as dental probing, to diagnose carious lesions, drilling operation for cavity preparation, and filling the prepared cavities with amalgam. The system requires fast and stable haptic rendering and volume modeling techniques working on the virtual tooth. Collision detection and force computation are implemented on an offset surface in volumetric representation to simulate reasonable physical interactions between dental tools with a certain volume and the teeth model. To avoid discrete haptic feeling due to the gap between the fast haptic process (1 KHz) and much slower visual update frequency (30 Hz) during drilling and filling the cavities, we employed an intermediate implicit surface to be animated between the original and target surfaces. The volumetric teeth model is converted into a geometric model by an adaptive polygonization method to maintain sharp features in every visual frame. Volumetric material properties are represented by stiffness and color values to simulate the resistance and texture information depending on anatomical tissues. Finally, we made a dental workbench to register sensory modalities like visual, auditory and haptic sensation.

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References

  1. Avila, R.S., Sobierajski, L.M.: A haptic interaction method for volume visualization. IEEE Visualization Proceedings, pp. 197–204 (1996)

  2. Baerentzen, J.A.: Octree-based volume sculpting. IEEE Visualization Proceedings, pp. 9–12 (1998)

  3. Bloomenthal, J.: Introduction to Implicit surface. Morgan Kaufmann Publishers, San Francisco, CA (1997)

  4. Foskey, M., Otaduy, M.A., Lin, M.C.: ArtNova: Touch-enabled 3D model design. IEEE Virtual Reality Proceedings, pp. 119–126 (2002)

  5. SensAble Technologies Inc.: Freeform modeling system, http://www.sensable.com/freeform (1999)

  6. Galyean, T.A., Hughes, J.F.: Sculpting: an interactive volumetric modeling technique. ACM SIGGRAPH Proceedings, pp. 267–274 (1991)

  7. Hayward, V., Armstrong, B.: A new computational model of friction applied to haptic rendering. Experimental Robotics, Lect. Notes Comput. Sci. 250, 404–412 (2000)

    Google Scholar 

  8. Hua, J., Qin, H.: Haptic sculpting of volumetric implicit functions. Pacific Conference on Computer Graphics and Applications Proceedings, pp. 254–264, Tokyo (2001)

  9. Kim, L., Sukhatme, G.S., Desbrun, M.: A haptic rendering technique based on hybrid surface represenation. IEEE Comput Graph Appl, Special Issue – Haptic Rendering Beyond Visual Computing 24(2), 66–75 (2004)

    Google Scholar 

  10. Kim, L., Park, S.: A Haptic Sculpting Technique Based on Volumetric Representation. Lecture Notes in Computer Science, Vol. 3179. Springer (2004)

  11. Mauch, S.: A fast alogorithm for computing the closest point and distance transform. Technical Report at http://www.its.caltech.edu/∼sean/ (2000)

  12. McDonnell, K.T., Qin, H., Wlodarczyk, R.A.: Virtual clay: a real-time sculpting system with haptic toolkits. ACM Symposium on Interactive 3D Techniques, pp. 179–190 (2001)

  13. Pandit, S.M., Wu, M.S.: Time Series and System Analysis with Applications. John Wiley, New York (1983)

  14. Perry, R.N., Frisken, S.F.: Kizamu: A system for sculpting digital characters. ACM SIGGRAPH, pp.47–56 (2001)

  15. Petersik, A., Pflesser, B., Tiede, U., Hohne, K., Leuwer, R.: Realistic Haptic Interaction in Volume Sculpting for Surgery Simulation. Lecture Notes in Computer Science, Vol. 2673, pp. 194–202. Springer (2003)

  16. Ranta, J.F., Avile, W.A.: The virtual reality dental tranining system – simulating dental procedures for the purpose of training dental students using haptics. Fourth Phantom User Groups Workshop Proceedings, pp.73–77 (1999)

  17. Ruspini, D.C., Kolarov, K., Khatib, O.: The haptic display of complex graphical environment. ACM SIGGRAPH Proceedings, Vol. 1, pp. 295–301 (1997)

  18. Ruspini, D.C., Khatib, O.: Dynamic models for haptic rendering systems. Advances in Robot Kinematics Proceedings, pp. 523–532 (1998)

  19. Sae-Kee, B., Riener, R., Frey, M., Proll, T., Burgkart, R.: Phantom-based interactive simulation system for dental treatment training. Annual Medicine Meet Virtual Reality (2004)

  20. SkyScan: microtomography, nanotomography, 3D x-ray microschopy, http://www.skyscan.be/

  21. Wiegand, E.T., Schloerb, W.D., Sachtler, W.L., Virtual Workbench: Near-field virtual environment system with applications. Presence 8(5), 492–519 (1999)

    Google Scholar 

  22. Thomas, G., Johnson, L., Dow, S., Standford, C.: The design and testing of a force feedback dental simulator. Comput. Meth. Prog. Biomed. 64, 53–64 (2000)

    Google Scholar 

  23. Velho, L., Figureiredo, L.H.D., Gomes, J.: A unified approach for hierarchical adaptive tesselation of surfaces. ACM Trans. Graph. 18(4), 329–360 (1999)

    Google Scholar 

  24. Virtual Reality Dental Training System (VRDTS), http://www.novint.com/VRDTS.htm

  25. Zilles, C., Salisbury, J.K.: A constraint-based God-object method for haptic display. Haptic Interfaces for Virtual Environment and Teleoperator Systems Proceedings, pp. 146–150 (1994)

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Authors and Affiliations

  1. Korea Institute of Science and Technology, Korea

    Laehyun Kim & Se Hyung Park

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  1. Laehyun Kim
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  2. Se Hyung Park
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Correspondence to Laehyun Kim.

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Kim, L., Park, S. Haptic interaction and volume modeling techniques for realistic dental simulation. Visual Comput 22, 90–98 (2006). https://doi.org/10.1007/s00371-006-0369-8

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  • DOI: https://doi.org/10.1007/s00371-006-0369-8

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