%0 Journal Article %1 Kerwin:2009:IEEE-Trans-Vis-Comput-Graph:19590102 %A Kerwin, T %A Shen, H W %A Stredney, D %D 2009 %J IEEE Trans Vis Comput Graph %K ohio t-vr-sim %N 5 %P 747-758 %R 10.1109/TVCG.2009.31 %T Enhancing realism of wet surfaces in temporal bone surgical simulation %U http://www.ncbi.nlm.nih.gov.ep.fjernadgang.kb.dk/pubmed/?term=Enhancing+Realism+of+Wet+Surfaces+in+Temporal+Bone+Surgical+Simulation %V 15 %X We present techniques to improve visual realism in an interactive surgical simulation application: a mastoidectomy simulator that offers a training environment for medical residents as a complement to using a cadaver. As well as displaying the mastoid bone through volume rendering, the simulation allows users to experience haptic feedback and appropriate sound cues while controlling a virtual bone drill and suction/irrigation device. The techniques employed to improve realism consist of a fluid simulator and a shading model. The former allows for deformable boundaries based on volumetric bone data, while the latter gives a wet look to the rendered bone to emulate more closely the appearance of the bone in a surgical environment. The fluid rendering includes bleeding effects, meniscus rendering, and refraction. We incorporate a planar computational fluid dynamics simulation into our three-dimensional rendering to effect realistic blood diffusion. Maintaining real-time performance while drilling away bone in the simulation is critical for engagement with the system.

@article{Kerwin:2009:IEEE-Trans-Vis-Comput-Graph:19590102, abstract = {We present techniques to improve visual realism in an interactive surgical simulation application: a mastoidectomy simulator that offers a training environment for medical residents as a complement to using a cadaver. As well as displaying the mastoid bone through volume rendering, the simulation allows users to experience haptic feedback and appropriate sound cues while controlling a virtual bone drill and suction/irrigation device. The techniques employed to improve realism consist of a fluid simulator and a shading model. The former allows for deformable boundaries based on volumetric bone data, while the latter gives a wet look to the rendered bone to emulate more closely the appearance of the bone in a surgical environment. The fluid rendering includes bleeding effects, meniscus rendering, and refraction. We incorporate a planar computational fluid dynamics simulation into our three-dimensional rendering to effect realistic blood diffusion. Maintaining real-time performance while drilling away bone in the simulation is critical for engagement with the system.}, added-at = {2013-04-09T09:53:55.000+0200}, author = {Kerwin, T and Shen, H W and Stredney, D}, biburl = {https://www.bibsonomy.org/bibtex/2a1f3fb2948ee39f04f4f4ee86a9cf36f/stevenarild}, description = {Enhancing realism of wet... [IEEE Trans Vis Comput Graph. 2009 Sep-Oct] - PubMed - NCBI}, doi = {10.1109/TVCG.2009.31}, interhash = {1695eb3555ec96d5435572a93aa49053}, intrahash = {a1f3fb2948ee39f04f4f4ee86a9cf36f}, journal = {IEEE Trans Vis Comput Graph}, keywords = {ohio t-vr-sim}, month = {Sep-Oct}, number = 5, pages = {747-758}, pmid = {19590102}, timestamp = {2013-04-10T09:41:47.000+0200}, title = {Enhancing realism of wet surfaces in temporal bone surgical simulation}, url = {http://www.ncbi.nlm.nih.gov.ep.fjernadgang.kb.dk/pubmed/?term=Enhancing+Realism+of+Wet+Surfaces+in+Temporal+Bone+Surgical+Simulation}, volume = 15, year = 2009 }