A Review of Virtual Surgical Object Modeling Technology Based on Force Feedback

[1] David, Pinzon, Simon, et al. Prevailing Trends in Haptic Feedback Simulation for Minimally Invasive Surgery. [J]. Surgical Innovation, 2016, 23(4):415–421. David Pinzon Simon Prevailing Trends in Haptic Feedback Simulation for Minimally Invasive Surgery. [J] Surgical Innovation 2016 23 4 415 421 Search in Google Scholar

[2] Zhang Y, Luo D, Li J, et al. Study on Collision Detection and Force Feedback Algorithm in Virtual Surgery [J]. Journal of Healthcare Engineering, 2021, 2021(1):1–12. ZhangY LuoD LiJ Study on Collision Detection and Force Feedback Algorithm in Virtual Surgery [J] Journal of Healthcare Engineering 2021 2021 1 1 12 Search in Google Scholar

[3] Verstreken K, Van Cleynenbreugel J, Martens K, Marchal G, van Steenberghe D, Suetens P. An image-guided planning system for endosseous oral implants. [J]. IEEE transactions on medical imaging, 1998, 17(5). VerstrekenK Van CleynenbreugelJ MartensK MarchalG van SteenbergheD SuetensP An image-guided planning system for endosseous oral implants. [J] IEEE transactions on medical imaging 1998 17 5 Search in Google Scholar

[4] Kusumoto Naoki, Sohmura Taiji, Yamada Shinichi, Wakabayashi Kazumichi, Nakamura Takashi, Yatani Hirofumi. Application of virtual reality force feedback haptic device for oral implant surgery. [J]. Clinical oral implants research, 2006, 17(6). NaokiKusumoto TaijiSohmura ShinichiYamada KazumichiWakabayashi TakashiNakamura HirofumiYatani Application of virtual reality force feedback haptic device for oral implant surgery. [J] Clinical oral implants research 2006 17 6 Search in Google Scholar

[5] http://www.measurego.com/Force-feedback. http://www.measurego.com/Force-feedback. Search in Google Scholar

[6] Lin Y, Wang X, Wu F, et al. Development and validation of a surgical training simulator with haptic feedback for learning bone-sawing skill [J]. Journal of Biomedical Informatics, 2014, 48(2):122–129. LinY WangX WuF Development and validation of a surgical training simulator with haptic feedback for learning bone-sawing skill [J] Journal of Biomedical Informatics 2014 48 2 122 129 Search in Google Scholar

[7] Massie T H, Salisbury J K. The PHANTOM haptic interface: a device for probing virtual objects[C]// Proc. of the ASME Winter Annual Meeting, Symposium on Haptic Interfaces for Virtual Environment and Teleoperator Systems. 1994. MassieT H SalisburyJ K The PHANTOM haptic interface: a device for probing virtual objects[C] Proc. of the ASME Winter Annual Meeting, Symposium on Haptic Interfaces for Virtual Environment and Teleoperator Systems 1994 Search in Google Scholar

[8] Bogoni T, Scarparo R, Pinho M. A virtual reality simulator for training endodontics procedures using manual files. IEEE, 2015. BogoniT ScarparoR PinhoM A virtual reality simulator for training endodontics procedures using manual files IEEE 2015 Search in Google Scholar

[9] Jones M W, Satherley R. Voxelisation: Modelling for volume graphics[C]// Proceedings of the 2000 Conference on Vision Modeling and Visualization (VMV-00), Saarbrücken, Germany, November 22–24, 2000. DBLP, 2000. JonesM W SatherleyR. Voxelisation: Modelling for volume graphics[C] Proceedings of the 2000 Conference on Vision Modeling and Visualization (VMV-00) Saarbrücken, Germany November 22–24, 2000 DBLP, 2000. Search in Google Scholar

[10] K. Jayasudha, Mohan G. Kabadi. Soft tissues deformation and removal simulation modelling for virtual surgery [J]. International Journal of Intelligence and Sustainable Computing, 2020, 1(1). JayasudhaK. KabadiMohan G. Soft tissues deformation and removal simulation modelling for virtual surgery [J] International Journal of Intelligence and Sustainable Computing 2020 1 1 Search in Google Scholar

[11] Dan K, Chandrasekaran S, Wang Y F. A New Framework for Behavior Modeling of Organs and Soft Tissue using the Boundary-Element Methods[C]// IEEE Computer Society Conference on Computer Vision & Pattern Recognition Workshops. IEEE, 2008. DanK ChandrasekaranS WangY F A New Framework for Behavior Modeling of Organs and Soft Tissue using the Boundary-Element Methods[C] IEEE Computer Society Conference on Computer Vision & Pattern Recognition Workshops IEEE 2008 Search in Google Scholar

[12] Reinhard Mnner, Grimm J W, Clemens Wagner, et al. Interactive Real-Time Simulation of the Internal Limiting Membrane. [J]. Lecture Notes in Computer Science. Spring-Verlag Herdelberg. 2004. 3078: 153–160. ReinhardMnner GrimmJ W ClemensWagner Interactive Real-Time Simulation of the Internal Limiting Membrane. [J] Lecture Notes in Computer Science Spring-Verlag Herdelberg. 2004 3078 153 160 Search in Google Scholar

[13] Soon D, Chae M P, Pilgrim C, et al. 3D Haptic Modelling for Preoperative Planning of Hepatic Resection: A Systematic Review [J]. Annals of Medicine & Surgery, 2016, 10:1–7. SoonD ChaeM P PilgrimC 3D Haptic Modelling for Preoperative Planning of Hepatic Resection: A Systematic Review [J] Annals of Medicine & Surgery 2016 10 1 7 Search in Google Scholar

[14] Ruspini D C, Kolarov K, Khatib O. The haptic display of complex graphical environments[C]// Proceedings of the 24th annual conference on Computer graphics and interactive techniques. DBLP, 1997. RuspiniD C KolarovK KhatibO The haptic display of complex graphical environments[C] Proceedings of the 24th annual conference on Computer graphics and interactive techniques DBLP 1997 Search in Google Scholar

[15] Yanping L, Dedong Y, Xiaojun C, et al. Simulation and evaluation of a bone sawing procedure for orthognathic surgery based on an experimental force model. [J]. J Biomech Eng, 2014, 136(3):034501. YanpingL DedongY XiaojunC Simulation and evaluation of a bone sawing procedure for orthognathic surgery based on an experimental force model. [J] J Biomech Eng 2014 136 3 034501 Search in Google Scholar