A haptic interface for computer-integrated endoscopic surgery and training
Tóm tắt
Haptic feedback has the potential to provide superior performance in computer-integrated surgery and training. This paper discusses the design of a user interface that is capable of providing force feedback in all the degrees of freedom (DOFs) available during endoscopic surgery. Using the Jacobian matrix of the haptic interface and its singular values, methods are proposed for analysis and optimization of the interface performance with regard to the accuracy of force feedback, the range of applicable forces, and the accuracy of control. The haptic user interface is used with a sensorized slave robot to form a master–slave test-bed for studying haptic interaction in a minimally invasive environment. Using the master–slave test-bed, teleoperation experiments involving a single degree of freedom surgical task (palpation) are conducted. Different bilateral control methods are compared based on the transparency of the master–slave system in terms of transmitting the critical task-related information to the user in the context of soft-tissue surgical applications.
Tài liệu tham khảo
Furukawa T, Morikawa Y, Ozawa S, Wakabayashi G, Kitajima M (2001) The revolution of computer-aided surgery—the dawn of robotic surgery. Minim Invasive Ther Allied Technol 10(6):283–288
Ballantyne GH (2002) Robotic surgery, telerobotic surgery, telepresence, and telementoring. Surg Endosc 16(10):1389–1402
Breedveld P, Stassen HG, Meijer DW, Jakimowicz JJ (2000) Observation in laparoscopic surgery: overview of impeding effects and supporting aids. J Laparoendosc Adv Surg Tech 10:231–241
Tendick F, Jennings R, Tharp G, Stark L (1996) Perception and manipulation problems in endoscopic surgery. In: Computer-integrated surgery: technology and clinical applications. MIT Press, Cambridge
Taylor RH, Stoianovici D (2003) Medical robotics in computer-integrated surgery. IEEE Trans Rob Autom 19:765–781
Dario P, Hannaford B, Menciassi A (2003) Smart surgical tools and augmented devices. IEEE Trans Rob Autom 19(5):782–792
Howe RD, Matsuoka Y (1999) Robotics for surgery. Annu Rev Biomed Eng 01:211–240
Malpass L (1963) Motor skills in mental deficiency. In: Handbook of mental deficiency. McGraw-Hill, New York
Shimoga KB (1993) A survey of perceptual feedback issues in dextrous telemanipulation: part I. Finger force feedback. In: Proceedings of the IEEE annual virtual reality international symposium, pp 271–279
Burdea GC (1996) Force and touch feedback for virtual reality. Wiley, New York
Hannaford B, Wood L (1989) Performance evaluation of a 6 axis high fidelity generalized force reflecting teleoperator. In: Proceedings of the JPL/NASA conference on space telerobotics, pp 89–97
Gerovichev O, Marayong P, Okamura AM (2002) The effect of visual and haptic feedback on manual and teleoperated needle insertion. In: Proceedings of the 5th international conference on medical image computing and computer assisted intervention, pp 147–154
Wagner C, Stylopoulos N, Howe R (2002) Force feedback in surgery: analysis of blunt dissection. In: Proceedings of the 10th symposium on haptic interfaces for virtual environment and teleoperator systems, pp 68–74
Sung GT, Gill IS (2001) Robotic laparoscopic surgery: a comparison of the da Vinci and Zeus systems. Urology 58(6):893–898
Hashizume M, Shimada M, Tomikawa M, Ikeda Y, Takahashi I, Abe R, Koga F, Gotoh N, Konishi K, Maehara S, Sugimachi K (2002) Early experiences of endoscopic procedures in general surgery assisted by a computer-enhanced surgical system. Surg Endosc 16(8):1187–1191
Tendick F, Jennings R, Tharp G, Stark L (1993) Sensing and manipulation problems in endoscopic surgery: experiment, analysis and observation. Presence: Teleoper Virtual Environ 2(1):66–81
Taffinder N, Sutton C, Fishwick RJ, McManus IC, Darzi A (1998) Validation of virtual reality to teach and assess psychomotor skills in laparoscopic surgery: results from randomised controlled studies using the MIST VR laparoscopic simulator. Stud Health Technol Inform 50:124–130
Mason AH, Walji MA, Lee EJ, MacKenzie CL (2001) Reaching movements to augmented and graphic objects in virtual environments. In: Proceedings of the SIGCHI conference on Human factors in computing systems, pp 426–433
Fitts PM, Peterson J (1964) Information capacity of discrete motor responses. J Exp Psychol 67(2):103–112
Gupta R, Sheridan T, Whitney D (1997) Experiments using multi-modal virtual environments in design for assembly analysis. Presence: Teleoper Virtual Environ 6(3):318–338
Hurmuzlu Y, Ephanov A, Stoianovici D (1998) Effect of a pneumatically driven haptic interface on the perceptional capabilities of human operators. Presence: Teleoper Virtual Environ 7(3):290–307
Chen E, Marcus B (1998) Force feedback for surgical simulation. Proc IEEE 86(3):524–530
Moody L, Baber C, Arvanitis TN, Elliott M (2003) Objective metrics for the evaluation of simple surgical skills in real and virtual domains. Presence: Teleoper Virtual Environ 12(2):207–221
Feygin D, Keehner M, Tendick F (2002) Haptic guidance: experimental evaluation of a haptic training method for a perceptual motor skill. In: Proceedings of the 10th symposium on haptic interfaces for virtual environment and teleoperator systems, pp 40–47
Guo X, Hua J, Qin H (2004) Touch-based haptics for interactive editing on point set surfaces. IEEE Comput Graph Appl 24(6):31–39
Sherman A, Cavusoglu M, Tendick F (2000) Comparison of teleoperator control architectures for palpation task. In: Proceedings of the symposium on haptic interfaces for virtual environment and teleoperator systems, pp 1261–1268
Lazeroms M (1999) Force reflection for telemanipulation applied to minimally invasive surgery. PhD thesis, Delft University of Technology
Madhani A, Niemeyer G, Salisbury JK Jr (1998) The black falcon—a teleoperated surgical instrument for minimally invasive surgery. In: Proceedings of the IEEE/RSJ international conference on intelligent robots and systems, pp 936–944
Youngblut C, Johnston RE, Nash SH, Wienclaw RA, Will CA (1996) Review of virtual environment interface technology. Institute for Defense Analyses (IDA) Paper P-3186
Massie TH (1993) Design of a three degree of freedom force-reflecting haptic interface. BS thesis, MIT
Holden JG, Flach JM, Donchin Y (1999) Perceptual-motor coordination in an endoscopic surgery simulation. Surg Endosc 13(2):127–132
Gao F, Gruver WA (1997) Performance evaluation criteria for analysis and design of robotic mechanisms. In: Proceedings of the 8th international conference on advanced robotics, pp 879–884
Gosselin C, Angeles J (1991) A global performance index for the kinematic optimization of robotic manipulators. Trans ASME J Mech Design 113:220–226
Tavakoli M, Patel R, Moallem M (2005) Haptic interaction in robot-assisted endoscopic surgery: a sensorized end effector. Int J Med Rob Comput Assist Surg 1(2):53–63
Taylor RM II, Hudson TC, Seeger A, Weber H, Juliano J, Helser AT (2001) VRPN: a device-independent, network-transparent VR peripheral system. In: Proceedings of the ACM symposium on virtual reality software and technology, pp 55–61
Yokokohji Y, Yoshikawa T (1994) Bilateral control of master-slave manipulators for ideal kinesthetic coupling—formulation and experiment. IEEE Trans Rob Autom 10(5):605–620
Nicosia S, Tomei P (1990) Robot control by using only joint position measurements. IEEE Trans Autom Control 35(9):1058–1061
Hacksel PJ, Salcudean SE (1994) Estimation of environment forces and rigid-body velocities using observers. In: Proceedings of the IEEE International Conference on Robotics and Automation, pp 931–936
Hannaford B (1989) A design framework for teleoperators with kinesthetic feedback. IEEE Trans Rob Autom 5:426–434
Cavusoglu MC, Sherman A, Tendick F (2002) Design of bilateral teleoperation controllers for haptic exploration and telemanipulation of soft environments. IEEE Trans Rob Autom 18(4):641–647
Hashtrudi-Zaad K, Salcudean SE (2002) Transparency in time-delayed systems and the effect of local force feedback for transparent teleoperation. IEEE Trans Rob Autom 18:108–114