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Minimally Invasive Therapy & Allied Technologies Volume 17, 2008 - Issue 3: Topic section: Tissue approximation and welding
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Development of a micro‐robot for endoscopes based on wireless power transfer

Dongdong Ye Institute of Precision Engineering and Intelligence Micro‐System, School of Electronics and Information Technology, Shanghai Jiao tong University, Shanghai, ChinaCorrespondence[email protected]
,
Guozheng Yan Institute of Precision Engineering and Intelligence Micro‐System, School of Electronics and Information Technology, Shanghai Jiao tong University, Shanghai, China
,
Kundong Wang Institute of Precision Engineering and Intelligence Micro‐System, School of Electronics and Information Technology, Shanghai Jiao tong University, Shanghai, China
&
Guanying Ma Institute of Precision Engineering and Intelligence Micro‐System, School of Electronics and Information Technology, Shanghai Jiao tong University, Shanghai, China
Pages 181-189 | Published online: 10 Jul 2009

References

  • Ikuta K. The application of the micro/miniature mechatronics to medical robotics. IEEE International Workshop on Intelligent Robots, Center for Robotic Systems in Microelectronics 1988; 9–14, University of California
  • Slatkin A. B., Burdick J., Grundfest W. The development of a robotic endoscope. IEEE/RSJ International Conference on Human Robot Interaction and Cooperative Robots: Proceedings 1995; 2: 162–71
  • Hoeg H. D., Slatkin A. B., Burdick J. W. Biomechanical modeling of the small intestine as required for the design and operation of a robotic endoscope. Proceedings of the IEEE International Conference on Robotics&Automation 2000; 1599–1606, San Francisco
  • Carrozza M. C., Lencioni L., Magnani B., Dario P., et al. A microrobot for intestinescopy. IEEE Seventh International Symposium on Micro Machine and Human Science, October 2, Nagoya Municipal Industrial Research Institute 1996; 223–8, Japan
  • Carrozza M. C., Lencioni L., Magnani B., DAttanasio S., et al. The development of a microrobot system for endoscope. Proceedings of Computer Vision, Virtual Reality and Robotics in Medicine and Medical Robotics and Computer‐Assisted Surgery 1997; 1205: 779–88
  • Dario P., Carrozza M. C., Pietrabissa A. Development and In‐Vitro testing of a miniature robotic system for endoscope. Journal of Computer Aided Surgery 1999; 4: 1–14
  • Phee L., Menciassi A., Gorini S., et al. An innovative locomotion principle for mini robots moving in the gastrointestinal tract. IEEE International Conference on Robotics and Automation 2002; 1125–30, Washington DC
  • Phee L., Menciassi A., Accoto D., et al. Analysis of robotic locomotion devices for the gastrointestinal tract. Robotics Research 2003; 6: 467–83
  • Matsuki H., Shiiki M. Investigation of coil geometry for transcutaneous energy transfer for artificial heart. IEEE Trans Magnetic 1992; 28: 2406–8
  • Matsuki H., Shiiki M. Investigation of coil geometry for transcutaneous energy transfer for artificial heart. IEEE Trans Magnetic 1992; 28: BP–05
  • Wang Kun‐Dong. Research on a miniature biomimetic robot for colon examination: key technology and experiments. A Dissertation Submitted to Shanghai Jiaotong University for the Ph.D. Degree 2006; 13–30
  • Ma Hao, Zhou Wenqi. Modeling a current source push‐pull resonant converter for loosely coupled power transfer systems. IEEE industrial Electronics Society, Busan, Korea, November 2–5 2004; 1024–9
  • Ma Guanying, Yan Guozheng, He Xiu. Power transmission for gastrointestinal microsystems using inductive coupling. Physiol. Meas 2007; 28: 9–18
  • Lenaerts B., Puers R. Inductive powering of a freely moving system. Sensors and Actuators 2005; 522–3
  • Lenaerts B., Puers R. An inductive power link for a wireless endoscope. Biosensors and Bioelectronics 2006; 6: 1–6
  • Lenaerts B., Puers R. An Omnidirectional Transcutaneous Power Link for Capsule Endoscopy. Proceedings of the International Workshop on Wearable and Implantable Body Sensor Networks, 3–5 April 2006; 4
  • Theodoridis M. P., Mollov S. V. Distant Energy Transfer for Artificial Human Implants. IEEE Transactions on Biomedical Engineering November 2005; 52: 1931–8
  • Wang C. S., Stielau O. H., Covic G. A. Load models and their application in the design of loosely coupled inductive power transfer systems. Proceeding of Power System Technology 2000; l2: 1053–8
  • Ghahary A., Cho B. H. Design of transcutaneous energy transmission system using a series resonant converter. IEEE Trans, Power Electron 1992; 7: 261–9
  • Vandevoorde G., Puers R. Wireless energy transfer for stand‐alone systems: a comparison between low and high power applicability. Sensors Actuators 2001; A 92: 305–11
  • Zhou Qu, Yan Guozheng, Wang Wenxing. Estimating Parameter for Defocus Blur Image using Cepstrum Analysis. High Technology Letters of China 2007; 13

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