STEERING DRIVING CHARACTERISTICS OF A CAPSULE ROBOT IN MULTIPLE BENDING ENVIRONMENT

Minglu Chi,∗ Yuanli Wang,∗ Jianxia Zhang,∗ Aimin Zhang,∗∗ Jingcai Bai,∗∗∗ and Junxiao Wu∗∗∗

References

  1. [1] J.C. Saurin, N. Beneche, C. Chambon, et al., Challenges and future of wireless capsule endoscopy, Clinical Endoscopy, 49(1), 2016, 26–29.
  2. [2] P. Chattopadhyay and S.K. Ghoshal, Adhesion technologies of bio-inspired climbing robots: A survey, International Journal of Robotics and Automation, 33(6), 2018, 654–661.
  3. [3] R. Koprowski, Overview of technical solutions and assessment of clinical usefulness of capsule endoscopy, BioMedical Engineering OnLine, 14(1), 2015, 1.
  4. [4] B. Abbas, A. Fatemeh, and A. Reza, Integrated system for automatic detection of representative video frames in wireless capsule endoscopy using adaptive sliding window singular value decomposition, IET Image Processing, 14(1), 2020, 147–153.
  5. [5] T. Ren, Y. Zhang, Y. Li, et al., Development of an active helical drive self-balancing in-pipe robot based on compound planetary gearing, International Journal of Robotics and Automation, 34(3), 2019, 235–242.
  6. [6] J. Jang, J. Lee, K.R. Lee, et al., A four-camera VGA-resolution capsule endoscope system with 80-Mb/s body channel communication transceiver and sub-centimeter range capsule localization, IEEE Journal of Solid-State Circuits, 54(2), 2019, 538–549.
  7. [7] H.M. Kim, S. Yang, J. Kim, et al., Active locomotion of a paddling-based capsule endoscope in an in vitro and in vivo experiment (with videos), Gastrointestinal Endoscopy, 72(2), 2010, 381–387.
  8. [8] A. Mousa, L. Feng, Y. Dai, et al., Self-driving 3-legged crawling prototype capsule robot with orientation controlled by external magnetic field, 2018 WRC Symposium on Advanced Robotics and Automation (WRC SARA), Beijing, China, 2018, 243–248.
  9. [9] J. Gao, G. Yan, Z. Wang, et al., Design and testing of a motor-based capsule robot powered by wireless power transmission, IEEE/ASME Transactions on Mechatronics, 21(2), 2016, 683–693.
  10. [10] J. Guo, P. Liu, S. Guo, et al., Development of a novel wireless spiral capsule robot with modular structure, 2017 IEEE International Conference on Mechatronics and Automation (ICMA), Takamatsu, Japan, 2017, 439–444.
  11. [11] H. Banerjee, Z.T.H. Tse, and H. Ren, Soft robotics with compliance and adaptation for biomedical applications and forthcoming challenges, International Journal of Robotics and Automation, 33(1), 2018, 69–80.
  12. [12] J. Zhang, H. Guo, T. Wang, et al., The design and motion analysis of a pneumatic omnidirectional soft robot, International Journal of Robotics and Automation, 32(6), 2017, 1–8.
  13. [13] K. Wang, B. Chen, and T. Li, A robotic colonoscope with double balloons: Analysis, design, and experiments, International Journal of Robotics and Automation, 32(6), 2017, 560–568.
  14. [14] Y. Yan, Y. Liu, L. Manfredi, et al., Modelling of a vibroimpact self-propelled capsule in the small intestine, Nonlinear Dynamics, 96(1), 2019, 123–144.
  15. [15] S. Yim and M. Sitti. Shape-programmable soft capsule robots for semi-implantable drug delivery, IEEE Transactions on Robotics, 28(5), 2012, 1198–1202.
  16. [16] K.M. Popek, T. Schmid, and J.J. Abbott, Six-degree-offreedom localization of an untethered magnetic capsule using a single rotating magnetic dipole, IEEE Robotics and Automation Letters, 2(1), 2017, 305–312.
  17. [17] H. Yang, L. Jing, B. Federico, et al., Analytical magnetic model towards compact design of magnetically-driven capsule robots, IEEE Transactions on Medical Robotics and Bionics, 2(2), 2020, 188–195.
  18. [18] J. Sun, Z. Ju, and H. Ren, Finite element simulation of a passive magnetic robotic system, International Journal of Robotics and Automation, 32(1), 2017, 87–92.
  19. [19] C.D. Natali, M. Beccani, N. Simaan, et al., Jacobian-based iterative method for magnetic localization in robotic capsule endoscopy, IEEE Transactions on Robotics, 32(2), 2016, 327–338.
  20. [20] A.W. Mahoney and J.J. Abbott, Five-degree-of-freedom manipulation of an untethered magnetic device in fluid using a single permanent magnet with application in stomach capsule endoscopy, The International Journal of Robotics Research, 35(1–3), 2016, 129–147.
  21. [21] Q. Fu, S. Guo, Q. Huang, et al., Development and evaluation of novel magnetic actuated microrobot with spiral motion using electromagnetic actuation system, Journal of Medical and Biological Engineering, 36(4), 2016, 506–514.
  22. [22] M. Chi and Y. Zhang, Research on spatial steering magnetic moment for petal-shaped capsule robot, Journal of Huazhong University of Science and Technology, 46(4), 2018, 80–85.
  23. [23] A.W. Mahoney and J.J. Abbott, Generating rotating magnetic fields with a single permanent magnet for propulsion of untethered magnetic devices in a lumen, IEEE Transactions on Robotics, 30(2), 2013, 411–420.
  24. [24] C. Lee, H. Choi, G. Go, et al., Active locomotive intestinal capsule endoscope (ALICE) system: A prospective feasibility study, IEEE/ASME Transactions on Mechatronics, 20(5), 2014, 2067–2074.
  25. [25] Y. Zhang, M. Chi, and Z. Su, Critical coupling magnetic moment of a petal-shaped capsule robot, IEEE Transactions on Magnetics, 52(1), 2016, 1–9.

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