WIRELESS POWER TRANSFER SYSTEM FOR SCORBOT ER-4U ROBOTIC ARM, 103-111.

Samta Shastri, Yusuf Parvez, and Nathi R. Chauhan

References

1. [1] Y. Shi, G. Yan, W. Chen, and B. Zhu, Micro-intestinal robot with wireless power transmission: design, analysis and experiment, Comput. Biol. Med., 2015, 1–9.
2. [2] J. Jadidian and D. Katabi, Magnetic MIMO: How To Charge Your Phone in Your Pocket, 495–506.
3. [3] F. V. Constantinos Marios Angelopoulos, Sotiris Nikoletseas, Theofanis P. Raptis and Christoforos Raptopoulos, Improving sensor network performance with wireless energy transfer, Int. J. Ad Hoc Ubiquitous Comput., 20(3), 2015.
4. [4] Y. T. H. and W. Lou L Xie, Yi Shi, On traveling path and related problems for a mobile station in a rechargeable sensor network. Proceedings of the International Symposium on Mobile Ad Hoc Networking and Computing (MobiHoc)., 109–118.
5. [5] D. Curiac, Towards wireless sensor, actuator and robot networks: Conceptual framework, challenges and perspectives, J. Netw. Comput. Appl., 2016.
6. [6] A. Karalis, Efficient wireless non-radiative mid-range energy transfer, 323, 2008, 34–48.
7. [7] A. Kurs, A. Karalis, R. Moffatt, J. D. Joannopoulos, P. Fisher, and M. Soljac, Wireless Power Transfer via Strongly Coupled Magnetic Resonances, Science (80-.)., 317, 2007, 83–86.
8. [8] S. Y. R. Hui, W. X. Zhong, and C. K. Lee, A Critical Review of Recent Progress in Mid-Range Wireless Power Transfer, no. c.
9. [9] C. Park et al., Innovative 5m-off-distance Inductive Power Transfer Systems with Optimally Shaped Dipole Coils, 8993(c), 2014.
10. [10] C. Chang, C. Hung, C. Tai, and S. Member, Numerical and Experimental Studies of The Effects of Parallel Inductive Coils and Distance Variation on Wireless Power Transfer Systems of Electric Vehicles, 2015, 2662–66.
11. [11] N. Bakalela and J. Agbinya, Design of multi-dimensional wireless power transfer systems Design of Multi-Dimensional Wireless Power Transfer Systems, no. March, 2015, 85–91.
12. [12] V. Jaros, P. Drgona, B. Kozacek, and M. Piri, Analytical comparison of topology configuration of wireless power transfer system, 2016.
13. [13] C. Zhu, K. Liu, C. Yu, R. Ma, and H. Cheng, Simulation and Experimental Analysis on Wireless Energy Transfer Based on Magnetic Resonances, 2008, 3–6.
14. [14] F. Lu, S. Member, H. Zhang, S. Member, H. Hofmann, and S. Member, An Inductive and Capacitive Combined Wireless Power Transfer System with LC-Compensated Topology, 8993(c), 2016, 1–11.
15. [15] L. J. W. Jingquin, A study based on new resonant topology of WPT system. 7th Asia Pacific Int. Symp. on Electromagnetic Compatibility, Shenzhen, China, 2016.
16. [16] K. Y. Kim et al., Magnetic Resonance Wireless Power Transfer System for Practical Mid-Range Distance Powering Scenario References, 2013, 175–176.
17. [17] W. X. Zhong, C. Zhang, X. Liu, and S. Y. R. Hui, A Methodology for Making a 3 – Coil Wireless Power Transfer System More Energy Efficient Than a 2 – Coil Counterpart for Extended Transfer Distance, 8993(c), 2014. 110
18. [18] A. Moradi, F. Tahami, and A. Poorfakhraei, Minimum Weight Wireless Power Transfer Coil Design, no. Pedstc, 2016, 16–18.
19. [19] M. Kato, T. Imura, and Y. Hori, New Characteristics Analysis Considering Transmission Distance and Load Variation in Wireless Power Transfer via Magnetic Resonant Coupling, no. 1, 2012.
20. [20] C. A. Tucker, K. Warwick, and W. Holderbaum, Electrical Power and Energy Systems A contribution to the wireless transmission of power, Int. J. Electr. Power Energy Syst., 47, 2013, 235–242.
21. [21] T. Deyle and M. Reynolds, Surface Based Wireless Power Transmission and Bidirectional Communication for Autonomous Robot Swarms, 2008, 1036–1041.
22. [22] P. Arunkumar, Experimental Investigation on Mobile Robot Drive System through Resonant Induction Technique, 2010, 699–705.
23. [23] W. Fahui, X. Lin, Y. Dingcheng, and L. Cuthbert, Transmission strategies for wireless powered MIMO relay systems, J. China Univ. Posts Telecommun., 24(1), 2017, 1–10.
24. [24] Q. Liu, K. S. Yildirim, P. Paweczak, and M. Warnier, Safe and Secure Wireless Power Transfer Networks? Challenges and Opportunities in RF-Based Systems, no. September, 2016, 74–79.
25. [25] S. Chhawchharia, S. Kumar, M. Balamurugan, S. Sukchai, and F. Yanine, Investigation of wireless power transfer applications with a focus on renewable energy Microwave Ionosphere Nonlinear Interaction experiment, Renew. Sustain. Energy Rev., 91, September 2017, 2018, 888–902.
26. [26] R.I.Y. Sawahara and T. I. I. Awai, Construction of a secure wireless power transfer system for robot fish, 2015, 6–9.
27. [27] S. Das, A. Wasif, N. Kumar, and E. Karim, Wireless powering by magnetic resonant coupling? Recent trends in wireless power transfer system and its applications, Renew. Sustain. Energy Rev., 51, 2015, 1525–1552.
28. [28] J. Dai and S. Member, A Survey of Wireless Power Transfer and a Critical Comparison of Inductive and Capacitive Coupling for Small Gap Applications, 8993(c), 2015, 1–14.
29. [29] S. Shastri, Y. Parvez, and R. Chauhan, Inverse Kinematics for A 3-R Robot Using Artificial Neural Network and Modified Particle Swarm Optimization, J. Inst. Eng. Ser. C, 2019.
30. [30] https://www.intelitek.com/robots/scorbot-er-4u/.
31. [31] T. Selvaraj and S. Kumanan, PARAMETER IDENTIFICATION OF ROBOT ARM USING ARTIFICIAL NEURAL NETWORKS, Natl. Conf. Comput. Intell. 2007, no. January 2007, 2007.
32. [32] K. Fotopoulou and B. W. Flynn, Wireless Powering of Implanted Sensors using RF Inductive Coupling, 2006, 765–768.

Important Links:

• Abstract
• DOI: 10.2316/J.2020.203-0044
• From Journal (203) International Journal of Power and Energy Systems - 2020

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