Experimental Study of 7-DOF bionic forearm prosthesis

  IJETT-book-cover  International Journal of Engineering Trends and Technology (IJETT)          
  
© 2020 by IJETT Journal
Volume-68 Issue-9
Year of Publication : 2020
Authors : Ivan Krechetov, Arkady Skvortsov, Ivan Poselsky
DOI :  10.14445/22315381/IJETT-V68I9P208

Citation 

MLA Style: Ivan Krechetov, Arkady Skvortsov, Ivan Poselsky  "Experimental Study of 7-DOF bionic forearm prosthesis" International Journal of Engineering Trends and Technology 68.9(2020):40-48. 

APA Style:Ivan Krechetov, Arkady Skvortsov, Ivan Poselsky. Experimental Study of 7-DOF bionic forearm prosthesis  International Journal of Engineering Trends and Technology, 68(9),40-48.

Abstract
In this work, an experimental study on the grip of complex shape objects by the developed hand module of the bionic prosthesis has been conducted. A description of the seven-degree-of-freedom (7- DOF) control system of the hand module has been presented. The hand module is designed for the use in forearm and shoulder prostheses; finger modules can be used separately in the manufacture of hand prostheses. Developed programming units can be used in the building control systems of the gripping anthropomorphic manipulator, which has a kinematic structure similar to the human hand but a different number of controlled and dependent degrees of freedom. The project aims at the development of a bionic forearm prosthesis which has reliability and performance close to a healthy human hand.

Reference

[1] I. Krechetov, A. Skvortsov, I. Poselsky, “Development of bionic arm prosthesis: selection of research directions,” Journal of Advanced Research in Dynamical & Control Systems, vol. 11, Special Issue 06, pp.2060-2068, 2019.
[2] K. Ohishi, M. Nakao, and K. Miyachi, “Microprocessorcontrolled DC motor for load-insensitive position servo system,” IEEE Transactions on Industrial Electronics, vol.1, pp. 44-49, Feb.1987.
[3] U. K. Bansal and R. Narvey, “Speed control of DC motor using fuzzy PID controller,” Advances in Electronic and Electric Engineering, vol.3, no.9, pp. 1209-1220, Nov. 2013.
[4] G. R. Yu and R. C. Hwang, “Optimal PID speed control of brush less DC motors using LQR approach,” in 2004 IEEE International Conference on Systems, Man and Cybernetics (IEEE Cat. No. 04CH37583), vol. 1, pp. 473-478, Oct. 2004.
[5] N. Thomas and D. P. Poongodi, “Position control of DC motor using genetic algorithm based PID controller,” in Proceedings of the World Congress on Engineering, vol. 2, pp. 1-3, July 2009.
[6] P. M. Meshram and R. G. Kanojiya, “Tuning of PID controller using Ziegler-Nichols method for speed control of DC motor,” in IEEE International Conference on Advances in Engineering, Science and Management (ICAESM-2012), pp. 117-122, March 2012.
[7] H. Ji and Z. Li, “Design of neural network PID controller based on brushless DC motor,” in 2009 Second International Conference on Intelligent Computation Technology and Automation, vol.3, pp. 46-49, Oct.2009.
[8] N. Leena and R. Shanmugasundaram, “Artificial neural network controller for improved performance of brushless DC motor,” in 2014 International Conference on Power Signals Control and Computations (EPSCICON), pp. 1-6, Jan 2014.
[9] W. Xing-gui and L. Qi, “Permanent magnet linear brushless DC motor position control system based on single neuron,” in: 2010 International Conference on Networking and Digital Society, vol. 2, pp. 593-596, May 2010.
[10] B. Dandil, “Fuzzy neural network IP controller for robust position control of induction motor drive,” Expert Systems with Applications, vol.36, no.3, pp. 4528-4534, Apr. 2009.
[11] E. C. Harrington, “The desirability function,” Industrial Quality Control, vol.21, no.10, pp.494-498, 1965.
[12] OttoBock. beBionic. User’s Guide. [Online] Available: from https://www.ottobockus.com/media/localmedia/ prosthetics/upperlimb/ files/14112_bebionic_user_guide_lo.pdf
[13] OSSUR. iLimb Ultra Information Sheet. [Online] Available: https://www.ossur.com/library/40545/i- Limb%20Ultra%20Information%20Sheet%20-%20.pdf
[14] OttoBock. SensorHand Speed and VariPlus Speed. [Online] Available: https://www.ottobockus.com/media/localmedia/ prosthetics/upperlimb/ speedhands/prosthesis_systems_information_for_prac titioners.pdf
[15] Vincent Systems. VINCENTevolution 2. [Online] Available: https://vincentsystems.de/en/prosthetics/vincentevolution-2/

Keywords
bionic hand, module, dexterous hand, upper limb prostheses.