Robotic Hand Controlling Based on Flexible Sensor

Year 2016, Volume: 8 Issue: 4, 49 - 58, 26.12.2016

Süleyman Bilgin Yavuz Üser , Muhammet Mercan

https://doi.org/10.24107/ijeas.281463

Cited By: 4

Abstract

Today's technology has increased the interest in robotic systems and
increase the number of studies realized in this area.  There are many studies on robotic systems in
several fields to facilitate human life in the literature. In this study, a
robot hand is designed to repeat finger movements depending upon flexible
sensors mounted on any wearable glove. In the literature, various sensors that
detect the finger movement are used. The sensor that detects the angle of the
fingers has been shown to provide high accuracy although cheap in present
research. Moreover, by entering the sensor data into the open source interface
program called Blender 3D, it can be seen on the program how the hand of the
robot moves. Thanks to the prototype of robotic hand in this study is developed
with different materials and mechanisms, it is possible to carry out experimental
studies at low cost in places where it is unsuitable for human health and
safety. The angle data on the sensors and servo motor position information are
transmitted through the RF 433 MHz wireless module. The determinations related
to robot hand control are performed with Arduino card. 

Keywords

Flexible Sensor, Robotic Hand, Blender 3D

References

• [1] Jacobsen, S.C., Wood, J.E., Knutti D. and Biggers K.B., Dextrous hand: Work in progress, Int J Robot Res., 321–350, 1984.
• [2] Bekey, G.A., Liu H., Tomovic, R., et al. Knowledge-based control of grasping in robot hands using heuristics from human motor skills, IEEE Trans Robot Autom. 9,709–722, 1993.
• [3] Landsberger, S., Shaperman, J., Setoguchi, Y., et al., Child prosthetic hand design: No small challenge, IEEE WESCON, 236–240, USA, 1996.
• [4] Doshi, R., Yeh, C., LeBlanc, M., The design and development of a gloveless endoskeletal prosthetic hand, J Rehab Res Dev., 35, 388–395, 1998.
• [5] Ambrose, R.O., Aldridge, H., Askew, R.S., et al., Robonaut: NASA’s Space Humanoid, IEEE Intel Syst. 15, 57–63, 2000.
• [6] Byoung, K., Byung, Y., Hong, O., et al., Biomimetic compliance control of robot hand by considering structures of human finger, Proc IEEE Int Conf Robot Autom., 4, 3879–3886, 2000.
• [7] Carrozza, M.C., Massa, B., Micera, S., et al., The development of a novel prosthetic hand-ongoing research and preliminary results, IEEE/ASME Trans Mechatron., 7, 108–114, 2002.
• [8] Massa, B., Roccella, S., Carrozza, M.C., Dario, P., design and development of an under actuated prosthetic hand, IEEE International Conference. Robotics and Automation, 4, 3374–3379, 2002.
• [9] Bundhoo V, Park EJ. Design of an Artificial muscle actuated finger towards biomimetic prosthetic hand. Proceedings 12th International Conference. Advanced Robotics, ICAR’05 IEEE, 368–375, 2005.
• [10] Zhao, D.W., Jiang, L., Huang, H., et al., Development of a multi-DOF anthropomorphic prosthetic hand, IEEE International Conference on Robotics & Biomimetrics, 878–883, China, 2006.
• [11] Zajdlik, J., The preliminary design and motion control of a five-fingered prosthetic hand, International Conference on Intelligent Engineering Systems. IEEE, London, United Kingdom, 2006.
• [12] Ramaiah, P.S., Venkateswara, R.M., Satyanarayana, G.V., A microcontroller based four fingered robotic hand, IJAIA, 2, 90–102, 2011.
• [13] Zhang, T., Fan, S., Zhao, J., et al., Design and control of a multisensory five-finger prosthetic hand, Intelligent Control and Automation (WCICA), 11th World Congress, Shenyang, China, 3327–3332, 2014.
• [14] Saikia, A., Mazumdar, S., Sahai, N., Paul, S., Bhatia, D., Verma, S., and Rohilla, P. K., Recent advancements in prosthetic hand technology, Journal of Medical Engineering & Technology, 1-10, 2016.
• [15] Kappassov, Z., Corrales, J.A., & Perdereau, V., Tactile sensing in dexterous robot hands—Review, Robotics and Autonomous Systems, 74, 195-220, 2015.
• [16] Das, A.K., Das, R., Design and realization of prosthetic hand and its free movement, Int J Emerg Technol Adv Eng., 3, 341–346, 2013.
• [17] Pfeifer, R., Iida, F., Gomez. G., Designing intelligent robots on the implications of embodiment, J Robot Soc Jpn, 24, 9–16, 2006.
• [18] Lee, S., Noh, S., Lee, Y., et al., Development of biomimetic robot hand using parallel mechanisms. IEEE International Conference on Robotics and Biomimetics, Guilin, Guangxi, China 2009.
• [19] O’Toole, K.T., McGrath, M.M., Mechanical design and theoretical analysis of a four fingered prosthetic hand incorporating embedded SMA bundle actuators, Int J Med Health Pharmaceut Biomed Eng., 1, 7, 2007.
• [20] Olawale, J., Oludele, A., Ayodele, A., et al., Development of a microcontroller based robotic arm, Proc Compr Sci IT Educ Conf., 2007.
• [21] Ciocarlie, M.T., Clanton, S.T., Spalding, M.C., Allen, P.K., Biomimetic grasp planning for cortical control of a robotic hand, Intelligent Robots and Systems IEEE/RSJ International Conference, 2271–2276, 2008.
• [22] Omer Korkmaz, Mustafa Cem Kasapbasi, Robot Hand Making Copying Finger Motion, XVIII. Academic Informatic Conference ,Turkey, AB 2016.