Hai Huang, Da-peng Yang, Chao-yu Sun, Nan Li, Yong-jie Pang, Li Jiang, and Hong Liu
[1] A. Bicchi, Hand for dexterous manipulation and robust grasping: A difficult road toward simplicity, IEEE Transactions on Robotics and Automation, 16(6), 2000, 652–662. [2] P. Dario, C. Laschi, and M.C. Carrozza, An integrated approach for the design and development of a grasping and manipulation system in humanoid robotics, Proc. 2002 IEEE\Int. Conf. on Robotics and Automation, Takamatsu, Japan, 2002, 1–7. [3] L. Zollo, S. Roccella, and E. Guglielmelli, Biomechatronic design and control of an anthropomorphic artificial hand for prosthetic and robotic applications, IEEE/ASME Transactions on Mechatronics, 12(4), 2007, 418–429. [4] L. Lotti, P. Tiezzi, and C. Melchiorri, Development of UB Hand 3, Proc. 2005 IEEE Int. Conf. on Robotics and Automation, Barcelona, Spain, April 2005, 4499–4503. [5] N. Chev, W.L. Cleghorn, and S. Naumann, Multiple finger, passive adaptive grasp prosthetic hand, Mechanism and Machine Theory, 36, 2001, 1157–1173. [6] L. Zollo, S. Roccella, and R. Tucci, Biomechatronic design and control of an anthropomorphic artificial hand for prosthetics hand robotic applications, Bio Rob 2006, Pisa, Italy, February 2006, 198–203. [7] http://www.touchbionics.com/products/active-prostheses/i-limb-ultra/ [8] http://www.ottobock.com/cps/rde/xchg/ob_com_en/hs.xsl/3633.html [9] C. Castellini and P. van der Smagt, Surface EMG in advanced hand prosthetics, Biological Cybernetics, 100(1), 2009, 1–22. [10] S. Micera, J. Carpaneto, and S. Raspopovic, Control of hand prostheses using peripheral information, IEEE Reviews inBiomedical Engineering, 3, 2010, 48–68. [11] S. Lee and G.N. Saridis, The control of a prosthetic arm by EMG pattern recognition, IEEE Transactions on Automatic Control, 29(4), 1984, 290–320. [12] D. Graupe, J. Salahi, and K.H. Kohn, Multifunction prosthesis and orthosis control via micro-computer identification of temporal pattern differences in single-site myoelectric signals, Journal of Biomedical Engineering, 4, 1982, 17–22. [13] A.B. Ajiboye and R.F.ff. Weir, A heuristic fuzzy logic approach to EMG pattern recognition for multifunctional prosthetic control, IEEE Transactions on Neural Systems and Rehabilitation Engineering, 13(3), 2005, 280–291. [14] H.P. Huang and C.Y. Chen, Development of a myoelectric discrimination system for a multi-degree prosthetic hand, Proc. IEEE Int. Conf. on Robotics and Automation, Detroit, MI, May 10–15, 1999, 2392–2397. [15] Y.-H. Liu, H.-P. Huang, and C.-H. Weng, Recognition of electromyographic signals using cascaded kernel learning machine, IEEE/ASME Transactions on Mechatronics, 12(3), 2007,253–264. [16] C.E. Stepp, B.T. Dellon, and Y. Matsuoka, Contextual effects on robotic experiments of sensory feedback for object manipulation, Proc. 3rd IEEE RAS & EMBS, Tokyo, Japan, September 2010, 58–63. [17] C. Antfolk, C. Balkenius, G. Lundborg, B. Rosén, and F. Sebelius, Design and technical construction of a tactile display for sensory feedback in a hand prosthesis system, Biomedical Engineering Online, 50(9), 2010, 1–9. [18] L.E. Rodríguez-Cheu, D. González, and M. Rodríguez, Result of a perceptual feedback of the grasping forces, Proc. of the 2nd Biennial IEEE/RAS-EMBS, Scottsdale, AZ, October 2008, 901–906. [19] C. Antfolk, C. Cipriani, M. Controzzi, M.C. Carrozza, G. Lundborg, B. Rosén, F. Sebelius, Using EMG for real-time prediction of joint angles to control a prosthetic hand equipped with a sensory feedback system, Journal of Medical and Biological Engineering, 6(30), 2010, 399–406. [20] A. Chatterjee, P. Chaubey, J. Martin, N.V. Thakor, Quantifying prosthesis control improvements using a vibrotactile representation of grip force, 2008 IEEE Region 5 Conf., Kansas City, MO, April 2008, 1–5. [21] C. Pylatiuk, S. Mounier, A. Kargov, S. Schulz, and G. Bretthauer, Progress in the development of a multifunctional hand prosthesis, Proc. 26th Annual Int. Conf. of the IEEE EMBS, San Francisco, CA, United states, September 2004, 4260–4263. [22] H. Huang, L. Jiang, D.W. Zhao, J.D. Zhao, H.G. Cai, H. Liu, P. Meusel, B. Willberg, and G. Hirzinger, The Development on a new biomechatronic prosthetic hand based on under-actuated mechanism, IEEE/RSJ Int. Conf. on Intelligent Robots and Systems, Beijing, China, October 2006, 3791–3796. [23] S. Shunji, S. Makoto, S. Sigeru, S. Yoshikazu, T. Akihiko, I. Yukio, and Y. Matsutaro, The relationship between human grip types and force distribution pattern in grasping, Proc. 8th Int. Conf. on Advanced Robotics, Monterey, CA, 1997, 299–304. [24] I.C. Sollerman, Assessment of grip function: Evaluation of a new test method (Sjöbo, Sweden: MITAB, 1980). [25] C.L. Taylor and R.J. Schwarz, The anatomy and mechanics of the human hand, Artificial Limbs, 2, 1955, 22–35. [26] C. Castellini, P. van der Smagt, and G. Sandini, Surface EMG for force control of mechanical hands, Proc. 2008 IEEE Int. Conf. on Robotics and Automation, Pasadena, CA, May 2008, 725–730. [27] M.A. Oskoei and H. Hu, Support vector machine-based classification scheme for myoelectric control applied to upper limb, IEEE Transactions on Biomedical Engineering, 55(8), 2008, 1956–1965. [28] C.J.C. Burges, A tutorial on support vector machines for pattern recognition, Knowledge Discovery and Data Mining, 2(2), 1998, 121–167. [29] S. Bitzer and P. van der Smagt, Learning EMG control of a robotic hand: Towards active prosthesis, Proc. of ICRA, Int. Conf. on Robotics and Automation, Orlando, FL, May 2006, 2819–2823. [30] V. Vapnik, Statistical learning theory (New York, NY: Wiley, 1998). [31] S.S. Keerthi and C.J. Lin, Asymptotic behaviors of support vector machines with Gaussian kernel, Neural Computation, 15(7), 2003, 1667–1689. [32] R.R. Riso, A.R. Ignagni, and M.W. Keith, Cognitive feedback for use with FES upper extremity neuroprosthesis, IEEE Transactions on Biomedical Engineering, 1(38), 1991, 29–38. [33] A. Chatterjee, P. Chaubey, J. Martin, N.V. Thakor, Quantifying prosthesis control improvements using a vibrotactile representation of grip force, 2008 IEEE Region 5 Conf., Kansas City, MO, April 2008. [34] H. Yaguchi, O. Fukayama, and T. Suzuki, Effect of simultaneous vibrations to two tendons on velocity of the induced illusory movement, Proc. of 32nd Annual Int. Conf. of the IEEE EMBS, Buenos Aires, Argentina, August 2010, 5851–5853. [35] H. Hai, J. Li, P. Yong-jie, S. Shi-cai, Observer-based dynamic control of an underactuated hand, Advanced Robotics, 24, 2010, 123–137.
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