Authors: B. Tondu, N. Bardou

Abstract:

In its attempt to offer new ways into autonomy for a large population of disabled people, assistive technology has largely been inspired by robotics engineering. Recent human-like robots carry new hopes that it seems to us necessary to analyze by means of a specific theory of anthropomorphism. We propose to distinguish a functional anthropomorphism which is the one of actual wheelchairs from a structural anthropomorphism based on a mimicking of human physiological systems. If functional anthropomorphism offers the main advantage of eliminating the physiological systems interdependence issue, the highly link between the robot for disabled people and their human-built environment would lead to privilege in the future the anthropomorphic structural way. In this future framework, we highlight a general interdependence principle : any partial or local structural anthropomorphism generates new anthropomorphic needs due to the physiological systems interdependency, whose effects can be evaluated by means of specific anthropomorphic criterions derived from a set theory-based approach of physiological systems.

Keywords: Anthropomorphism, Human-like machines, Systemstheory, Disability.

Digital Object Identifier (DOI): doi.org/10.5281/zenodo.1333218

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References:

[1] Jackson R.D., "Robotics and its Role in Helping Disabled People", Engineering Science and Educational Journal, December, 1993, pp. 267- 272.
[2] Bolmsjö G., Neveryd H. and Eftring H., "Robotics in Rehabilitation", IEEE Transactions on Rehabilitation Engineering, Vol. 3, N┬░1, 1995, pp. 77-83.
[3] Kuman V., Rahman T. and Krovi V., "Assistive Devices for People with Motor Disabilities" in Encyclopedia of Electrical and Electronics Engineering, J.G.Webster Ed., Wiley, New-York, 1999.
[4] Abdulrazak B. and Mokhtari M., "Assistive Robotics for Independent Living" in Smart Technology for Aging, Disability and Independence: Computing and Engineering Design and Applications, Wiley, New-York, 2008, Chap. 19, pp. 335-374.
[5] Friedland M.T., "Not Disabled Enough: The ADA-s ÔÇÿMajor Life Activity- Definition of Disability", Stanford Law Review, Vol. 52, 1999, pp. 171- 203.
[6] Yearwood A.C., "Being Disabled Doesn-t Mean Being Handicapped", American Journal of Nursing, Februray 1980, Vol. 80, N┬░2, pp. 299-302.
[7] DiSalvo C., Gemperle F. and Forlizi J., "Imitating the Human Form: Four Kinds of Anthropomorphic Form", on-line free document, web site of Carnegie Mellon School of Design.
[8] DiSalvo C. and Gemperle F., "From Seduction to Fulfillment: The Use of Anthropomorphic Form in Design", on-line free document, web site of Carnegie Mellon School of Design.
[9] Mesarovic M.D., "Auxiliary Functions and Constructive Specification of a General Systems", Math. Systems Theory, Vol.2, N┬░3, 1968, pp. 203-222.
[10] Mesarovic M.D., "Towards the Development of a General Systems Theory", Neue Technik Abteilung A : Automatik und Industrielle Elektronik, Vol.5, N┬░7, 1963, pp.370-377.
[11] Tondu B., "Towards a Anthropomorphism Theory for Human-like Machines based on Systems Science", Proc. of the 6th WSEAS Int. Conf. on Systems Science and Simulation in Engineering, Nov. 2007, pp. 399- 405.
[12] Morecki A., Ekiel J. and Fidelus K., Bionika Ruchu (Bionics of Movement), PWN, Warsaw, 1976, cited in Zatsiorsky V.M. Kinematics of Human Motion, Human Kinetics, 1998 (page 110).
[13] Morecki A., "Should an Industrial Robot be a more Anthropomorphic System in the Future that it is now ?", Proc. of the 6th ISIR, Nottingham, England, 1976.
[14] Tondu B., "Shoulder Complex Mobility Estimation", Applied Bionics and Biomechanics, Vol. 4, N┬░1, 2007, pp. 19-29.
[15] Web site of Exactdynamics, www.exactdynamics.ntl .
[16] Oderud T., Bastiansen J.E. and Tyvand S., "Experiences with the MANUS Wheelchair Mounted Manipulator", Proc. of the 2nd Eur. Conf. on the Adv. of Rehabilitation Technology (ECART), Stockholm, 1993, p. 29.1.
[17] Abdulrazak B., Grandjean B. and Mokhtari M., "Towards a New High Level Controller for MANUS Robot", Proc. of the Int. Conf. on Rehabilitation Robotics (ICORR), Paris, 2001, pp. 221-226.
[18] Tondu B., "Theory of Anthropomorphism for Human-like Machines", Internal Report, University of Toulouse, France, 2007.
[19] Jazrawi L.M., Rokito A.S., Birdzell M.G. and Zuckerman J.D., "Biomechanics of the Elbow", Chap. 13 in Della Valle C.J., Nordin M. and Frankel V.H., Basic Biomechanics of the Musculoskeletal System, 3rd Ed., Lippincott Williams & Wilkins, Philaddelphia, 2001, pp. 340-357.
[20] Kapandji I.A., The Physiology of the Joints, Vol.1,Upper Limb, 6th Ed., 2007, Vol.2. Lower Limb, 5th Ed., 1988, Vol.3. The Trunk and the Vertebral Column, 2nd Ed., 1974, Churchill Livingstone Editor.
[21] Tondu B., "Artificial Muscles for Humanoid Robots", Chap. 5 in Humanoid Robots-Human like Machines, Advanced Robotics books, Vienna, Austria, 2007, pp. 90-122.
[22] Web site of the Rehabilitation Institute of Chicago, www.ric.org (see Bionic Arm).
[23] McGrath B., "Muscle Memory", The New Yorker, 2007, July 30.
[24] Rebsamen B., Burdet E., Guan C., Teo C.L., Zeng Q., Laugier C. and Ang M., "Navigation Ones Wheelchair in a Building by Thought", IEEE Intelligent Systems, Vol. 22, 2007, pp. 18-24.
[25] Sawatsky B., "Wheeling in the New Millenium : The history of the wheelchair and the driving force of the wheelchair design of today", online free document, web site www.wheelchairnet.org, 2002.
[26] Prassler E., Scholz J. and Fiorini P., "A Robotic Wheelchair for Crowned Public Environments", IEEE Robotics and Automation Magazine, March 2001, pp.38-45.
[27] Simpson R.C., "Smart Wheelchairs : A literature Review", Journal of Rehabilitation Research and Development, Vol. 42, N┬░4, 2005, pp. 423- 436.
[28] Zeng Q., Teo C.L., Rebsamen B. and Burdet E., "A Collaborative Wheelchair System", IEEE Transactions on Neural Systems and Rehabilitation Engineering, Vol. 16, N┬░ 2, 2008, pp. 161-170.
[29] Gonzalez J., Muaeoz A.J., Galindo C., Fernandez-Madrigal J.A. and Blanco J.L., "A Description of the SENA Robotic Wheelchair", Proc. of the IEEE MELECON Conf., Benalmadena, Spain, 2006, pp. 437-440.
[30] Sugahara Y. and Hashimoto K., "Towards the Biped Walking Wheelchair", Proc. of 1st IEEE/RAS-EMBS Int. Conf. on Biomedical Robotics and Biomechatronics (BioRob 2006), Pisa, Italy, 2006, paper n┬░ 289.
[31] Tang J., Zhao Q. and Huang J., "Application of ÔÇÿHuman-In-the-Loop- Control to a Biped Walking-Chair Robot", Proc. of the 2007 Int. Conf. on Systems, Man and Cybernetics, 2007, pp. 2431-2436.
[32] Hirai K., Hirose M., Haikawa Y., Takenaka T., "The Development of the Honda Humanoid Robot", Proc. of the 1998 IEEE Int. Conf. on Robotics & Automation, Leuven, Belgium, 1998, pp. 1321-1326.
[33] Sakagami Y., Watanabe R., Aoyama C., Matsunaga S., Higaki N. and Fujimura K., "The Intelligent ASIMO: System Overview and Integration", Proc. of the 2002 IEEE/RSJ Conf., Lausanne, 2002, pp. 2478-2483.
[34] Arnott J.L., "Intelligent Systems and Disability - The Research Challenge", Proc. of the 1995 Int. Conf. on Systems, Man and Cybernetics, 1995, pp. 2390-2395.