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Elastostatic contact imaging for a mechanoreceptive tactile device

Published online by Cambridge University Press:  09 March 2009

M. Mehdian ,
P.M. Johns-Rahnejat  and
H. Rahnejat
M. Mehdian
Affiliation:
Robotics & Machine Intelligence Group, School of Engineering, University of Greenwich, Woolwich, London SE18 6PF(UK).
P.M. Johns-Rahnejat
Affiliation:
Department of Mechanical Engineering, Imperial College of Science, Technology & Medicine, Exhibition Road, London SW7 2BX(UK).
H. Rahnejat
Affiliation:
TEDAS Ltd, University of Warwick Science Park, Sir William Lyons Road, Coventry CV47EZ (UK).
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Summary

This paper presents a sensory gripper, consisting of two tactile sensing matrices which acquire three dimensional images of objects of interest. The image processing algorithm uses elastostatic contact information to discriminate among a host of parts made of different materials. The algorithm also enables the assessment of orientation of parts without the pre-requisite of having to recognise them. The positions of stable holdsites and a safe gripping force are also evaluated.

Keywords

Imaging; Sensory gripper; Electrostatic contact.
Type
Research Article
Information
Robotica , Volume 11 , Issue 4 , July 1993 , pp. 329 - 337
Copyright
Copyright © Cambridge University Press 1993

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References

[1]Harmon, L.D., “Automated Tactile SensingInt. J. Robotics Res. 1(2), 332 (1982).CrossRefGoogle Scholar
[2]Foroughi, F., Rahnejat, H. and Bera, H., “Tactile Sensors for Robot HandlingProc. Instn. Mech. Engrs. 201(B/B1), 53–59 (1987).Google Scholar
[3]Mehdian, M. and Rahnejat, H., “A Tactile Sensor with Automatic Learning Capability for Industrial Parts InspectionInt. J. AMT 2(4), 1126 (1987).Google Scholar
[4]Sato, N., Heginbotham, W.B. and Pugh, A., “A Method for Three Dimensional Part Identification by Tactile Trans-ducerProc. 7th Int. Sympos. on Industrial Robots (1977) pp. 123129.Google Scholar
[5]Rahnejat, H. and Bera, H., “Sensors, Special Purpose” Encyclopedia of Robotics (John Wiley & Sons, New York, 1988).Google Scholar
[6]Benhadj, R., Sadeque, S. and Rahnejat, H., “A Knowledge-Based System for Sensor Interaction and Real-Time Component ControlInt. J. AMT 3(1), 1429 (1988).Google Scholar
[7]Abu-Mostafa, Y.S. and Psaltis, D., “Image Normalisation by Complex MomentsIEEE Trans, on Pattern Ana. & Mach. Intell. PAMI–7(1), 423434 (1985).Google Scholar
[8]Checinski, S.S. and Agrawal, A.K., “Magnetoelastic Tactile Sensor” 3rd Int. Conf. on Robot Vision & Sensory Contr. (ROVISEC-3), Cambridge, MASS. (1983), pp. 348359.Google Scholar
[9]Hanafusa, H. and Asada, H., “An Adaptive Control of Robot Hand Equipped With Pneumatic Proximity Sensors”, 3rd Int. Conf. on Industrial Robots Tokyo, (1978) 564–576.Google Scholar
[10]Mehdian, M. and Rahnejat, H., “A Sensory Gripper Using Tactile Sensors for Object Recognition, Orientation and Stable ManipulationIEEE Trans. Man, Mach & Cyber. 19, No. 5, 12501261 (1989).CrossRefGoogle Scholar
[11]Boussinesq, J., Application des Potentials a VEtude de Equilibre et du Mouvement des Solides Elastiques (Gauthier-Villars, Paris 1885).Google Scholar
[12]Hu, M.K., “Visual Pattern Recognition by Moment InvariantsIRE Trans, on Info. Theory IT-8, 106117 (1962).Google Scholar
[13]Timoshenko, S.P. and Goodier, J.N., Theory of Elasticity 3rd Edition (McGraw-Hill, San Francisco, 1970).Google Scholar