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A tactile sensor based on thin-plate deformation

Published online by Cambridge University Press:  09 March 2009

R.E. Ellis ,
S.R. Ganeshan  and
S.J. Lederman
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Summary

Traditionally, tactile sensors have been designed using compliant, rubber-like materials; when such a sensitized gripper grasps or otherwise manipulates an object, the normal strain deformation in the compliant material is sampled. The resulting information can be used to deduce simple local geometry of the contact, but the transduction process does not typically permit use of the individual strains in determining large-scale properties of the object (e.g., the inertia). Measurements of inertial parameters of grasped objects require accurate, low-hysteresis transduction that few tactile sensors currently provide.

An alternative is to work from the task specification, and determine the tactile information that is necessary to accomplish the task. Here, we consider how to sense the length and mass of a uniform object that is gripped in a gravitational field, and show the design and assessment of a new kind of tactile sensor that is based on the theory of the deformation of thin plates. Features of this design include its potentially rugged realization, and its high-accuracy measurement that is more typical of force sensors than of tactile sensors.

Keywords

Tactile sensorThin-platē deformationHigh accuracy.
Type
Article
Information
Robotica , Volume 12 , Issue 4 , July 1994 , pp. 343 - 351
Copyright
Copyright © Cambridge University Press 1994

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References

1.Dario, P. and Rossi, D. De, “Tactile sensors and the gripping challengeIEEE Spectrum 22(8), 4652 (1985).Google Scholar
2.Fearing, R.S. and Hollerbach, J.M., “Basic solid mechanics for tactile sensingInt. J. Robotics Research 5(3), 4054 (1984).Google Scholar
3.Gurfinkel, V.S., Shneyder, Yu., Kanayev, Ye.M. and Gurfinkel, Ye.V., “Tactile sensitizing of manipulatorsEngineering Cybernetics, 12(6), 4756 (1974).Google Scholar
4.Hackwood, S. and Beni, G., “Sensor and high-precision robotics research” In: (Brady, M. and Paul, R., editors) Robotics Research (MIT Press, Cambridge, MA, 1984) pp. 509527.Google Scholar
5.Harmon, L.D., “A sense of touch begins to gather momentumSensor Review 1(2), 8288 (1981).Google Scholar
6.Rossi, D. De, “Artificial tactile sensing and haptic perceptionIn: Measurement Science and Technology, volume 2 (1991) pp. 10031016.Google Scholar
7.Nicholls, H.R. and Lee, M.H., “A survey of robot tactile sensing technologyInt. J. Robotics Research, 8(3), 330 (1989).Google Scholar
8.Hillis, D.W., “A high-resolution imaging touch sensorInt. J. Robotics Research, 1(2), 3344 (1982).CrossRefGoogle Scholar
9.Raibert, M.H. and Tanner, J.E., “Design and implementation of a VLSI tactile sensing computerInt. J. Robotics Research 1(3), 318 (1982).CrossRefGoogle Scholar
10.Speeter, T.H., “A tactile sensing system for robotic manipulationInt. J. Robotics Research 9(6), 2536 (1990).Google Scholar
11.Tamai, T., “Electrical properties of conductive elastomer as electrical contact matẹalIEEE Transactions on Components, Hybrids, and Manufacturing Technology, 5, 5661 (1982).CrossRefGoogle Scholar
12.Tise, B., “A compact, high resolution piezoresistive digital tactile sensorProceedings of the IEEE International Conference on Robotics and Automation (1988) pp. 760764.Google Scholar
13.Wong, K. and Spiegel, J. Van der, “A shielded piezoresistive tactile sensor arrayProceedings of the IEEE International Conference on Solid-State Sensors and Actuators (1985) pp. 2629.Google Scholar
14.Begej, S., “Planar and finger-shaped optical tactile sensors for robotic applicationsIEEE J. Robotics and Automation, 4, 472484 (1988).Google Scholar
15.King, A.A. and White, R.M., “Tactile sensing array based on forming and detecting an optical imageSensors and Actuators 8, 4963 (1985).CrossRefGoogle Scholar
16.Mott, D.H., Lee, M.H. and Nicholls, H.R., “An experimental very high resolution tactile sensor array” In: (Pugh, A., editor) Robot Sensors Vol. 2: Tactile and Non-Vision (Springer-Verlag, Berlin, 1985) pp. 179188.Google Scholar
17.Schoenwald, J.S., Thiele, A.W. and Gjellum, D.E., “A novel fiber optic tactile array sensorProceedings of the IEEE international Conference on Robotics and Automa-don (1987) pp. 17921797.Google Scholar
18.Winger, J.G. and Lee, K.-M., “Experimental investigation of a tactile sensor based on bending losses in fiber opticsProceedings of the IEEE International Conference on Robotics and Automation (1988) pp. 754759.Google Scholar
19.Jenstrom, D.T. and Chen, C.-T., “A fiber optic microbend tactile sensor arraySensors and Actuators, 20, 239248 (1989).Google Scholar
20.Rebman, J. and Morris, K.A., “A tactile sensor with electrooptical transduction” In: (Pugh, A., editor) Robot Sensors Vol. 2: Tactile and Non-Vision (Springer-Verlag, Berlin, 1985) pp. 145155.Google Scholar
21.Bertholds, A. and Daniker, R.High-resolution photoelastic pressure sensor using low-birefringence fiberApplied Optics, 25(3), 340343 (1987).CrossRefGoogle Scholar
22.Eghtedari, F. and Morgan, C., “A novel tactile sensor for robot applicationsRobotica 7, Part 4, 289295 (1989).Google Scholar
23.Boie, R.A., “Capacitive impedance readout tactile image sensorProceedings of the IEEE International Conference on Robotics and Automation (1984) pp. 370378.Google Scholar
24.Chun, K.J. and Wise, K.D., “A high performance silicon tactile imager based on a capacitive cellIEEE Transactions on Electronic Devices 32, 11961201 (1985).CrossRefGoogle Scholar
25.Fearing, R.S., “Tactile sensing mechanismsInt. J. Robotics Research 9(3), 323 (1990).CrossRefGoogle Scholar
26.Checinski, S.S. and Agrawal, A.K., “Magnetoelastic tactile sensor” In: (Pugh, A., editor) Robot Sensors Vol. 2: Tactile and Non-Vision (Springer-Verlag, Berlin, 1985) pp. 229235.Google Scholar
27.Luo, R.-C., Wang, F: and Liu, Y., “An imaging tactile sensor with magnetoresistive transduction” In: (Pugh, A., editor) Robot Sensors Vol. 2: Tactile and Non-Vision (Springer-Verlag, Berlin, 1985) pp. 113122.Google Scholar
28.Vranish, J.M., “Magnetoresistíve skin for robots” In: (Pugh, A., editor), Robot Sensors Vol. 2: Tactile and Non-Vision (Springer-Verlag, Berlin, 1985) pp. 99111.Google Scholar
29.Dario, P., Bardelli, R., Rossi, D. De, Wang, L. R. and Pinotti, P.C., “Touch-sensitive polymer skin uses piezoelectric properties to recognize orientation of objectsSensor Review 2(4), 194198 (1982).Google Scholar
30.Howe, R. and Cutkosky, M., “Sensing skin acceleration for texture and slip perceptionProceedings of the IEEE International Conference on Robotics and Automation (1989) pp. 145150.Google Scholar
31.Rossi, D. De, Lazzeri, L., Domenici, A., Nannini, C. and Basser, P., “Tactile sensing by an electromechanochemical skin analogSensors and Actuators 17, 107114 (1989).Google Scholar
32.Helsel, M., Zemel, J.N. and Dominko, V., “An impedence tomographic tactile sensorSensors and Actuators 14, 9398 (1988).CrossRefGoogle Scholar
33.Patterson, R.W. and Nevill, G.E. Jr., “The induced vibration touch sensor - a new dynamic touch sensing conceptRobotica 4(4), 2731 (1985).CrossRefGoogle Scholar
34.Zhu, F. and Spronck, J.W., “A capacitive tactile sensor for shear and normal force measurementsSensors and Actuators: A, 31, 115120 (1992).CrossRefGoogle Scholar
35.Novak, J.L., “Initial design and analysis of a capacitive sensor for shear and normal force measurementProceedings of the IEEE international Conference on Robotics and Automation (1989) pp. 137144.Google Scholar
36.Hackwood, S., Beni, G., Honrak, L.A., Wolfe, R. and Nelson, T.J.A torque-sensitive tactile array for roboticsInt. J. Robotics Research 2(2) 4650 (1983).CrossRefGoogle Scholar
37.Domenici, C. and Rossi, D. De, “A stress-componentselective tactile sensor arraySensors and Actuators A, 31, 97100 (1992).Google Scholar
38.Russell, R.A., “Thermal sensor for object shape and material constitutionRobotica 4(4), 3134 (1985).Google Scholar
39.Jeswiet, J. and Nshama, W., “A robot force/temperature sensing gripper for heavy industryProceedings of the international Conference on Robot Vision and Sensory Controls (1986) pp. 151156.Google Scholar
40.Siegel, D.M., Drucker, S.M. and Garabieta, I., “Performance of a tactile sensorProceedings of the IEEE on International Conference on Robotics and Automation (1987) pp. 14931499.Google Scholar
41.Brock, D.L. and Chics, S., “Environment perception of an articulated robot hand using contact sensorsProceedings of the ASME Winter Annual Conference (1985) pp. 18.Google Scholar
42.Okada, T., “A new tactile sensor design based on suspension shells” In: (Venkataraman, S.T. and Iberall, T., editors) Dextrous Robot Hands (Springer-Verlag, Berlin, 1990) pp. 267285.CrossRefGoogle Scholar
43.Russell, R.A.Using tactile whiskers to measure surface contoursProceedings of the IEEE international Conference on Robotics and Automation (1992) pp. 12951299.Google Scholar
44.Lederman, S.J., Ganeshan, S.R. and Ellis, R.E., “Haptic length perception of statistically held rods: equilibrium mechanics and psychophysical evalutionJ. Exper. Psychology: Human Perception and Performance, 1993. (in submission).Google Scholar
45.Wang, C.K.Statically Indeterminate Structures (McGraw-Hill, New York, 1962).Google Scholar
46.Timoshenko, S.P. and Woinowsky-Krieger, S., Theory of Plates and Shells (McGraw-Hill, New York, 1970).Google Scholar
47.Ganeshan, S.R., “Robotic and haptic perception of length of statically held objects”, Master's Thesis (Queen's University at Kingston, 1992).Google Scholar