Mathematical foundation for representing propagation of geometric tolerances

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Mathematical foundation for representing propagation of geometric tolerances

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ACM Symposium on Solid and Physical Modeling archive
Proceedings of the fourth ACM symposium on Solid modeling and applications table of contents

Atlanta, Georgia, United States

Pages: 240 - 247

Year of Publication: 1997

ISBN:0-89791-946-7

Authors

Sangho Park	Computer Graphics Laboratory, Systems Engineering Research Institute, Korea
Kunwoo Lee	Department of Mechanical Design and Production Engineering, Seoul National University, Korea

Sponsor

SIGGRAPH: ACM Special Interest Group on Computer Graphics and Interactive Techniques

Publisher

ACM New York, NY, USA

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REFERENCES

Note: OCR errors may be found in this Reference List extracted from the full text article. ACM has opted to expose the complete List rather than only correct and linked references.

	1	A.A.G. Requicha. Toward a theory of geometric tolerance. International Journal of Robotic Research, 2(4):45-60, 1983.
	2	J R Rossignac , A A G Requicha, Offsetting operations in solid modelling, Computer Aided Geometric Design, v.3 n.2, p.129-148, August 1986 [doi>10.1016/0167-8396(86)90017-8 ]
	3	M. Boyer , N. F. Stewart, Modeling spaces for toleranced objects, International Journal of Robotics Research, v.10 n.5, p.570-582, Oct. 1991 [doi>10.1177/027836499101000512]
	4	N.F. Stewart. Sufficient condition for correct topological form in tolerance specification. Computer Aided Design, 25(1):39-48, January 1993.
	5	F. Etesami. Tolerance verification through manufactured part modeling. Journal of Manufacturing System, 7(3):223-232, 1988.
	6	N.S. Bernstein and K. Preiss. Representation of tolerance information in solid models. In ASME 15th Design Automation Conf., pages 37-48. ASME, 1989.
	7	D.E. Whitney and O.L. Gilbert. Representation of geometric variations using matrix transformations for statistical tolerance analysis assemblies. In IEEE international Conference on Robotics and Automation, volume 2, pages 314-321, 1993.
	8	A. Wirtz. Vectorial tolerancing for quality control and functional analysis in design. In CIRP International Working Seminar on Computer Aided Tolerancing, PennState University, May 1991.
	9	J.U. Turner. A feasibility space approach for automated tolerancing. Journal of Engineering for Industry, 115:341-346, August 1993.
	10	V. Srinivasan , R. Jayaraman, Geometric tolerancing: 2. conditional tolerances, IBM Journal of Research and Development, v.33 n.2, p.105-124, March 1989
	11	R. Jayaraman , R. Srinivasan, Geometric tolerancing: 1. Virtual boundary requirements, IBM Journal of Research and Development, v.33 n.2, p.90-104, March 1989
	12	Richard P. Paul, Robot Manipulators: Mathematics, Programming, and Control, MIT Press, Cambridge, MA, 1982
	13	ISO. ISO standards.