Sage Journals: Discover world-class research

Abstract

Manual drafting is rapidly being replaced by modern, computerized systems for defining the geometry of mechanical parts and assemblies, and a new generation of powerful systems, called geometric (solid) modeling systems (GMSs), is entering industrial use. Solid models are beginning to play an important role in off-line robot programming, model- driven vision, and other industrial robotic applications.

A major deficiency of current GMSs is their lack of facilities for specifying tolerancing information, which is essential for design analysis, process planning, assembly planning for tightly toleranced components, and other applications of solid modeling. This paper proposes a mathe matical theory of tolerancing that formalizes and generalizes current practices and is a suitable basis for incorporating tolerances into GMSs.

A tolerance specification in the proposed theory is a collection ofgeometric constraints on an object's surface features, which are two-dimensional subsets of the object's boundary. An object is in tolerance if its surface features lie within tolerance zones, which are regions of space constructed by offsetting (expanding or shrinking) the object's nominal boundaries.

Get full access to this article

View all access options for this article.

References

American National Standards Institute (ANSI). 1973. Dimensioning and tolerancing. ANSI Standard Y 14.5-1973 . New York: American Society of Mechanical Engineers. (ANSI Y14.5-1983 has just become available.)

Brooks, R.A. 1981. Symbolic reasoning among 3-D models and 2-D images. Artificial Intell. 17(1-3):285 - 348.

Brooks, R.A. 1982. Symbolic error analysis and robot planning. Int. J. Robotics Res. 1(4):29-68.

Brown, C.M. 1982. PADL-2: A technical summary. IEEE Comput. Graphics Appl. 2(2):69-84.

Fitzgerald, W.J. 1981. Using axial dimensions to determine the proportions of line drawings in computer graphics. Computer Aided Design 13(6):377 - 382.

Hillyard, R.C. 1978. Dimensions and tolerances in shape design. Ph.D. dissertation, University of Cambridge, U.K.

Hillyard, R.C. , and Braid, I.C. 1978a. Analysis of dimensions and tolerances in computer-aided mechanical design. Computer Aided Design 10(3):161-166.

Hillyard, R.C. , and Braid, I.C. 1978b. Characterizing non-ideal shapes in terms of dimensions and tolerances. ACM Computer Graphics 12(3):234-238.

Hoffman, P. 1982. Analysis of tolerance and process inaccuracies in discrete part manufacturing. Computer Aided Design 14(2): 83 - 88.

10.

Lee, Y.T. , and Requicha, A.A.G. 1982. Algorithms for computing the volume and other integral properties of solids. II: A family of algorithms based on representation conversion and cellular approximation. Commun. ACM 25(9):642-650.

11.

Levy, S.J. 1974. Applied geometric tolerancing. Beverly, Mass.: TAD Products.

12.

Lin, V.C. , Gossard, D.C. , and Light, R.A. 1981. Variational geometry in computer aided design. ACM Computer Graphics 15(3):171-177.

13.

Lozano-Pérez, T. , and Wesley, M.A. 1979. An algorithm for planning collision-free paths among polyhedral obstacles. Commun. ACM 22( 10):560- 570.

14.

Nadler, S.B. Jr. 1978. Hyperspaces of sets. New York: Dekker.

15.

Requicha, A.A.G. 1977a. Part & assembly description languages. I: Dimensioning & tolerancing. Tech. Memo. No. 19, Production Automation Project. Rochester, N.Y.: University of Rochester.

16.

Requicha, A.A.G. 1977b. Mathematical models of rigid solid objects. Tech. Memo. No. 28, Production Automation Project. Rochester, N.Y. : University of Rochester.

17.

Requicha, A.A.G. 1980. Representations for rigid solids: Theory, methods, and systems. ACM Computing Surveys 12(4):437-464.

18.

Requicha, A.A.G. 1983 (Sept. 26-27). Representation of tolerances in solid modeling: Issues and alternative approaches. Paper delivered at General Motors Solid Modeling Symposium, Warren, Mich . Also forthcoming in Solid modeling by computers: From theory to applications, ed. J. W. Boyse and M. S. Pickett. New York : Plenum.

19.

Requicha, A.A.G. , and Voelcker, H.B. 1982. Solid modeling: A historical summary and contemporary assessment. IEEE Comput. Graphics Appl. 2(2):9-24.

20.

Silva, C.E. 1981. Alternative definitions of faces in boundary representations of solid objects. Tech. Memo. No. 36, Production Automation Project. Rochester, N.Y.: University of Rochester.

21.

Tilove, R.B. 1980. Set membership classification: A unified approach to geometric intersection problems. IEEE Trans. Comput. C-29(10):874-883.

Toward a Theory of Geometric Tolerancing

Abstract

Get full access to this article

References