Clipping using homogeneous coordinates

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Clipping using homogeneous coordinates

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ACM SIGGRAPH Computer Graphics archive
Volume 12 , Issue 3 (August 1978) table of contents

Pages: 245 - 251

Year of Publication: 1978

ISSN:0097-8930

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Authors

James F. Blinn	Caltech/JPL
Martin E. Newell	XEROX/PARC

Publisher

ACM New York, NY, USA

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Downloads (6 Weeks): 14, Downloads (12 Months): 88, Citation Count: 8

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ABSTRACT

Clipping is the process of determining how much of a given line segment lies within the boundaries of the display screen. Homogeneous coordinates are a convenient mathematical device for representing and transforming objects. The space represented by homogeneous coordinates is not, however, a simple Euclidean 3-space. It is, in fact, analagous to a topological shape called a “projective plane”. The clipping problem is usually solved without consideration for the differences between Euclidean space and the space represented by homogeneous coordinates. For some constructions, this leads to errors in picture generation which show up as lines marked invisible when they should be visible. This paper will examine these cases and present techniques for correctly clipping the line segments.

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	Barr, S., Experiments in Topology, Thomas Y. Crowell Co., New York, 1964.
	2	Riesenfeld, R. F., "Homogeneous Coordinates and Projective Planes in Computer Graphics", JACM, to appear.
	3	Roberts, L. G., "Homogeneous Matrix Representation and Manipulation of N-Dimensional Constructs", MIT Lincoln Laboratory, MS 1405, May 1965.
	4	Ivan E. Sutherland , Gary W. Hodgman, Reentrant polygon clipping, Communications of the ACM, v.17 n.1, p.32-42, Jan. 1974 [doi>10.1145/360767.360802]

CITED BY 8

	B. A. Barsky, A New Concept and Method for Line Clipping, ACM Transactions on Graphics (TOG), v.3 n.1, p.1-22, Jan. 1984
	Ron Goldman, On the algebraic and geometric foundations of computer graphics, ACM Transactions on Graphics (TOG), v.21 n.1, p.52-86, January 2002
	Masatoshi Niizeki , Fujio Yamaguchi, Projectively invariant intersection detections for solid modeling, ACM Transactions on Graphics (TOG), v.13 n.3, p.277-299, July 1994
	IEEE Computer Graphics and Applications Staff, A Trip Down the Graphics Pipeline: Line Clipping, IEEE Computer Graphics and Applications, v.11 n.1, p.98-105, January 1991
	IEEE Computer Graphics and Applications, Fractional Invisibility, IEEE Computer Graphics and Applications, v.8 n.6, p.77-84, November 1988
	Peter Shirley, Data structures for graphics, ACM SIGGRAPH 2005 Courses, July 31-August 04, 2005, Los Angeles, California
	Curtis R. Priem, Developing the GX Graphics Accelerator Architecture, IEEE Micro, v.10 n.1, p.44-54, January 1990
	Arthur Appel , F. James Rohlf , Arthur J. Stein, The haloed line effect for hidden line elimination., ACM SIGGRAPH Computer Graphics, v.13 n.2, p.151-157, August 1979