In Computer-Aided Design applications there is often a need to compute the union, intersection and Merence of two polygons or polyhedra. The sequential algorithms for this problem are characterized by poor speed of response and large computational complexity. In order to remove these defects, an algorithm amenable to implementation on a parallel architecture is proposed. The parallel architecture designed is a systolic one which forms a dedicated subsystem to perform set-theoretic operations on polygons. The improvement in speed gained by using the systolic array as compared to a uniprocessor has been evaluated using simulation techniques. Extensions of this architecture to perform the same operations on polyhedra are also discussed.

References

1 EE. Barton and I. Buchanan, “The polygon package,” Computer-Aided Design 12(2), pp. 3–11 (January 1980).
10.1016/0010-4485(80)90211-0
Web of Science® Google Scholar
2 I.E. Sutherland, “ The polygon package Technical Report, California Institute of Technology (1978).
Google Scholar
3 J. Bentley and D. Wood, “An optimal worst-case algorithm for reporting intersections of rectangles,” IEEE Transactions on Computers C-29(7), pp. 571–576 (July 1980).
10.1109/TC.1980.1675628
Web of Science® Google Scholar
4 J. Nievergelt and F.P. Preparata, “Plane sweq, algorithms for intersecting geometric figures,” Communications ACM 25(10), pp. 739–747 (October 1982).
10.1145/358656.358681
Web of Science® Google Scholar
5 M. Mantyla, “Set operations of GWB,” Computer Graphics Forum 2(2–3) (August 1983).
Google Scholar
6 R.B. Tilove, “Set membership classification: A unified appraoch to geometric intersection problems,” IEEE Transactions on Computers C-29(10), pp. 874–883 (October 1980).
10.1109/TC.1980.1675470
Web of Science® Google Scholar
7 R.B. Tilove, “ Exploiting structural and spatial locality in geometric modelling,” Production Automatton Project, University of Rochester TM-38 (October 1981).
Google Scholar
8 H.T. Kung, “ Why systolic architectures?,” IEEE Computer, pp. 37–46 (July 1982).
Google Scholar
9 L.M. Patnaik, R.S. Shenoy, and D. Krishnan, “Set-theoretic operations on polygons using the scan-grid approach,” Computer-Aided Design 18(6) (June 1986).
Google Scholar
10 R.B. Tilove and A.A.G. Reaquicha, “Closure of boolean operations on geometric entities,” Computer-Aided Design 12(5), pp. 219–220 (September 1980).
10.1016/0010-4485(80)90025-1
Web of Science® Google Scholar
11 H.T. Kung, “The structure of parallel algorithms,” Advances in Computers. 19, pp. 65–108 (1980).
10.1016/S0065-2458(08)60033-9
Google Scholar
12 G.C. Roman and T. Kimura, “ A VLSI perspective of hidden surface elimination. Rep. WUCS-79–2, Washington , Department of Computer Science (January 1980).
Google Scholar
13 Li Tao, K.F. Smith, and D. Hanscon, “ VLSI systolic architecture for computer graphics,” Proceedings of the International Conference on Computers, Banalore , India , Systems and Signal Processing (December 1984).
Google Scholar

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Volume6, Issue3

September 1987

Pages 203-210

Systolic Architecture for Boolean Operations on Polygons and Polyhedra

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Systolic Architecture for Boolean Operations on Polygons and Polyhedra

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