Stewart Dickson
23115 Bluebird Drive
Calabasas, CA  91302
(818)223-9117
Stewart.Dickson@disney.com
Contact: The Williams Gallery.

Portfolio of Fermat's Last Theorem

(updated 28 June, 1999)

Artist's Statement

Complex Projective Varieties Determined by x^3 + y^3 = z^3 (Fermat's Last Theorem), n = 3, Stereoscopic Mathematica computer rendering, (c) 1990 Andrew Hanson, Stewart Dickson. Press Here for price list.

The core Mathematica code for the visualization was devised by Andrew Hanson, Indiana University.

hanson@cs.indiana.edu
The image was rendered by Stewart Dickson using the Mathematica system for doing mathematics by computer on a Silicon Graphics 4D/25TG Personal Iris.

Complex Projective Varieties Determined by x^3 + y^3 = z^3 (Fermat's Last Theorem), n = 3. 8.5" X 6.0" X 6.0", Stereolithograph, (c) 1991 Andrew Hanson, Stewart Dickson. Press Here for price list.

The core Mathematica code for the visualization was devised by Andrew Hanson, Indiana University.

hanson@iuvax.cs.indiana.edu
The Three-dimensional computer database for the surface was adapted for sculpture by Stewart Dickson.

Software/Hardware used: The Mathematica system for doing mathematics by computer, Silicon Graphics 4D/25TG Personal Iris. Mathematica- Wavefront-Stereolithography data interface by Stewart Dickson. Stereolithography by SLA-500 system at Hughes Aircraft Company, El Segundo, California, funding by ACM/SIGGRAPH Special Projects Committee, T. Defanti, Chair.

Complex Projective Varieties Determined by x^5 + y^5 = Z^5 (Fermat's Last Theorem), n = 5, Stereoscopic Mathematica computer rendering, (c) 1990 Andrew Hanson, Stewart Dickson. Press Here for price list.

The core Mathematica code for the visualization was devised by Andrew Hanson, Indiana University.

hanson@cs.indiana.edu
The image was rendered by Stewart Dickson using the Mathematica system for doing mathematics by computer on a Silicon Graphics 4D/25TG Personal Iris.

Complex Projective Varieties Determined by x^5 + y^5 = Z^5 (Fermat's Last Theorem), n = 5. 9.0" X 6.8" X 6.8", Stereolithograph, (c) 1991 Andrew Hanson, Stewart Dickson. Press Here for price list.

The core Mathematica code for the visualization was devised by Andrew Hanson, Indiana University.

hanson@cs.indiana.edu
The three-dimensional computer database for the surface was adapted for sculpture by Stewart Dickson.

Software/Hardware used: The Mathematica system for doing mathematics by computer, Silicon Graphics 4D/25TG Personal Iris. Mathematica-Wavefront-Stereolithography data interface by Stewart Dickson. Stereolithography by SLA-500 system at Hughes Aircraft Company, El Segundo, California, funding by ACM/SIGGRAPH Special Projects Committee, T. Defanti, Chair.

A 3-D Zoetrope, Computer-Rendered Proposal.

Complex Projective Varieties Determined by x^7 + y^7 = Z^7 (Fermat's Last Theorem), n = 7, Mathematica computer rendering, (c) 1990 Andrew Hanson, Stewart Dickson.

The core Mathematica code for the visualization was devised by Andrew Hanson, Indiana University.

hanson@cs.indiana.edu
The image was rendered by Stewart Dickson using the Mathematica system for doing mathematics by computer on a Silicon Graphics 4D/25TG Personal Iris.

Complex Projective Varieties Determined by x^9 + y^9 = Z^9 (Fermat's Last Theorem), n = 9, Mathematica computer rendering, (c) 1990 Andrew Hanson, Stewart Dickson.

The core Mathematica code for the visualization was devised by Andrew Hanson, Indiana University.

hanson@iuvax.cs.indiana.edu
The image was rendered by Stewart Dickson using theMathematica system for doing mathematics by computer on a Silicon Graphics 4D/25TG Personal Iris.

Contact: The Williams Gallery.

Press Here to go to Mathart.org home page.

Press Here to go to Stewart Dickson's General Portfolio