Complex Projective Varieties Determined by x^3 + y^3 = z^3
(Fermat's Last Theorem), n = 3,
Stereoscopic Mathematica computer rendering,
Harvest Fine Art Print on archival paper, (c) 1990
Andrew Hanson,
Stewart Dickson.
Stewart Dickson 60 Chestnut Court Champaign, IL 61822 USA +1(217)607-1024 mathart(a)emsh.calarts.eduContact: Impression3D.com
Complex Projective Varieties Determined by x^3 + y^3 = z^3
(Fermat's Last Theorem), n = 3,
Stereoscopic Mathematica computer rendering,
Harvest Fine Art Print on archival paper, (c) 1990
Andrew Hanson,
Stewart Dickson.
Press Here for more information. Press Here for price list.
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 more information. Press Here for price list.
Complex Projective Varieties Determined by x^5 + y^5 = Z^5
(Fermat's Last Theorem), n = 5,
Stereoscopic Mathematica computer rendering,
Harvest Fine Art Print on
archival paper, (c) 1990
Andrew Hanson, Stewart Dickson.
Press Here for more information. Press Here for price list.
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 more information. Press Here for price list.
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.
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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.
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