# Projection of a Torus

(Difference between revisions)
 Revision as of 15:44, 4 June 2009 (edit)← Previous diff Revision as of 10:38, 5 June 2009 (edit) (undo)Next diff → Line 6: Line 6: A similar process is carried out to create this page's main image. A four-dimensional object, described further below, is projected into three-dimensions using two different projections. A similar process is carried out to create this page's main image. A four-dimensional object, described further below, is projected into three-dimensions using two different projections. - |ImageDesc=The four-dimensional object is defined parametrically by $(x_1,x_2,x_3,x_4)=(cos(u),sin(u),cos(v),sin(v))$. A [[stereographic projection]] is used to map this 4-d object into 3-d, using a projection point of $(0,0,0,\sqrt{2})$ for the first object in this page's main image. This projection is centered above the four-dimensional object, projecting the symmetric torus into three-dimensional space. The projection point is shifted to be closer to one part of the four-dimensional object than the other to create the second object in the main image, projecting an uneven object into three-dimensional space. + |ImageDesc=The four-dimensional object is defined parametrically by $(x_1,x_2,x_3,x_4)=(cos(u),sin(u),cos(v),sin(v))$. A [[Stereographic Projection| stereographic projection]] is used to map this 4-d object into 3-d, using a projection point of $(0,0,0,\sqrt{2})$ for the first object in this page's main image. This projection is centered above the four-dimensional object, projecting the symmetric torus into three-dimensional space. The projection point is shifted to be closer to one part of the four-dimensional object than the other to create the second object in the main image, projecting an uneven object into three-dimensional space. |AuthorName=Thomas F. Banchoff |AuthorName=Thomas F. Banchoff |AuthorDesc=Thomas F. Banchoff is a geometer, and a professor at Brown University since 1967. |AuthorDesc=Thomas F. Banchoff is a geometer, and a professor at Brown University since 1967.

## Revision as of 10:38, 5 June 2009

Projection of a Torus
A four-dimensional torus projected into three-dimensional space.

# Basic Description

It is impossible to visualize a complete four-dimensional object, since we have only ever lived in three-dimensional space. However, there are ways to capture parts of the four-dimensional object in three-dimensional space. A useful analogy is a world map. We can capture the essence of the three-dimensional globe on a two-dimensional map, but only by using a projection, which distorts the three-dimensional object in some way to fit on a two-dimensional surface.

A similar process is carried out to create this page's main image. A four-dimensional object, described further below, is projected into three-dimensions using two different projections.

# A More Mathematical Explanation

The four-dimensional object is defined parametrically by $(x_1,x_2,x_3,x_4)=(cos(u),sin(u),cos(v),sin(v))$. [...]

The four-dimensional object is defined parametrically by $(x_1,x_2,x_3,x_4)=(cos(u),sin(u),cos(v),sin(v))$. A stereographic projection is used to map this 4-d object into 3-d, using a projection point of $(0,0,0,\sqrt{2})$ for the first object in this page's main image. This projection is centered above the four-dimensional object, projecting the symmetric torus into three-dimensional space. The projection point is shifted to be closer to one part of the four-dimensional object than the other to create the second object in the main image, projecting an uneven object into three-dimensional space.

# Teaching Materials

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# About the Creator of this Image

Thomas F. Banchoff is a geometer, and a professor at Brown University since 1967.

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