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2. Plücker coordinates - Wikipedia

   en.wikipedia.org/wiki/Plücker_coordinates

   Because they satisfy a quadratic constraint, they establish a one-to-one correspondence between the 4-dimensional space of lines in ⁠ ⁠ and points on a quadric in ⁠ ⁠ (projective 5-space). A predecessor and special case of Grassmann coordinates (which describe k -dimensional linear subspaces, or flats , in an n -dimensional Euclidean ...

3. PG (3,2) - Wikipedia

   en.wikipedia.org/wiki/PG(3,2)

   In finite geometry, PG(3, 2) is the smallest three-dimensional projective space. It can be thought of as an extension of the Fano plane. It has 15 points, 35 lines, and 15 planes. [1] It also has the following properties: [2] Each point is contained in 7 lines and 7 planes. Each line is contained in 3 planes and contains 3 points.

4. Correlation (projective geometry) - Wikipedia

   en.wikipedia.org/wiki/Correlation_(projective...

   In a 3-dimensional projective space a correlation maps a point to a plane.As stated in one textbook: [2] If κ is such a correlation, every point P is transformed by it into a plane π′ = κP, and conversely, every point P arises from a unique plane π′ by the inverse transformation κ −1.

5. Fano plane - Wikipedia

   en.wikipedia.org/wiki/Fano_plane

   The Fano plane can be extended in a third dimension to form a three-dimensional projective space, denoted by PG(3, 2). It has 15 points, 35 lines, and 15 planes and is the smallest three-dimensional projective space. [16] It also has the following properties: [17] Each point is contained in 7 lines and 7 planes.

6. Projective geometry - Wikipedia

   en.wikipedia.org/wiki/Projective_geometry

   The only projective geometry of dimension 0 is a single point. A projective geometry of dimension 1 consists of a single line containing at least 3 points. The geometric construction of arithmetic operations cannot be performed in either of these cases. For dimension 2, there is a rich structure in virtue of the absence of Desargues' Theorem.

7. Klein quadric - Wikipedia

   en.wikipedia.org/wiki/Klein_quadric

   The geometry of S is retrieved as follows: The points of S are the planes in C. The lines of S are the points of Q. The planes of S are the planes in C′. The fact that the geometries of S and Q are isomorphic can be explained by the isomorphism of the Dynkin diagrams A 3 and D 3.

8. Reye configuration - Wikipedia

   en.wikipedia.org/wiki/Reye_configuration

   The Reye configuration can be realized in three-dimensional projective space by taking the lines to be the 12 edges and four long diagonals of a cube, and the points as the eight vertices of the cube, its center, and the three points where groups of four parallel cube edges meet the plane at infinity.

9. Duality (projective geometry) - Wikipedia

   en.wikipedia.org/wiki/Duality_(projective_geometry)

   Another way to put it is that the points of n-dimensional projective space are the 1-dimensional vector subspaces, which may be visualized as the lines through the origin in K n+1. [10] Also the n - (vector) dimensional subspaces of K n+1 represent the (n − 1)- (geometric) dimensional hyperplanes of projective n-space over K, i.e., PG(n, K).