File:GeometricProduct201.svg and Space-Antispace Transform Correspondence in Projective Geometric Algebra: Difference between pages
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Eric Lengyel (talk | contribs) (Created page with "'''By Eric Lengyel'''<br /> May 20, 2022 The concept of duality can be understood geometrically in an ''n''-dimensional projective setting by considering both the subspace that an object occupies and the complementary subspace that the object concurrently does not occupy. The dimensionalities of these two components always sum to ''n'', and they represent the ''space'' and ''antispace'' associated with the object. (Antispace is also known as negative space or counterspa...") |
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'''By Eric Lengyel'''<br /> | |||
May 20, 2022 | |||
The concept of duality can be understood geometrically in an ''n''-dimensional projective setting by considering both the subspace that an object occupies and the complementary subspace that the object concurrently does not occupy. The dimensionalities of these two components always sum to ''n'', and they represent the ''space'' and ''antispace'' associated with the object. (Antispace is also known as negative space or counterspace.) The example shown in Figure 1 demonstrates the duality between homogeneous points and lines in a three-dimensional projective space. The triplet of coordinates $$(p_x, p_y, p_z)$$ can be interpreted as a vector pointing from the origin toward a specific location on the projection plane $$z = 1$$. This vector corresponds to the one-dimensional space of the point that it represents. The dual of a point materializes when we consider all of the directions of space that are orthogonal to the single direction $$(p_x, p_y, p_z)$$. As illustrated by the figure, these directions span an $$(n - 1)$$-dimensional subspace that intersects the projection plane at a line when $$n = 3$$. In this way, the coordinates $$(p_x, p_y, p_z)$$ can be interpreted as both a point and a line, and they are ''duals'' of each other. | |||
Revision as of 02:19, 5 August 2023
By Eric Lengyel
May 20, 2022
The concept of duality can be understood geometrically in an n-dimensional projective setting by considering both the subspace that an object occupies and the complementary subspace that the object concurrently does not occupy. The dimensionalities of these two components always sum to n, and they represent the space and antispace associated with the object. (Antispace is also known as negative space or counterspace.) The example shown in Figure 1 demonstrates the duality between homogeneous points and lines in a three-dimensional projective space. The triplet of coordinates $$(p_x, p_y, p_z)$$ can be interpreted as a vector pointing from the origin toward a specific location on the projection plane $$z = 1$$. This vector corresponds to the one-dimensional space of the point that it represents. The dual of a point materializes when we consider all of the directions of space that are orthogonal to the single direction $$(p_x, p_y, p_z)$$. As illustrated by the figure, these directions span an $$(n - 1)$$-dimensional subspace that intersects the projection plane at a line when $$n = 3$$. In this way, the coordinates $$(p_x, p_y, p_z)$$ can be interpreted as both a point and a line, and they are duals of each other.
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