Complement (linear algebra): Difference between revisions
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In [[linear algebra]], a '''complement''' to a subspace of a vector space is another subspace which forms an internal direct sum. Two such spaces are mutually ''complementary''. | In [[linear algebra]], a '''complement''' to a subspace of a vector space is another subspace which forms an internal direct sum. Two such spaces are mutually ''complementary''. | ||
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:<math>U \cap W = \{0\} .\,</math> | :<math>U \cap W = \{0\} .\,</math> | ||
Equivalently, every element of ''V'' can be expressed uniquely as a sum of an element of ''U'' and an element of ''W''. The complementarity relation is [[symmetric]], that is, if ''W'' is a complement of ''U'' then ''U'' is also a complement of ''W''. | |||
If ''V'' is finite-dimensional then for complementary subspaces ''U'', ''W'' we have | If ''V'' is finite-dimensional then for complementary subspaces ''U'', ''W'' we have | ||
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In general a subspace does not have a unique complement (although the zero subspace and ''V'' itself are the unique complements each of the other). However, if ''V'' is in addition an [[inner product]] space, then there is a unique ''orthogonal complement'' | In general a subspace does not have a unique complement (although the zero subspace and ''V'' itself are the unique complements each of the other). However, if ''V'' is in addition an [[inner product]] space, then there is a unique ''orthogonal complement'' | ||
:<math>U^\perp = \{ v \in V : (v,u) = 0 \mbox{ for all } u \in U \} . \,</math> | :<math>U^\perp = \{ v \in V : (v,u) = 0 \mbox{ for all } u \in U \} . \,</math>[[Category:Suggestion Bot Tag]] | ||
Latest revision as of 11:00, 31 July 2024
In linear algebra, a complement to a subspace of a vector space is another subspace which forms an internal direct sum. Two such spaces are mutually complementary.
Formally, if U is a subspace of V, then W is a complement of U if and only if V is the direct sum of U and W, , that is:
Equivalently, every element of V can be expressed uniquely as a sum of an element of U and an element of W. The complementarity relation is symmetric, that is, if W is a complement of U then U is also a complement of W.
If V is finite-dimensional then for complementary subspaces U, W we have
In general a subspace does not have a unique complement (although the zero subspace and V itself are the unique complements each of the other). However, if V is in addition an inner product space, then there is a unique orthogonal complement
