Complex conjugate vector space

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In mathematics, one associates to every complex vector space V its complex conjugate vector space V*, again a complex vector space. The underlying set of vectors and the addition of V* are the same as those of V, and the scalar multiplication in V* is defined as follows:

to multiply the complex number α with the vector x in V*, take the complex conjugate α* of α and multiply it with x in the original space V.

The map * : VV* defined by x* = x for all x in V is then bijective and antilinear. Furthermore, we have V** = V and x** = x for all x in V.

Given any other bijective antilinear map from V to some vector space W, we can show that W and V* are isomorphic as complex vector spaces.

Given a linear map f : VW, the conjugate linear map f* : V*W* is defined as follows:

f * (x * ) = f(x) * .

As you may verify for yourself, f* is a linear map and * becomes a functor from the category of C-vector spaces to itself.

If V and W are finite-dimensional and the map f is described by the matrix A with respect to the bases B of V and C of W, then the map f* is described by the complex conjugate of A with respect to the bases B* of V* and C* of W*.

Note that V and V* have the same dimension over C and are therefore isomorphic as C vector spaces. However, there is no natural isomorphism from V to V*.

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