Complex conjugate of a vector space explained

is a complex vector space

\overlineV

that has the same elements and additive group structure as

but whose scalar multiplication involves conjugation of the scalars. In other words, the scalar multiplication of

\overlineV

satisfies

\alpha\,*\, v =

where

is the scalar multiplication of

\overline{V}

and

⋅

is the scalar multiplication of

The letter

stands for a vector in

\alpha

is a complex number, and

\overline{\alpha}

denotes the complex conjugate of

\alpha.

^[1]

(different multiplication by

Motivation

and

are complex vector spaces, a function

f:V\toW

is antilinear if

f(v + w) = f(v) + f(w) \quad \text \quad f(\alpha v) = \overline \, f(v)

With the use of the conjugate vector space

\overlineV

, an antilinear map

f:V\toW

can be regarded as an ordinary linear map of type

\overline{V}\toW.

The linearity is checked by noting:

f(\alpha * v) = f(\overline \cdot v) = \overline \cdot f(v) = \alpha \cdot f(v)

Conversely, any linear map defined on

\overline{V}

gives rise to an antilinear map on

This is the same underlying principle as in defining the opposite ring so that a right

-module can be regarded as a left

R^op

-module, or that of an opposite category so that a contravariant functor

C\toD

can be regarded as an ordinary functor of type

C^op\toD.

Complex conjugation functor

A linear map

f:V\toW

gives rise to a corresponding linear map

\overline{f}:\overline{V}\to\overline{W}

that has the same action as

Note that

\overlinef

preserves scalar multiplication because

\overline(\alpha * v) = f(\overline \cdot v) = \overline \cdot f(v) = \alpha * \overline(v)

Thus, complex conjugation

V\mapsto\overline{V}

and

f\mapsto\overlinef

define a functor from the category of complex vector spaces to itself.

and

are finite-dimensional and the map

is described by the complex matrix

with respect to the bases

l{B}

and

l{C}

then the map

\overline{f}

is described by the complex conjugate of

with respect to the bases

\overline{l{B}}

\overline{V}

and

\overline{l{C}}

\overline{W}.

Structure of the conjugate

The vector spaces

and

\overline{V}

have the same dimension over the complex numbers and are therefore isomorphic as complex vector spaces. However, there is no natural isomorphism from

\overline{V}.

The double conjugate

\overline{\overline{V}}

is identical to

Complex conjugate of a Hilbert space

l{H}

(either finite or infinite dimensional), its complex conjugate

\overline{l{H}}

is the same vector space as its continuous dual space

l{H}^\prime.

There is one-to-one antilinear correspondence between continuous linear functionals and vectors. In other words, any continuous linear functional on

l{H}

is an inner multiplication to some fixed vector, and vice versa.

Thus, the complex conjugate to a vector

particularly in finite dimension case, may be denoted as

v^\dagger

(v-dagger, a row vector that is the conjugate transpose to a column vector

).In quantum mechanics, the conjugate to a ket vector

|\psi\rangle

is denoted as

\langle\psi|

– a bra vector (see bra–ket notation).

Notes and References

Book: K. Schmüdgen. Unbounded Operator Algebras and Representation Theory. 11 November 2013. Birkhäuser. 978-3-0348-7469-4. 16.

Complex conjugate of a vector space explained

Motivation

Complex conjugation functor

Structure of the conjugate

Complex conjugate of a Hilbert space

See also

Further reading

Notes and References