A complex structure on a real vector space V is a real linear transformation

Going in the other direction, if one starts with a complex vector space W then one can define a complex structure on the underlying real space by defining Jw = iw for all w ∈ W.

More formally, a linear complex structure on a real vector space is an algebra representation of the complex numbers C, thought of as an associative algebra over the real numbers. This algebra is realized concretely as

If V_J has complex dimension n then V must have real dimension 2n. That is, a finite-dimensional space V admits a complex structure only if it is even-dimensional. It is not hard to see that every even-dimensional vector space admits a complex structure. One can define J on pairs e,f of basis vectors by Je = f and Jf = −e and then extend by linearity to all of V. If (v₁, …, v_n) is a basis for the complex vector space V_J then (v₁, Jv₁, …, v_n, Jv_n) is a basis for the underlying real space V.

A real linear transformation A : V → V is a complex linear transformation of the corresponding complex space V_J if and only if A commutes with J, i.e. if and only if

Elementary example edit

The collection of 2x2 real matrices M(2,R) over the real field is 4-dimensional. Any matrix

${\displaystyle J={\begin{pmatrix}a&c\\b&-a\end{pmatrix}}}$  with a² + bc = –1

has square equal to the negative of the identity matrix. A complex structure may be formed in M(2,R): with identity matrix I, elements x I + y J, with matrix multiplication form complex numbers.

Cⁿ edit

The fundamental example of a linear complex structure is the structure on R²ⁿ coming from the complex structure on Cⁿ. That is, the complex n-dimensional space Cⁿ is also a real 2n-dimensional space – using the same vector addition and real scalar multiplication – while multiplication by the complex number i is not only a complex linear transform of the space, thought of as a complex vector space, but also a real linear transform of the space, thought of as a real vector space. Concretely, this is because scalar multiplication by i commutes with scalar multiplication by real numbers ${\displaystyle i(\lambda v)=(i\lambda )v=(\lambda i)v=\lambda (iv)}$  – and distributes across vector addition. As a complex n×n matrix, this is simply the scalar matrix with i on the diagonal. The corresponding real 2n×2n matrix is denoted J.

Given a basis ${\displaystyle \left\{e_{1},e_{2},\dots ,e_{n}\right\}}$  for the complex space, this set, together with these vectors multiplied by i, namely ${\displaystyle \left\{ie_{1},ie_{2},\dots ,ie_{n}\right\},}$  form a basis for the real space. There are two natural ways to order this basis, corresponding abstractly to whether one writes the tensor product as ${\displaystyle \mathbb {C} ^{n}=\mathbb {R} ^{n}\otimes _{\mathbb {R} }\mathbb {C} }$  or instead as ${\displaystyle \mathbb {C} ^{n}=\mathbb {C} \otimes _{\mathbb {R} }\mathbb {R} ^{n}.}$ 

If one orders the basis as ${\displaystyle \left\{e_{1},ie_{1},e_{2},ie_{2},\dots ,e_{n},ie_{n}\right\},}$  then the matrix for J takes the block diagonal form (subscripts added to indicate dimension):

On the other hand, if one orders the basis as ${\displaystyle \left\{e_{1},e_{2},\dots ,e_{n},ie_{1},ie_{2},\dots ,ie_{n}\right\}}$ , then the matrix for J is block-antidiagonal:

The data of the real vector space and the J matrix is exactly the same as the data of the complex vector space, as the J matrix allows one to define complex multiplication. At the level of Lie algebras and Lie groups, this corresponds to the inclusion of gl(n,C) in gl(2n,R) (Lie algebras – matrices, not necessarily invertible) and GL(n,C) in GL(2n,R):

The inclusion corresponds to forgetting the complex structure (and keeping only the real), while the subgroup GL(n,C) can be characterized (given in equations) as the matrices that commute with J:

Note that the defining equations for these statements are the same, as ${\displaystyle AJ=JA}$  is the same as ${\displaystyle AJ-JA=0,}$  which is the same as ${\displaystyle [A,J]=0,}$  though the meaning of the Lie bracket vanishing is less immediate geometrically than the meaning of commuting.

Direct sum edit

If V is any real vector space there is a canonical complex structure on the direct sum V ⊕ V given by

If B is a bilinear form on V then we say that J preserves B if

If g is an inner product on V then J preserves g if and only if J is an orthogonal transformation. Likewise, J preserves a nondegenerate, skew-symmetric form ω if and only if J is a symplectic transformation (that is, if ${\textstyle \omega (Ju,Jv)=\omega (u,v)}$ ). For symplectic forms ω an interesting compatibility condition between J and ω is that

Given a symplectic form ω and a linear complex structure J on V, one may define an associated bilinear form g_J on V by

If the symplectic form ω is preserved (but not necessarily tamed) by J, then g_J is the real part of the Hermitian form (by convention antilinear in the first argument) ${\textstyle h_{J}\colon V_{J}\times V_{J}\to \mathbb {C} }$  defined by

Given any real vector space V we may define its complexification by extension of scalars:

${\displaystyle V^{\mathbb {C} }=V\otimes _{\mathbb {R} }\mathbb {C} .}$ 

This is a complex vector space whose complex dimension is equal to the real dimension of V. It has a canonical complex conjugation defined by

${\displaystyle {\overline {v\otimes z}}=v\otimes {\bar {z}}}$ 

If J is a complex structure on V, we may extend J by linearity to V^C:

${\displaystyle J(v\otimes z)=J(v)\otimes z.}$ 

Since C is algebraically closed, J is guaranteed to have eigenvalues which satisfy λ² = −1, namely λ = ±i. Thus we may write

${\displaystyle V^{\mathbb {C} }=V^{+}\oplus V^{-}}$ 

where V⁺ and V⁻ are the eigenspaces of +i and −i, respectively. Complex conjugation interchanges V⁺ and V⁻. The projection maps onto the V^± eigenspaces are given by

${\displaystyle {\mathcal {P}}^{\pm }={1 \over 2}(1\mp iJ).}$ 

So that

${\displaystyle V^{\pm }=\{v\otimes 1\mp Jv\otimes i:v\in V\}.}$ 

There is a natural complex linear isomorphism between V_J and V⁺, so these vector spaces can be considered the same, while V⁻ may be regarded as the complex conjugate of V_J.

Note that if V_J has complex dimension n then both V⁺ and V⁻ have complex dimension n while V^C has complex dimension 2n.

Abstractly, if one starts with a complex vector space W and takes the complexification of the underlying real space, one obtains a space isomorphic to the direct sum of W and its conjugate:

${\displaystyle W^{\mathbb {C} }\cong W\oplus {\overline {W}}.}$ 

Let V be a real vector space with a complex structure J. The dual space V* has a natural complex structure J* given by the dual (or transpose) of J. The complexification of the dual space (V*)^C therefore has a natural decomposition

${\displaystyle (V^{*})^{\mathbb {C} }=(V^{*})^{+}\oplus (V^{*})^{-}}$ 

into the ±i eigenspaces of J*. Under the natural identification of (V*)^C with (V^C)* one can characterize (V*)⁺ as those complex linear functionals which vanish on V⁻. Likewise (V*)⁻ consists of those complex linear functionals which vanish on V⁺.

The (complex) tensor, symmetric, and exterior algebras over V^C also admit decompositions. The exterior algebra is perhaps the most important application of this decomposition. In general, if a vector space U admits a decomposition U = S ⊕ T then the exterior powers of U can be decomposed as follows:

${\displaystyle \Lambda ^{r}U=\bigoplus _{p+q=r}(\Lambda ^{p}S)\otimes (\Lambda ^{q}T).}$ 

A complex structure J on V therefore induces a decomposition

${\displaystyle \Lambda ^{r}\,V^{\mathbb {C} }=\bigoplus _{p+q=r}\Lambda ^{p,q}\,V_{J}}$ 

where

${\displaystyle \Lambda ^{p,q}\,V_{J}\;{\stackrel {\mathrm {def} }{=}}\,(\Lambda ^{p}\,V^{+})\otimes (\Lambda ^{q}\,V^{-}).}$ 

All exterior powers are taken over the complex numbers. So if V_J has complex dimension n (real dimension 2n) then

${\displaystyle \dim _{\mathbb {C} }\Lambda ^{r}\,V^{\mathbb {C} }={2n \choose r}\qquad \dim _{\mathbb {C} }\Lambda ^{p,q}\,V_{J}={n \choose p}{n \choose q}.}$ 

The dimensions add up correctly as a consequence of Vandermonde's identity.

The space of (p,q)-forms Λ^p,q V_J* is the space of (complex) multilinear forms on V^C which vanish on homogeneous elements unless p are from V⁺ and q are from V⁻. It is also possible to regard Λ^p,q V_J* as the space of real multilinear maps from V_J to C which are complex linear in p terms and conjugate-linear in q terms.

See complex differential form and almost complex manifold for applications of these ideas.

• Almost complex manifold
• Complex manifold
• Complex differential form
• Complex conjugate vector space
• Hermitian structure
• Real structure

• Kobayashi S. and Nomizu K., Foundations of Differential Geometry, John Wiley & Sons, 1969. ISBN 0-470-49648-7. (complex structures are discussed in Volume II, Chapter IX, section 1).
• Budinich, P. and Trautman, A. The Spinorial Chessboard, Springer-Verlag, 1988. ISBN 0-387-19078-3. (complex structures are discussed in section 3.1).
• Goldberg S.I., Curvature and Homology, Dover Publications, 1982. ISBN 0-486-64314-X. (complex structures and almost complex manifolds are discussed in section 5.2).