In mathematics, if is a group and is a linear representation of it on the vector space, then the dual representation is defined over the dual vector space as follows:[1] [2]
is the transpose of, that is, = for all .
The dual representation is also known as the contragredient representation.
If is a Lie algebra and is a representation of it on the vector space, then the dual representation is defined over the dual vector space as follows:[3]
= for all .
The motivation for this definition is that Lie algebra representation associated to the dual of a Lie group representation is computed by the above formula. But the definition of the dual of a Lie algebra representation makes sense even if it does not come from a Lie group representation.
In both cases, the dual representation is a representation in the usual sense.
If a (finite-dimensional) representation is irreducible, then the dual representation is also irreducible[4] —but not necessarily isomorphic to the original representation. On the other hand, the dual of the dual of any representation is isomorphic to the original representation.
Consider a unitary representation
\rho
G
\rho
G
\rho\ast(g)
\rho(g)
\rho(g)
\rho(g)
\rho(g)
The upshot of this discussion is that when working with unitary representations in an orthonormal basis,
\rho*(g)
\rho(g)
In the representation theory of SU(2), the dual of each irreducible representation does turn out to be isomorphic to the representation. But for the representations of SU(3), the dual of the irreducible representation with label
(m1,m2)
(m2,m1)
(1,0)
3
\bar3
More generally, in the representation theory of semisimple Lie algebras (or the closely related representation theory of compact Lie groups), the weights of the dual representation are the negatives of the weights of the original representation.[6] (See the figure.) Now, for a given Lie algebra, if it should happen that operator
-I
\mu\mapsto-\mu
\{I,-I\}
\operatorname{so}(2n+1;C)
Bn
\operatorname{sp}(n;C)
Cn
If, for a given Lie algebra,
-I
w0
\mu
-\mu
w0 ⋅ (-\mu)
-I
w0
-I
\mu\mapstow0 ⋅ (-\mu)
\mu
\mu=w0 ⋅ (-\mu)
In the case of SU(3) (or its complexified Lie algebra,
\operatorname{sl}(3;C)
\{\alpha1,\alpha2\}
\alpha3=\alpha1+\alpha2
w0
\alpha3
\mu\mapstow0 ⋅ (-\mu)
\alpha3
\alpha3
(m,m)
In representation theory, both vectors in and linear functionals in are considered as column vectors so that the representation can act (by matrix multiplication) from the left. Given a basis for and the dual basis for, the action of a linear functional on, can be expressed by matrix multiplication,
\langle\varphi,v\rangle\equiv\varphi(v)=\varphiTv
\langle{\rho}*(g)\varphi,\rho(g)v\rangle=\langle\varphi,v\rangle.
\langle{\rho}*(g)\varphi,\rho(g)v\rangle=\langle\rho(g-1)T\varphi,\rho(g)v\rangle=(\rho(g-1)T\varphi)T\rho(g)v=\varphiT\rho(g-1)\rho(g)v=\varphiTv=\langle\varphi,v\rangle.
For the Lie algebra representation one chooses consistency with a possible group representation. Generally, if is a representation of a Lie group, then given by
\pi(X)=
| d | |
| dt |
\Pi(etX)|t.
\pi*(X)=
| d | |
| dt |
\Pi*(etX)|t=
| d | |
| dt |
\Pi(e-tX
| T| | |
| ) | |
| t=0 |
=-\pi(X)T.
Consider the group
G=U(1)
n
| i\theta | |
| \rho | |
| n(e |
)=[ein\theta].
\rhon
| *(e | |
| \rho | |
| n |
i\theta)=[e-in\theta]=\rho-n(ei\theta).
\rhon
\rho-n
A general ring module does not admit a dual representation. Modules of Hopf algebras do, however.