In mathematics, if φ: G→H is a homomorphism of Lie groups, and g and h are the Lie algebras of G and H respectively, then the induced map φ* on tangent spaces is a homomorphism of Lie algebras, i.e. satisfies
![\phi_*[x\,y] = [\phi_*x\,\phi_*y]](a/../upload/math/5cc858ca3f30b73fb454ee2bf0552b15.png)
for all x and y in g. In particular, a representation of Lie groups φ: G→GL(V) determines a homomorphism of Lie algebras from g to the Lie algebra of the general linear group GL(V) over the vector space V. (GL(V) is just the endomorphism ring End(V) = Hom(V,V)). Such a homomorphism is called a representation of the Lie algebra g.
More generally (since we can study Lie algebras independently from their incarnation as the tangent space of a Lie group), such a representation may be described as a bilinear map (x,v)→x.v
from g×V to V satisfying the Jacobi identity analogue
![[x_1\,x_2].v = x_1.(x_2.v) - x_2.(x_1.v)](a/../upload/math/a7054a4cbc809accb0e9295df83a4879.png)
Equivalently, it is a representation of the universal enveloping algebra.
If the Lie algebra is semisimple, then all reducible reps are decomposable . Otherwise, that's not true in general.
If we have two reps, with V1 and V2 as their underlying vector spaces and .[.]1 and .[.]2 as the reps, then the product of both reps would have 
as the underlying vector space and
![x[v_1\otimes v_2]=x[v_1]\otimes v_2+v_1\otimes x[v_2]](a/../upload/math/cec3a0694ae51d70d3a44a8ce7be417a.png)
If L is a real Lie algebra and 
is a complex rep of it, we can construct another rep of L called its dual rep as follows.
Let V* be the dual vector space of V. In other words, V is the set of all linear maps from V to C with addition defined over it in the usual linear way BUT scalar multiplication defined over it such that ![(z\omega)[X]=\bar{z}\omega[X]](a/../upload/math/be5cff240f50e255525b55a04e17b150.png)
for any z in C, ω in V* and X in V. This is usually rewritten as a contraction with a sesquilinear form <.,>. i.e. <ω,X> is defined to be ω[X].
We define 
as follows:
<A[ω],X>+<ω,A[X]>=0
for any A in L, ω in V* and X in V. This defines uniquely.
See also