In mathematics, the Weyl character formula in representation theory describes the characters of irreducible representations of compact Lie groups in terms of their highest weights.[1] It was proved by . There is a closely related formula for the character of an irreducible representation of a semisimple Lie algebra.[2] In Weyl's approach to the representation theory of connected compact Lie groups, the proof of the character formula is a key step in proving that every dominant integral element actually arises as the highest weight of some irreducible representation.[3] Important consequences of the character formula are the Weyl dimension formula and the Kostant multiplicity formula.
By definition, the character
\chi
\pi
\pi(g)
g\inG
\chi
\pi
\pi
Weyl's formula is a closed formula for the character
\chi
The character formula can be expressed in terms of representations of complex semisimple Lie algebras or in terms of the (essentially equivalent) representation theory of compact Lie groups.
Let
\pi
ak{g}
ak{h}
ak{g}
\pi
\operatorname{ch}\pi:ak{h} → C
| \pi(H) | |
| \operatorname{ch} | |
| \pi(H)=\operatorname{tr}(e |
).
H=0
\pi
\operatorname{ch}\pi(H)=\sum\mum\mue\mu(H)
\mu
\pi
m\mu
\mu
The character formula states[4] that
\operatorname{ch}\pi(H)
\operatorname{ch}\pi(H)=
| \sumw\in\varepsilon(w)ew(λ+\rho)(H) | ||||||
|
where
W
\Delta+
\Delta
\rho
λ
V
\varepsilon(w)
w
ak{h}\subsetak{g}
(-1)\ell(w)
\ell(w)
w
Using the Weyl denominator formula (described below), the character formula may be rewritten as
| \operatorname{ch} | ||||
|
\operatorname{ch}\pi(H){\sumw\in\varepsilon(w)ew(\rho)(H)
e(λ+\rho)(H)
\operatorname{ch}\pi
e(λ+\rho)(H)
Let
K
T
K
\Pi
K
\Pi
\Chi(x)=\operatorname{trace}(\Pi(x)), x\inK.
K
K
Since
\Chi
T
H
akt
T
\operatorname{trace}(\Pi(eH))=\operatorname{trace}(e\pi(H))
\pi
akk
K
H\mapsto\operatorname{trace}(\Pi(eH))
\pi
akk
\Pi
T
| ||||
| \Chi(e |
.
i
i
In the case of the group SU(2), consider the irreducible representation of dimension
m+1
T
\Chi\left(\begin{pmatrix} ei\theta&0\\ 0&e-i\theta\end{pmatrix}\right)=
| ei(m+1)\theta-e-i(m+1)\theta | = | |
| ei\theta-e-i\theta |
| \sin((m+1)\theta) | |
| \sin\theta |
.
Since the representations are known very explicitly, the character of the representation can be written down as
\Chi\left(\begin{pmatrix} ei\theta&0\\ 0&e-i\theta\end{pmatrix}\right)=eim\theta+ei(m-2)\theta+ … +e-im\theta.
ei\theta-e-i\theta
\Chi\left(\begin{pmatrix} ei\theta&0\\ 0&e-i\theta\end{pmatrix}\right)(ei\theta-e-i\theta)=\left(ei(m+1)\theta+ei(m-1)\theta+ … +e-i(m-1)\theta\right)-\left(ei(m-1)\theta+ … +e-i(m-1)\theta+e-i(m+1)\theta\right).
We can now easily verify that most of the terms cancel between the two term on the right-hand side above, leaving us with only
\Chi\left(\begin{pmatrix} ei\theta&0\\ 0&e-i\theta\end{pmatrix}\right)(ei\theta-e-i\theta)=ei(m+1)\theta-e-i(m+1)\theta
\Chi\left(\begin{pmatrix} ei\theta&0\\ 0&e-i\theta\end{pmatrix}\right)=
| ei(m+1)\theta-e-i(m+1)\theta | = | |
| ei\theta-e-i\theta |
| \sin((m+1)\theta) | |
| \sin\theta |
.
R=e2i\theta
In the special case of the trivial 1-dimensional representation the character is 1, so the Weyl character formula becomes the Weyl denominator formula:[9]
{\sumw\in\varepsilon(w)ew(\rho)(H)=
| \prod | |
| \alpha\in\Delta+ |
(e\alpha(H)/2-e-\alpha(H)/2)}.
For special unitary groups, this is equivalent to the expression
| \sum | |
| \sigma\inSn |
sgn(\sigma)
| \sigma(1)-1 | |
| X | |
| 1 |
…
| \sigma(n)-1 | |
| X | |
| n |
=\prod1\le(Xj-Xi)
By evaluating the character at
H=0
\dim(Vλ)=
| {\prod | |
| \alpha\in\Delta+ |
(λ+\rho,\alpha)\over
| \prod | |
| \alpha\in\Delta+ |
(\rho,\alpha)}
Vλ
λ
m+1
\theta
\sin((m+1)\theta)/\sin\theta
We may consider as an example the complex semisimple Lie algebra sl(3,C), or equivalently the compact group SU(3). In that case, the representations are labeled by a pair
(m1,m2)
| \dim(V | )= | |
| m1,m2 |
| 1 | |
| 2 |
(m1+1)(m2+1)(m1+m2+2)
m1=1,m2=0
See main article: Kostant partition function. The Weyl character formula gives the character of each representation as a quotient, where the numerator and denominator are each a finite linear combination of exponentials. While this formula in principle determines the character, it is not especially obvious how one can compute this quotient explicitly as a finite sum of exponentials. Already In the SU(2) case described above, it is not immediately obvious how to go from the Weyl character formula, which gives the character as
\sin((m+1)\theta)/\sin\theta
eim\theta+ei(m-2)\theta+ … +e-im\theta.
\sin((m+1)\theta)/\sin\theta
In general, the division process can be accomplished by computing a formal reciprocal of the Weyl denominator and then multiplying the numerator in the Weyl character formula by this formal reciprocal.[13] The result gives the character as a finite sum of exponentials. The coefficients of this expansion are the dimensions of the weight spaces, that is, the multiplicities of the weights. We thus obtain from the Weyl character formula a formula for the multiplicities of the weights, known as the Kostant multiplicity formula. An alternative formula, that is more computationally tractable in some cases, is given in the next section.
Hans Freudenthal's formula is a recursive formula for the weight multiplicities that gives the same answer as the Kostant multiplicity formula, but is sometimeseasier to use for calculations as there can be far fewer terms to sum. The formula is based on use of the Casimir element and its derivation is independent of the character formula. It states[14]
(\|Λ+\rho\|2-
| 2)m | |
| \|λ+\rho\| | |
| Λ(λ) = |
2
| \sum | |
| \alpha\in\Delta+ |
\sumj\ge(λ+j\alpha,\alpha)mΛ(λ+j\alpha)
where
The Weyl character formula also holds for integrable highest-weight representations of Kac–Moody algebras, when it is known as the Weyl–Kac character formula. Similarly there is a denominator identity for Kac–Moody algebras, which in the case of the affine Lie algebras is equivalent to the Macdonald identities. In the simplest case of the affine Lie algebra of type A1 this is the Jacobi triple product identity
| infty \left( | |
| \prod | |
| m=1 |
1-x2m\right) \left(1-x2m-1y\right) \left(1-x2m-1y-1\right) =
| infty | |
| \sum | |
| n=-infty |
(-1)n
| n2 | |
| x |
yn.
The character formula can also be extended to integrable highest weight representations of generalized Kac–Moody algebras, when the character is given by
{\sumw\in(-1)\ell(w)w(eλ+\rhoS)\overe\rho
| \prod | |
| \alpha\in\Delta+ |
(1-e-\alpha)}.
Here S is a correction term given in terms of the imaginary simple roots by
S=\sumI(-1)|I|e\Sigma
where the sum runs over all finite subsets I of the imaginary simple roots which are pairwise orthogonal and orthogonal to the highest weight λ, and |I| is the cardinality of I and ΣI is the sum of the elements of I.
The denominator formula for the monster Lie algebra is the product formula
j(p)-j(q)=\left({1\overp}-{1\overq}\right)
| infty | |
| \prod | |
| n,m=1 |
(1-pnqm)
| cnm | |
for the elliptic modular function j.
Peterson gave a recursion formula for the multiplicities mult(β) of the roots β of a symmetrizable (generalized) Kac–Moody algebra, which is equivalent to the Weyl–Kac denominator formula, but easier to use for calculations:
(\beta,\beta-2\rho)c\beta=\sum\gamma+\delta=\beta(\gamma,\delta)c\gammac\delta
where the sum is over positive roots γ, δ, and
c\beta=\sumn\ge{\operatorname{mult}(\beta/n)\overn}.
Harish-Chandra showed that Weyl's character formula admits a generalization to representations of a real, reductive group. Suppose
\pi
λ
\Theta\pi
\pi
\Theta\pi|H'=
| {\sum | |
| w\inW/Wλ |
awewλ\overe\rho
| \prod | |
| \alpha\in\Delta+ |
(1-e-\alpha)}.
Here
HC
GC
Wλ
λ
The coefficients
aw