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On a character formula involving Borel subgroups
On a Character Formula Involving Bore1 Subgroups Mihalis Maliakas 13epartment
of Mathematics
Iiniversity of Athens Panepistimiopolis Athens 15784,
Greece
Let k be a field of characteristic zero, and B the subgroup of GL,(k) of upper triangular matrices. Consider the natural GL,,(k)-module V = k”, and let {el, e2,. . . , e,} be the standard basis of V. We have the flag 0 c v, & v, c ... G v,, where V3 is the subsequence of V spanned by { “1>“2,...> -
ei}. An easy computation
is a B-module.
The (formal)
h,(xl,
x2,...,
shows that each symmetric
character
xj) =
power S,\‘,
of SiVI is
c cl, t ...
xp’x;’
. . . q,,
+a,=i
the ith complete symmetric function on the variables x,, x1, . . . , xj [41. For A = (A,, . . . , A,) E N”, the character of the B-module S,,V, 8 SJ,
@ -1. 8 SAnV,, is the
which
will be denoted
by
product h,{x,)h,Jx,, x2)... h,Jx,, h,. Let k, be the one-dimensional
whose character is ch k, = x:lr,hz ... x,^ll. In this note we give a very elementary equivalent to the main result of Kovacec combinatorics of semistandard tableaux. THEOREM .
direct
proof
and Santana
x2.. . x,,), B-module
of a theorem
[2]; their proof uses
With the above notation we have
ch kA=
c c,TE
(1)
sgn(o) hm(h)~
I-,
where IT,, is the symmetric group on n symbols, sgn(a) denotes the sign of the permutation CT, and a(h) = (A, + a(l) - 1, A, + a(2) - 2 ,..., A, + a(n) - n). (The convention is that h,(,, = 0 is a(A) P N”.) LINEAR
ALGEBRA
AND ITS APPLICATlONS
fi5.5 Avenue of the Americas,
247273-275
(1996) 0024.3795/96/$15.00
CBElsevier Science Inc., 1996 New York, NY 100 10
SSDI 0024-3795(95)00116-9
274
MIHALIS MALIAKAS
Recently, methods, the teristic yields We begin
Doty [I], Woodcock [5], and the author [3] proved, using various existence of B-resolutions of k, whose Euler-Poincare characthe above character identity. by making two observations:
(a) The right-hand side of (1) is the determinant of the following n X n matrix whose i, j entry is hAi_i+j(xl,. . . , xi): ...
... ...
h Al+n-l(X1) h ,h,+n-2 (bX2)
h&l,:..,
q,>
/
(2) (b) We have the identity
hi(xl,
x2>**.>
xj) - xlhi_l(
xl,
x2,.
. .,
xj) = hi(
for each i E N and j E {1,2,. . . , n], where as usual h,(x,, h_l(x,,..., xj) = 0.
x2,
. . . .
xj)
(3)
. . . , xj) = 1 and
We proceed now by induction on n to show that the determinant of (2) is r+2”2 . . . r,h,* The case n = 1 is trivial. Assuming n > 1, multiply column n - 1 of (2) by x1 and subtract from column n, multiply column n - 2 by x1 and subtract from column n - 1, etc. Using (3), the resulting matrix is I
h*l(xd h**-lb,,
x2)
h A,-n+l (&,...J,,,
...
0 h&2)
h*,-"+P(XP.....
...
4
*.*
0 hA\2+n-2(~2)
h&x,,:..,
xJ (4)
By induction, the determinant of the matrix obtained after deleting the first row and column of (4) is ~2x2 a** x$. Thus the determinant of (4) is +lx> . . . x$, and the proof is complete.
A CHARACTER
275
FORMULA
If A E N” and (Y E Z” with CY= ((Ye,. . . , cc,>, let cA,LI be the number of row semistandard
tableaux of shape A and weight
(Y. Verify that cA,(I equals
the coefficient of the monomial xpl *** x,*n in h,. Thus by considering in (1) rnonomials of weight cx = ((Ye, . . . , a,), one recovers immediately the main result of [2], namely the identity
6A, a where
6, a is the Kronecker
=
~Sgn(~>Co(,qa,
delta.
REFERENCES I
S. R. Doty,
Resolutions
2
A. Kovacec
and A. P. Santana,
of Schur algebra 3
M. Maliakas,
4
I. G. MacDonald,
S(B+),
Resolutions
of B-modules,
In&g.
A combinatorial
Linear
Algebra
and parabolic
Appl.
Math. 5(3):267-283 theorem 197:79-91
Schur algebras,
(1994).
on the Cartan
invariants
(1994). /.
ofAlgebra (to
Symmetric
Functions
and Hull Polynomials,
Bore1 Schur
algebras,
Comm.
Clarendon,
appear). Oxford,
1979. 5
D. J. Woodcock,
Algebra
22:1703-1721
Received 15 September 1994; final manuscript accepted 2 February 1995
(1994).
of Mathematics
Iiniversity of Athens Panepistimiopolis Athens 15784,
Greece
Let k be a field of characteristic zero, and B the subgroup of GL,(k) of upper triangular matrices. Consider the natural GL,,(k)-module V = k”, and let {el, e2,. . . , e,} be the standard basis of V. We have the flag 0 c v, & v, c ... G v,, where V3 is the subsequence of V spanned by { “1>“2,...> -
ei}. An easy computation
is a B-module.
The (formal)
h,(xl,
x2,...,
shows that each symmetric
character
xj) =
power S,\‘,
of SiVI is
c cl, t ...
xp’x;’
. . . q,,
+a,=i
the ith complete symmetric function on the variables x,, x1, . . . , xj [41. For A = (A,, . . . , A,) E N”, the character of the B-module S,,V, 8 SJ,
@ -1. 8 SAnV,, is the
which
will be denoted
by
product h,{x,)h,Jx,, x2)... h,Jx,, h,. Let k, be the one-dimensional
whose character is ch k, = x:lr,hz ... x,^ll. In this note we give a very elementary equivalent to the main result of Kovacec combinatorics of semistandard tableaux. THEOREM .
direct
proof
and Santana
x2.. . x,,), B-module
of a theorem
[2]; their proof uses
With the above notation we have
ch kA=
c c,TE
(1)
sgn(o) hm(h)~
I-,
where IT,, is the symmetric group on n symbols, sgn(a) denotes the sign of the permutation CT, and a(h) = (A, + a(l) - 1, A, + a(2) - 2 ,..., A, + a(n) - n). (The convention is that h,(,, = 0 is a(A) P N”.) LINEAR
ALGEBRA
AND ITS APPLICATlONS
fi5.5 Avenue of the Americas,
247273-275
(1996) 0024.3795/96/$15.00
CBElsevier Science Inc., 1996 New York, NY 100 10
SSDI 0024-3795(95)00116-9
274
MIHALIS MALIAKAS
Recently, methods, the teristic yields We begin
Doty [I], Woodcock [5], and the author [3] proved, using various existence of B-resolutions of k, whose Euler-Poincare characthe above character identity. by making two observations:
(a) The right-hand side of (1) is the determinant of the following n X n matrix whose i, j entry is hAi_i+j(xl,. . . , xi): ...
... ...
h Al+n-l(X1) h ,h,+n-2 (bX2)
h&l,:..,
q,>
/
(2) (b) We have the identity
hi(xl,
x2>**.>
xj) - xlhi_l(
xl,
x2,.
. .,
xj) = hi(
for each i E N and j E {1,2,. . . , n], where as usual h,(x,, h_l(x,,..., xj) = 0.
x2,
. . . .
xj)
(3)
. . . , xj) = 1 and
We proceed now by induction on n to show that the determinant of (2) is r+2”2 . . . r,h,* The case n = 1 is trivial. Assuming n > 1, multiply column n - 1 of (2) by x1 and subtract from column n, multiply column n - 2 by x1 and subtract from column n - 1, etc. Using (3), the resulting matrix is I
h*l(xd h**-lb,,
x2)
h A,-n+l (&,...J,,,
...
0 h&2)
h*,-"+P(XP.....
...
4
*.*
0 hA\2+n-2(~2)
h&x,,:..,
xJ (4)
By induction, the determinant of the matrix obtained after deleting the first row and column of (4) is ~2x2 a** x$. Thus the determinant of (4) is +lx> . . . x$, and the proof is complete.
A CHARACTER
275
FORMULA
If A E N” and (Y E Z” with CY= ((Ye,. . . , cc,>, let cA,LI be the number of row semistandard
tableaux of shape A and weight
(Y. Verify that cA,(I equals
the coefficient of the monomial xpl *** x,*n in h,. Thus by considering in (1) rnonomials of weight cx = ((Ye, . . . , a,), one recovers immediately the main result of [2], namely the identity
6A, a where
6, a is the Kronecker
=
~Sgn(~>Co(,qa,
delta.
REFERENCES I
S. R. Doty,
Resolutions
2
A. Kovacec
and A. P. Santana,
of Schur algebra 3
M. Maliakas,
4
I. G. MacDonald,
S(B+),
Resolutions
of B-modules,
In&g.
A combinatorial
Linear
Algebra
and parabolic
Appl.
Math. 5(3):267-283 theorem 197:79-91
Schur algebras,
(1994).
on the Cartan
invariants
(1994). /.
ofAlgebra (to
Symmetric
Functions
and Hull Polynomials,
Bore1 Schur
algebras,
Comm.
Clarendon,
appear). Oxford,
1979. 5
D. J. Woodcock,
Algebra
22:1703-1721
Received 15 September 1994; final manuscript accepted 2 February 1995
(1994).