118 J.W. COGDELL, £-FUNCTIONS FOR GLn
where the unfolded global integral is
with the h integral over Nm(A)\ GLm(A) and the x integral over Mn-m-1,m(A), the
space of ( n -m - 1) x m matrices, p denoting right translation, and Wn,m the Weyl
element Wn,m = (Im ) with Wn-m = ( · ·
1
) the standard long Weyl
Wn-m l
element in GLn-m· Also, for WE W(7r,7/i) we set W(g) = W(wng") E W(?r,?ji-^1 ).
The extra unipotent integration is the remnant of ifD::::i. As before, W(s; W, W') is
absolutely convergent for Re( s) > > 0. For <p and <p^1 factorizable as before, these
integrals W ( s; W 'P, W~,) will factor as well. Hence we have
v
where
where now with the hv integral is over Nm(kv)\ GLm(kv) and the Xv integral is over
the matrix space Mn-m-l,m(kv)· Thus, coming back to our functional equation,
we find that the right hand side is Eulerian and factors as
v
2.3. Eulerian integrals for GLn x GLn
The paradigm for integral representations of £-functions for GLn x GLn is not
Hecke but rather the classical papers of Rankin [71] and Selberg [73]. These were
first interpreted in the framework of automorphic representations by Jacquet for
GL2 x GL 2 [37] and then Jacquet and Shalika in general [45].
Let (7r, V1f) and (7r^1 , V1f') be two cuspidal representations of GLn(A). Let <p E V7r
and <p^1 E V7r' be two cusp forms. The analogue of the construction above would be
simply
f i.p(g)i.p'(g)I det(g)ls dg.
JGLn(k)\ GLn(A)
This integral is essentially the £^2 -inner product of <p and <p^1 and is not suitable
for defining an £-function, although it will occur as a residue of our integral at a
pole. Instead, following Rankin and Selberg, we use an integral representation that
involves a third function: an Eisenstein series on G Ln (A). This family of Eisenstein
series is constructed using the mirabolic subgroup once again.