140 J.W. COGDELL, £-FUNCTIONS FOR GLnseems to be no obstruction to carrying this out, and then we obtain boundedness
in vertical strips for L( s , 7r x 7r^1 ) in general.
We should point out that if one approaches these £-function by the method
of constant terms and Fourier coefficients of Eisenstein series, then Gelbart and
Shahidi have shown a wide class of automorphic £-functions, including ours, to b e
bounded in vertical strips [25].4.2. Poles of £-functions
Let us determine where the global £-functions can have poles. The poles of the
£-functions will be related to the poles of t he global integrals. Recall from Lecture
2 that in the case of m < n we have that the global integrals I(s; cp, cp') are entire
and that when m = n then I(s;cp,cp',if?) can h ave at most simple poles and they
occur at s = -iu and s = 1-iu for u real when n :::::: if'® I det lia. As we have noted
above, the global integrals and global £-functions are related, for appropriate cp,
cp', and if?, byI(s; cp, cp') = (rr ev(s; W'Pv, W~J) L(s, n x 7r
1
)
vES
orI(s;cp,cp
1
,if?) = (rr ev(s;W'Pv• W~~,if?v)) L(s,n x n').
vES
On the other hand, we have seen that for any s 0 E re and any v there is a
choice of local Wv, W~, and if?v such that the local factors ev(s 0 ; Wv, W~) -1- 0
or ev(so; Wv, W~, if?v) -1-0. So as we vary cp, cp' and if? at the places v E S we see
that division by these factors can introduce no extraneous poles in L(s, 7r x 7r^1 ) ,
that is, in keeping with the local characterization of the £-factor in terms of poles
of local integrals, globally the poles of L(s, 7r x n') are precisely the poles of the
family of global integrals {I(s; cp, cp')} or {I(s; cp, cp', if?)}. Hence from Theorems 2.1
and 2.2 we have.
Theorem 4.2. If m < n then L(s, 7r x 7r^1 ) is entire. If m = n, then L(s, n x n')h as at most simple poles and they occur iff 7r :::::: if'® I det lia with u real and are
then at s = -iu and s = 1 - iu.
If we apply this with n' = if we obtain the following useful corollary.
Corollary. L(s, 7r x if) has simple poles at s = 0 ands= l.4.3. Strong Multiplicity One
Let us return to the Strong Multiplicity One Theorem for cuspidal representations.
First, recall the statement:
Theorem (Strong Multiplicity One). Let (n, V1r) and (n', V1r1) be two cuspidal
representations of GLn(A). Suppose there is a finite set of places S such that for
all v tf. S we have nv:::::: n~. Then 7r = n'.
We will now present Jacquet and Shalika's proof of this statement via £-
functions [45]. First note the following observation, which follows from our analysis
of the location of the poles of the £-functions.