1. Introduction
Let
be a non-uniform lattice in
. By an automorphic representation of
, we mean a finitely generated admissible representation of
, consisting of
-invariant functions on
([
1]). Among all automorphic representations,
automorphic representations, i.e., subrepresentations of
, are of fundamental importance. Since
automorphic representations are unitary and completely reducible, we assume
automorphic representations to be irreducible. By Langlands theory,
automorphic representations come from either the residues of Eisenstein series or the cuspidal automorphic representations ([
2]). Throughout this paper, we shall mostly focus on irreducible cuspidal representations, even though our results also apply to unitary Eisenstein series with vanishing constant term near a cusp.
Let
and
be an irreducible admissible representation of
G. We say an automorphic representation is of type
if the automorphic representation is infinitesimally equivalent to
. In particular, we write
for the sum of all
-automorphic representations of type
. It is well-known that
is of finite multiplicity ([
1]). The main purpose of this paper is to study various
-norms of the automorphic forms at the representation level. In the literature, automorphic forms, the
K-finite vectors in an automorphic representation, are the main focus of interests. Our main focus here is the
-norms of automorphic forms, in comparison with (intrinsic) norms in the representation. We hope to gain some understanding of various
-norms of automorphic representation as a whole, without references to automorphic forms. We believe this may lead to a better understanding of the Fourier coefficients and
L-functions.
Our estimates of -norms essentially involve two decompositions, the Iwasawa decomposition , and its variant . The decomposition is utilized mainly to define Fourier coefficients and constant terms of automorphic forms. We give estimates of various norms of the restriction of automorphic representation to and the Siegel set. The decomposition, on the other hand, seems to be a potentially useful tool to study the L-function associated with the automorphic representation. In this paper, we give various estimates on the -norm of automorphic representation restricted to , with a compact domain in .
Our view point and setup are very similar to those of Harish-Chandra ([
1]). The group action will be from the left and the standard cusp will be at zero instead of
∞. Working in the general framework of harmonic analysis on semisimple Lie groups, Harish-Chandra gave a very detailed account of the theory of cusp forms and Eisenstein series, mainly due to Selberg, Gelfand and Piatetsky-Shapiro, and Langlands ([
1]). Our goal here is quite limited: we only treat the group
and we study various
-norms of automorphic representations of type
. Most of our results are stated in terms of automorphic distribution ([
3,
4,
5]). The reason is simple. There are two types of norms involved, one for the automorphic forms, and one for the representation. Using automorphic distributions, automorphic forms can be viewed as matrix coefficients of
K-finite vectors and a fixed automorphic distribution. This allows us to compare norms of automorphic forms and norms of the representation. These results will shed lights on the growth of the Rankin-Selberg
L-functions ([
6,
7]).
To state our results in a simpler form, let
. Fix the usual Iwasawa decomposition
with
N the unipotent upper triangular matrices. Let
be the fundamental domain of
contained in a Siegel set. Recall that the
-norm on the fundamental domain is
We have
Theorem 1. Let be a unitary representation in the principal series (see Section 3.1 for the definition). Let be a cuspidal representation in . Then for any , there exists a such thatFor any , there exists a such thatHere and the norm is defined on , smooth vectors in the representation in (see Equation (10) for the definition of ). Our theorem essentially says that every
is also in
for every
. In other words, the natural injection
is bounded for every
even though the natural map
is not bounded unless
. In terms of the parameter
, there is a natural barrier at
, namely, as
, the norms of these bounded operators go to infinity.
We shall remark that our estimates are true for all nonuniform lattices of any finite covering of
(see Theorem 15). In addition, the first bound with
also holds for discrete series
(see Corollary 2). They are proved by studying the
-norms of Fourier coefficients of the automorphic distribution, defined in Schmid ([
5]) and Bernstein-Resnikov ([
3]). For the general linear group
, similar results should hold. The following problem is worthy of further investigation.
Problem 1. Let G be a semisimple Lie group, Γ an arithmetic lattice and S a Siegel domain. Find the best exponents α such thatis bounded. Here is the Iwasawa decomposition. Notice that if , the sum of positive roots of , the measure on the right hand side is the invariant measure of G restricted to S. In this case, i is automatically bounded. This shows that if is “bigger” than , i is also bounded. The problem is to find the “smallest” such that i is bounded. We shall remark that cusp forms will remain to be in for any since they are fast decaying on the Siegel set. Hence our problem is about cuspidal representations, rather than cusp forms.
The second main result is an -estimates of f on where is a compact domain in .
Theorem 2. Let Γ be a nonuniform lattice in . Suppose that the Weyl element and . Let be a cuspidal automorphic representation of G of type . Let Ω be a compact domain in . Let . Then there exists a positive constant C depending on and Ω such thatSee Equation (10) for the definition of . We shall remark that in the decomposition, the invariant measure is given by . Hence, the -norm here is a perturbation of the canonical -norm. In addition, has infinite measure. The perturbation is needed because our theorem fails at . At , the norm is the original Hilbert norm of the cuspidal representation. There is no chance that can remain bounded for all .
Throughout our paper, the Haar measure on A will be . We use c or C as symbolic constants and to indicate the dependence on and u.
3. Matrix Coefficients and Analysis on
Now we shall focus on
automorphic representations of type
where
is a principal series representation. According to Langlands,
automorphic representations come from either the residue of Eisenstein series or cuspidal automorphic forms. In either cases, the restrictions of
automorphic representations fail to be
on
, when
is equipped with the left invariant measure. However if we perturb the invariant measure correctly, automorphic forms will be square integrable. In this section, we will discuss the
-integrability of
with
with respect to the measure
. We will consequently discuss the
-norm on a Siegel subset. We conduct our discussion in terms of matrix coefficients with respect to periodical distributions with no constant term. More precisely, the function
will be regarded as the matrix coefficient of
and a periodical distribution in
. Our view is similar to Schmid and Bernstein-Reznikov ([
3,
5]).
3.1. Principal Series Representations of
Principal series representations of
G can be easily constructed using homogeneous distributions on
, namely, those
See for example [
8,
9]. In this section, we shall focus on the smooth vectors and the space of distributions associated with them. Let
be the unitarized principal series representation with the trivial or nontrivial central character.
includes unitary principal series
(with
) and complementary series
(with
). All of these representations are irreducible except
. In addition
.
Consider the noncompact picture ([
9]). The noncompact picture is essentially the restriction of
f onto the line
. We have for any
,
,
Here
is the sign character on
and
is the trivial character. In particular, we have
There is a
G-invariant pairing between
and
. This allows us to write the dual space of
as
.
Unless otherwise stated, will refer to the noncompact picture. The space will then be a subspace of infinitely differentiable functions on satisfying certain conditions at infinity.
3.2. Matrix Coefficients with Respect to Periodical Distribution with Zero Constant Term
According to [
3,
5,
10], every
automorphic form of type
can be written as matrix coefficients of an automorphic distribution and a vector in the unitary representation
. Equivalently, in our setting, there exists a distribution
such that the automorphic forms of type
can be written as linear combinations of
with
. For
, the weight
m can only be an even integer. For
, the weight
m must be an odd integer. If
is cuspidal,
has a Fourier expansion
Here
is a positive integer and
denote the weak summation ([
6,
11]). We call such
a periodical distribution without constant term. Our discussion is similar to [
6].
Let
be a periodic distribution without constant term. We compute the matrix coefficient formally:
Here
is the Fourier transform, and
v is in a suitable subspace of
. The formula above, also known as the Fourier-Whittaker expansion in a more general context, is valid for
with
.
Lemma 1. Let with andFor , we have Proof. Suppose
. The functions in
are smooth functions of the form
with
an odd or even smooth function on the unit circle. They are slowly decreasing functions. Their Fourier transforms exist. Since the derivatives
are of this form and they are integrable, we see that
will decay faster than any polynomial at
∞. The weak sum in Equation (
4) becomes a convergent sum. Our lemma is proved. □
We shall make a few remarks here. Since
and
, the matrix coefficient
is automatically smooth. Our lemma simply provided a Fourier expansion, which is generally known as the Fourier-Whittaker expansion over the whole group
G. The restriction that
is somewhat unsatisfactory. When
,
may fail to be a function even for
v smooth. This happens when
is reducible and discrete series will appear as composition factors. Hence, automorphic representations that are discrete series, can be treated by considering the reducible
. We shall refer readers to Schmid’s paper [
5] for details. When
is irreducible,
is a fast decaying continuous function off from zero. Our lemma is still valid in this case. However, if
,
will fail to be a locally integrable function near zero and need to be regularized to be a Schwartz distribution.
From now on, without further mentioning, we will restrict our scope to
. We do not lose any generalities here. If
is unitary, then
. If
is a discrete series representation, then
can be embedded into a principal series representation
with
. Hence our assumption is adequate for the discussion of
automorphic representations. When
and
,
shall be interpreted as
3.3. -Norms on
Let us first study the
norms of
on
.
and
v are given in Lemma 1. Now we compute
We summarize this in the following proposition.
Proposition 3. Let with . Let and :Let . Then is a smooth function on andIn particular, Proof. Since is a smooth function on G, is a smooth function on . Both equations hold without any assumptions on convergence. Hence both sides of the equations converge or diverge at the same time. □
3.4. Estimates of Fourier Coefficients
We can now provide some estimates of certain sum of Fourier coefficients. These estimates are more or less known for automorphic forms ([
3,
4,
5,
12]). Our setting is more general.
Theorem 6. Under the same assumption as Proposition 3, suppose that there exists a such that is bounded on . Suppose that is nonvanishing on or . Then we have the following estimates about the Fourier coefficients .
- 1.
If for some , i. e., decays faster than near the cusp 0, then we have for each , - 2.
For each , there exists a such that
Let me make a remark about the ± or ∓ signs. If is nonvanishing on , then should be read as ; if is nonvanishing on , then should be read as . The proof should be read in the same way.
Proof. Fix bounded on by . Suppose that is nonvanishing on or .
Suppose that
for
. For
, the left hand side of Equation (
7) converges. Since
is nonvanishing on
,
. Then the sum
becomes a factor and must remain bounded by a constant depending on
f and
.
Let
,
and
. By Proposition 3 we have
Now fix a
such that
is positive. It follows that there exists
such that for any
,
Notice that depends on v, therefore also on f. We can write as .
□
If
is a cuspidal automorphic distribution in a unitary principal series or complementary series representation, then all automorphic forms
will be bounded and rapidly decaying near the cusp at zero. In this situation, the estimates in Theorem 6 were well-known ([
3,
5]). The first estimate can also be obtained by observing that the Rankin-Selberg
has a pole at
for suitable
f and the coefficients of the Dirichlet series are all nonnegative ([
12]). If the (cuspidal) automorphic representation is a discrete series representation, the automorphic distribution
can be embedded in
for a suitable
u and will have its Fourier coefficients supported on
or
. Our estimates of Fourier coefficients also follow similarly upon applying the intertwining operator. The details of how to treat the discrete series representations can be found in [
4,
5].
3.5. -Norms of Bounded Periodical Matrix Coefficients
By considering the converse of Theorem 6, the equations in Proposition 3 also imply the following.
Theorem 7. Under the same assumption as Proposition 3, we have the following estimates.
- 1.
If and then there exists positive constant such that - 2.
If and for any , then
We shall remark that this theorem holds even is not unitary.
Combining Theorems 6 and 7, we have
Corollary 1 (
)
. Under the same assumption as Proposition 3, suppose for some the function is bounded on and is nonvanishing on both and . Then for any and , we haveIn particular, if is unitary, we havefor every . Proof. We only need to prove the second statement. If
, i.e.,
is a unitary principal series, then
If
is a complementary series representation, then the unitary Hilbert norm
is given by exactly the square root of
up to a normalizing factor depending on
u. Hence we have
Observe that
and
. The inequalities in the second statement hold for
. Therefore, they must also hold for
. □
Notice that Inequality (
9) is true for all
, in particular for
u with
reducible. Hence it applies to discrete series representation
. In addition, the norm on the right hand side of Inequality (
9) is bounded by
By the Kirillov model, this integral is a constant multiple of the unitary norm
([
13]). We have
Corollary 2 (discrete series case)
. Let be a discrete series representation. Let τ be a periodic distribution in with period . Suppose that for some , the function is bounded on . Then for any and ,for every and therefore . Here is the dual of . Notice that Theorem 7 holds for each . We obtain
Corollary 3 (
)
. Let be a unitary representation. Under the assumptions of Proposition 3, suppose that and Then there exists such thatIn particular,Both inequalities hold for those with which the right hand sides converge. In the case of automorphic forms, our
norms are estimated over a Siegel subset, but with the measure
, while the Siegel set is often equipped with the measure
. The bounds we have are certain norms on the representation. This allows us to treat everything at the representation level. If
, the bounds come from the Hilbert norm of the automorphic representation. We have nothing to improve on. If
, we will need to further study the norm
in more details. Our goal is to bound
by a more tangible norm. A natural choice is a norm coming from the complementary series construction.
4. K-Invariant Norms and Complementary Series
Let
. Recall that the smooth vectors in the noncompact picture of unitarizable
are bounded smooth functions on
with integrable Fourier transform. The Fourier transforms are indeed fast decaying at
∞, but singular at zero. For any bounded smooth function
with locally square integrable Fourier transform, let us define
whenever such an integral converges. This norm is indeed the unitary norm of the complementary series
, upto a normalizing factor. The standard norm
for the complementary series is often constructed using the standard intertwining operator
([
9]). Our norm
differs from the
by a normalizing factor. The standard norm
has a pole at
. The norm
does not. Hence
is potentially easier to use. In this section, we will first review the basic theory of complementary series. Then we will use
to bound the norm
. Our main references are [
8,
9].
4.1. Intertwining Operator and Complementary Series
The standard intertwining operator
is well-defined for
and has meromorphic continuation on
. In the noncompact picture,
Let
be the complex linear
G-invariant pairing
defined by
For any
, we define
This is a
G-invariant bilinear form on
. When
u is real and
,
yields an
G-invariant inner product on
. Its completion is often called a complementary series representation of
G, which is irreducible and unitary.
In the noncompact picture, the standard basis for the
K-types of
is given by
The intertwining operator
maps
to
. The constant
See [
8]. We make two observations here. First, the formula above in fact uniquely determined the analytic continuation of the intertwining operator
. Secondly, for
,
We have
Lemma 2. For a fixed or , there exist positive constants , such that The intertwining operator has a pole at . Hence we must exclude from our estimates.
4.2. Normalizing
Recall that for
and
By Fourier inversion formula, we have
where
. This is true for
and can be analytically continued to
, since the function
can be expressed in terms of
-functions and possesses a zero at
([
10]). Hence we have
for
. By Lemma 2 we have the following estimates:
Theorem 8. For , there exist positive constants , depending continuously on u such that and 4.3. Bounds by the Complementary Norm: Case
Fix
with
. Recall that we are interested in the norm
Clearly, this norm is
K-invariant. Hence we will need to estimate
.
Theorem 9. Let . Then there exists a positive constant such that Proof. Observe that
Under the compact picture of
,
becomes
The function
has period
and
derivative. Hence its Fourier series expansion
satisfy that
for some positive constant
. We obtain
It follows that
which will be bounded by a multiple of
. □
For
the map
preserves the
K action and maps
to
. By Theorems 8 and 9 there is a constant
such that
We have
Theorem 10. For and , there exists a positive constant such that Under the assumption of Corollary 3, applying Theorem 10, will be in as long as is bounded with .
4.4. Bounds by the Complementary Norm: Case
Let
and
. The
K-types in
are
Here
and
is well-defined. Our goal is to estimate
. We still have
In the compact picture of
,
becomes
. Notice that this function has period
and take the same value as
when
. Observe that
. Let
be its Fourier expansion. Again, the function
has
-derivative. Hence
. By a similar argument as
case we have
Theorem 11. Let . Then there exists a positive constant such that Theorem 12. For and , there exists a positive constant such that Proof. Consider the map
defined by
I maps the orthogonal basis
of
to orthogonal basis
of the complementary series
. In addition, one can easily check that
I is bounded. Our theorem then follows. Contrary to the spherical case, the operator
I is no longer
K-invariant. □
4.5. Bounds by the Complementary Norm: Case
Let
. Then
is the complementary series
. For
and
, we are interested in
For our purpose, we will assume that
.
Theorem 13. Let and . Then there exists a positive constant such that If , our proof is similar to the proof of Theorem 9. If , the proof will be different. We will be a little sketchy.
Proof. We have
. Under the compact picture,
. Let
be the Fourier expansion of
. Since
has
-derivative, we must have
for a positive constant
. We obtain
Notice
. If
, by Theorem 8,
which will be bounded by a multiple of
.
If
and
, we have
The first sum is bounded by
, since
. The second sum is bounded by
. We see that
□
By essentially the same proof as Theorem 10, we have
Theorem 14. For and , there exists a positive constant such that 5. -Invariant Norms over
Let
be a nonuniform lattice in
. Then
has a finite volume and a finite number of cusps,
. Write
as the union of Siegel sets
with a compact set
([
14]). Since
action is on the right, our standard Siegel set will be near 0, not
∞. Let
be the invariant measure of
G under the
decomposition. Over each Siegel set
, the invariant measure can be written as
.
Theorem 15. Let Γ be a nonuniform lattice in . Let be a cuspidal automorphic representation of type . Given any K-invariant measure ν on such that ν is bounded by on and bounded by on , there exists a constant C depending on ν (hence on ϵ) and such that
- 1.
- 2.
If , then for any ,and will be bounded the complementary norm given in Theorems 10, 12 and 14.
We shall remark that our theorem can be generalized to all nonuniform lattice of a finite covering of .
Proof. Let
and
. Let
. Then for any
, the left action
We see that the left action on
is equivalent to the action of
on
v. Fix
, a cuspidal automorphic representation of type
. By [
3,
5], there exists a
-invariant distribution
such that all smooth vectors in
can be written as
for some
.
Fix
. For each cusp
, we can use the action of
so that
. In the language of Harish-Chandra, this amounts to choose a cuspidal pair
. By Corollary 1, for each cusp
, we can choose a Siegel set
and find a constant
such that
Obviously, for the compact set
,
Hence, our first inequality follows.
Fix
. By Corollary 3,
defined for each cusp
. In the cases of
, By Theorem 10, the norm
Observe that the map from
to
defined by
is
K-invariant and the
is independent of the choices of the unipotent subgroup
N. Hence
remains the same for different choices of cusps. Over
, we have
We obtain
The complementary series case
is similar. The nonspherical unitary principal series
is more delicate. Essentially, norms
with respect to different
will be mutually bounded. Hence we still have
□
5.1. Bounds with Respect to
The decomposition fits naturally in the theory of Fourier-Whittaker coefficients of automorphic forms. It is used by number theorists to conduct analysis on automorphic forms, often over a Siegel set. However to understand the L-function of automorphic representation, in particular, the growth of L-function, the natural choice seems to be the decomposition. Both and originated in the Iwasawa decomposition and are closely related to Cartan decomposition. The analysis based on these decomposition seems to be of different flavor and have different implications. The G-invariant measure with respect to decomposition is or depending on the choices of N. The G-invariant measure with respect to decomposition is simply .
Recall that L-function for a cuspidal automorphic representation of can be represented by a zeta integral over . Hence it is desirable to have an estimate of the -norm of automorphic forms over , where a compact set with finite measure in .
Theorem 16. Let Γ be a nonuniform lattice in . Suppose that and . Let be a cuspidal automorphic representation of G of type . Then there exists a positive constant C depending on and such that Proof. By Theorem 5,
Since
is cuspidal, the
K-finite functions in
are bounded and rapidly decaying near the cusp 0. Again, we write
as matrix coefficient
for some
and
. Obviously,
will have no constant term in Fourier expansion. Its Fourier coefficients have the convergence specified in Theorem 6. By Corollaries 1 and 3, there exists
such that
Our theorem then follows. □
Corollary 4. Let Γ be a nonuniform lattice in . Suppose that and . Let be a cuspidal automorphic representation of G of type . Let Ω be a compact 2 dimensional domain in . Let . Then there exists a positive constant C depending on and Ω such that Proof. Obviously, any compact set in is contained in some . Hence . Then our assertion follows from the previous theorem. □
We shall remark that our results also apply to cuspidal automorphic representations of type with . The bound will be a constant multiple of as in Theorem 16.
5.2. Applications to Unitary Eisenstein Series
We shall remark that the Theorem 16 remains to be true if
The following proposition follows directly from Theorem 7.
Proposition 4. Let Γ be a discrete subgroup of such that and . Let be an automorphic representation of type . In addition, we can assume is given by with . Let and suppose with . Then If is a congruence subgroup containing w and the unitary Eisenstein series is cuspidal at 0 and ∞, we have
Corollary 5. Let Γ be a congruent subgroup of such that . Let be an Eisenstein series of type and . Suppose that has zero constant term with respect to N. Then Proof. The Fourier coefficients of Eisenstein series for congruence subgroups are computable ([
12]). It can be checked that
for
. □