Hardy Spaces on Homogeneous Groups. (MN-28), Volume 28 9780691222455, 069108310X
The object of this monograph is to give an exposition of the real-variable theory of Hardy spaces (HP spaces). This theo
234 96 14MB
English Pages 286 [298] Year 2020
Recommend Papers
![Harmonic Analysis on Homogeneous Spaces [1 ed.]
3540547029, 9783540547020](https://ebin.pub/img/200x200/harmonic-analysis-on-homogeneous-spaces-1nbsped-3540547029-9783540547020.jpg)
![A Primer on Hilbert Space Theory: Linear Spaces, Topological Spaces, Metric Spaces, Normed Spaces, and Topological Groups (UNITEXT for Physics) [2nd ed. 2021]
3030674169, 9783030674168](https://ebin.pub/img/200x200/a-primer-on-hilbert-space-theory-linear-spaces-topological-spaces-metric-spaces-normed-spaces-and-topological-groups-unitext-for-physics-2nd-ed-2021-3030674169-9783030674168.jpg)
- Author / Uploaded
- Gerald B. Folland
- Elias M. Stein
File loading please wait...
Citation preview
HARDY SPACES ON HOMOGENEOUS GROUPS
by G. B.
Folland and E. M. Stein
Mathematical Notes 28
Princeton University Press and University of Tokyo Press
Princeton, New Jersey 1982
Copyright © 1982 by Princeton University Press All Rights Reserved Published in Japan exclusively by University of Tokyo Press; in other parts of the world by Princeton University Press.
Library of Congress Cataloging-in-Publication Data Folland, G. B. Hardy spaces on homogeneous groups. (Princeton mathematical notes ; 28) Bibliography: p. Includes indexes. 1. Hardy spaces. 2. Functions of real variables. groups. I. Stein, Elias M., 1931II. Title. III. Series. QA331.5.F64 515.7-3 82-47594 ISBN 0-691-08310-X (pbk.) AACR2
3. Lie
Printed in the United States of America The Princeton Mathematical Notes are edited by Luis A. Caffarelli, John N. Mather, and Elias M. Stein
TABLE OF CONTENTS
INTRODUCTION
iii
Remarks on Notation
xii
CHAPTER 1: Background on Homogeneous Groups A. Homogeneous Groups
1 2
B. Convolutions C. Derivatives and Polynomials D. The Schwartz Class
15 20 35
E. F. G.
1+5 53 55 6l
Integral Representations of the 6 Function Covering Lemmas The Heat Kernel on Stratified Groups Notes and References
CHAPTER 2: Maximal Functions and Atoms Notes and References
62 79
CHAPTER 3: Decomposition and Interpolation Theorems A. The Calderon-Zygmund Decomposition
80 8l
B. The Atomic Decomposition C. Interpolation Theorems Notes and References CHAPTER k: Other Maximal Function Characterizations of H P A. Relationships Among Maximal Functions B. Construction of Commutative Approximate Identities Notes and References
97 107 111 113 113 128 139
Duals of
HP
A.
The Dual of
HP
B.
BMO
C.
Lipschitz Classes
156
Notes and References
182
CHAPTER 5:
CHAPTER 6:
spaces:
Campanato Spaces
1U6
Convolution Operators on
A.
Kernels of Type
B.
A Multiplier
HP
(a,r)
Theorem
Notes and References CHAPTER 7:
Characterization of H P by Square Functions: The Lusin and Littlewood-Paley Functions
Notes and References CHAPTER 8:
lUl lUl
Boundary Value Problems
l8U l8U 208 215
217 2k6 2^7
A.
Temperatures on Stratified Groups
2^8
B.
Poisson Integrals on Stratified Groups
253
C.
Poisson Integrals on Symmetric Spaces
26l
Notes and References
272
BIBLIOGRAPHY
273
Index of Terminology
28l
Index of Notation
283
INTRODUCTION
The object of this monograph is to give an exposition of the realvariable theory of Hardy spaces
(HP spaces).
This theory has attracted
considerable attention in recent years because it led to a better understanding in B
of such related topics as singular integrals, multiplier
operators, maximal functions, and real-variable methods generally.
Because
of its fruitful development it seems to us that a systematic exposition of some of the main parts of this theory is now desirable.
There are,
however, good reasons why in addition the theory should be recast in the more general setting where the underlying 3R group.
is replaced by a homogeneous
The justification for this wider scope, both in terms of the
structure of the theory and its applications, will be described in more detail below. Background:
Development of
The theory of
HP
H
theory
spaces is a multifaceted one with a rich history.
Here we can do no more than sketch its highlights . Originally functions
F
H
(0 < p < ») was defined to be the space of holomorphic
on the unit disc or upper half-plane such that
See also the overview by C. Fefferman [2].
su
Pn< 0, x G G ,
6 x
for
we shall denote them also by
6
reserving the notation
and call them
6
Sometimes we shall even write
is suggested by the case
G = Bn,
given by scalar multiplication.
x/r
for
with IR 0
6
—
6 , x.
6
as a
This notation
in which the natural dilations are
(Note, however, that we write the group
law multiplicatively, so the distributive law morphism property of
instead
for occasions
when it is required for clarity or when we wish to consider mapping.
rx
becomes
—
that is, the auto-
r(xy) = (rx)(ry).)
The analogy
is strong enough to persuade us to denote the group identity by
and to refer to it as the origin.
peculiar, but the equation
lim
The equation
rx = 0
xx" = 0
thus looks
comes out looking right.
Some examples may be in order. (1)
Abelian groups:
]R
is a homogeneous group with dilations given
by scalar multiplication. (2) group
H
Heisenberg groups:
If
n
is a positive integer, the Heisenberg
is the group whose underlying manifold is
(C x J?
and whose
multiplication is given by
H
is a homogeneous group with dilations 6r(z1,...,zn,t) = (rZ;L,...,rzn,r t ) . (3) Upper triangular groups:
matrices
(a. .)
such that
Let
G
be the group of all
nxn
real
a. . = 1 for 1 < i < n and a. . = 0 when i > j .
G
is a homogeneous group with dilations
These examples are all stratified groups.
It is also possible to
define other families of dilations on these groups.
For instance, on 3R
we can define d.
where
1 = d_ < d o < ••• < d , and on 1 - d n
H
min{a ,...a ,b ,.. . ,b } = 1
when we refer to 1
or
H
we can define
n b
a,
6r(x1+iy1,...,xn+iyn,t) = (r ^ i r where
d
and
±
a
b
y1,...,r \ + i r
a.+b. = c
X ^ t )
for all
j. However,
we shall assume that they are equipped with
the natural dilations defined in (l) and (2) above unless we state otherwise. Henceforth we shall be working on a fixed homogeneous group dimension
n
with dilations
the eigenvalues of
A,
{6
= exp(A log r)}. We denote by
of
d ,...,d
listed in increasing order and with each eigenvalue
listed as many times as its multiplicity, and we set 1 = d < d < ••• < d 1 - 2 - n We also fix a basis
G
Xl9...,X
and we define a Euclidean norm
of
g
Q
Thus
= d.
such that
II • II on
d = max{d.}. J
AX. = d.X.
for each j ,
by declaring the
orthonormal.
We may also regard this norm as a function on
obvious way:
llxll = llexp xll.
G
X.'s
to be
in the
The Euclidean norm is of limited utility for our purposes, since it does not interact in a simple fashion with dilations.
We therefore define
a homogeneous norm on
x -> |x| from
to
[0,~) which is
|rx| = r|x| x = 0.
G
to be a continuous function
C°° on
for all
xGG
G\{0} and
X ^ 0,
tends to
is
then,
0
or
II6 Xll
C
|X| = 0
and on
if and only if
^)\
is a strictly increasing function of r.
Hence there is a unique
and we may define a homogeneous norm on
|x| = l/r(exp~ x) G\{0}
116 Xtl = (Z^c2r
implies
°° along with
116 r vXll = 1,
101 = 0
(b)
|x""11 = |x| and
Observe that X = EVx.Gg
that
r > 0,
(a)
Homogeneous norms always exist; one example may be constructed as
follows.
If
and satisfies
for
x / 0.
r
which
r(X) > 0 G
00
C
Henceforth we assume that
(The fact that this function
manifold.) G
_is_ equipped with a_ fixed homogeneous
norm. x6G
and
r > 0
we define
B(r,x) = {yGG : \x~1y\ < r}, and we call B(r,x)
B(r,x)
the ball of radius
is the left translate by
image under (l.U)
6
of
LEMMA.
x
of
r
about
B(r,0),
x.
We observe that
which in turn is the
B(l,0). For all
xGG
and
r > 0,
such
by setting
follows from the implicit function theorem since the
Euclidean unit sphere is a
If
G
B(r,x)
is compact.
Proof:
Let us define l/d. p(x) = E°|c.| J
Then
p
and does not contain n
on it.
that
|x| > np(x)
Thus
B(n»0)
B(r,x)
0,
|rx| = r|x|
for all
x,
x •* |x| assumes a positive
and
p(rx) = rp(x),
and hence that
r > 0,
xGG.
There exist
(^ llxll < |x| < C2llxlll/d
If
y = exp(Zc.X.) J J
r llyll < llryll < rllyll a positive maximum x ^ 0
is compact
it follows
B(n,0) c {x : p(x) < 1}.
is compact, and it follows by dilation and translation that
is compact for all
Proof:
{x : p(x) = 1 }
C . Clearly
so the function
Since
(1.5) PROPOSITION.
Any
x = exp(z![c.X.)
satisfies all the properties of a homogeneous norm except that it
is merely continuous instead of
minimum
for
for C
r < 1.
C ,C
> 0
whenever
then
2 2d i ± llryll = (Ec.r J ) J
where
|xy|
|x|dHyll > C " d | x | d .
There is a constant
x,yeG,
2
By Lemma l.k, the Euclidean norm assumes
x = |x|y
| llyll < C ^ l x l ,
such that
|x| < 1.
and a positive minimum
can be written as
(1.6) PROPOSITION.
#
C > 0
such that for all
10
Proof:
By Lemma l.k9 the set
compact, so the function it.
Then, given any
{(x,y)e G x G : |x| + |y| = 1}
(x,y) ->• |xy|
x,yGG, set
assumes a finite maximum
is C
on
r = |x| + |y| . It follows that
|xy| = rlr^txy)! = r | (r^x) (r'V) I f Cr = C(|x| + |y|). #
By Proposition 1.2, Lebesgue measure on Haar measure on
G.
Q
We_ now fix the normalization of Haar measure on
by requiring that the measure of the usual norm, our measure is
B(l,0)
be_ 1.
r( (n+2)/2)/7r
denote the integral of a function or
f
G
G = B n with
(Thus, if
times Lebesgue measure.)
We shall denote the measure of any measurable
Jt
induces a bi-invariant
E c G
by
|E|, and we shall
with respect to this measure simply by
/f(x)dx.
The number Q = E^d. = trace(A) will be called the homogeneous dimension of |6p(E)| = rQ|E|, In particular,
|B(r,x)| = r^
A
( A G E ) if
f
on
G\{0}
f°5r = r f
Clearly we have
d(rx) = rQdx.
for all
r > 0, x 6 G .
always denote the homogeneous dimension of A function
G.
Henceforth
Q
will
and
g,
G.
will be called homogeneous of degree
for
r > 0.
We note that for any
f
jf(x)go xy
smooth, so by the mean value theorem and Proposition 1.5, |f(xy) - f(x)| < Cllyll < C'|y| = C |y | |x | X ' 1 . #
This proposition may be applied, in particular, to the homogeneous norm.
Combining this with Proposition 1.6, we see that there exists a
constant (1.8)
y
such that |xy| < y (|x| + |y|)
for all
x,yGG,
is
12
(1.9)
||xy| - |x|| < y|y|
Henceforth
y
and (1.9).
Clearly
for all x,yQG
such that
|y| < |x|/2.
will always denote the minimal constant satisfying (1.8) y > 1.
We shall use (1.8) and (1.9) without comment
in the sequel. The following simple fact will be useful later: (1.10)
LEMMA.
Proof:
Since
For all
xjeG
and
s > 0,
|x| < y(|xy~ |+|y|) we have
1 + |x| < Yd+lxy^lKl+iyl), and we obtain the desired inequality by raising both sides to the
s-th
power. # We now establish our notation for some common function spaces on (with apologies for some slight inconsistencies). If
Q, c G, C(^),
(C (tt),C (Q)) denotes the space of continuous functions on compact support, vanishing at infinity). the class of
k
If
Q
G
is open,
C
G
(with
(k) (tt) denotes
times continuously differentiable functions on fi,
C*(a) = r\^ C^(ft),
and
C~(ft) = C°°(ft) n CQ(a).
usually omit mentioning it. Lebesgue space on
G.
For
If
0 < p < °°, L
0 < p < °° we write
llfllp= (j|f(x)| p dx) 1 / p ,
When
Q = G
we shall
will denote the usual
13
even though t h i s i s not a norm for however, a metric on
L
We recall that if function
for f
p < 1.
(f,g) -> Hf-gllP
(The map
is,
P
p < 1.)
is a measurable function on
G,
its distribution
X f : [0,°°) -> [0,°°] is defined by
(1.11)
Af(a) = |{x : |f(x)| > a}|,
and its nonincreasing rearrangement (1.12)
f* : [0, [0, Q a P A f (a) = sup t>o t l/p f*(t) < «,. It is easily checked that
[f]
< llfll
(Chebyshev's inequality).
not a norm, but it defines a topology on weak which is bounded from
L
to weak
L
[ ]
is
L . A subadditive operator
is said to be of weak type
(p,q).
We conclude this section with some results concerning integration in "polar coordinates". (1.13) o_f degree
PROPOSITION.
I£
f
is continuous on
-Q, there is ji constant
y
G\{0}
(the "mean value" of
i
for all g G l ^ U O ^ K r ^ d r ) , (1.1*0
and homogeneous
f f(x)g(|x|)dx = y I g(r)r"1dr.
f)
such that ————
— — —
Ill
Proof :
Define
L f : (0,«) + QJ by
Mr) = l sx
and using the homogeneity of
L (rs) = Lf(r)+Lf,(s)
is continuous, it follows that
for all
L (r) = L (e)log r,
Then equation (l.lU) is obvious when
g
r,s > 0.
and we set
Since
f, L
y f = L f (e).
is the characteristic function of
an interval, and it follows in general by taking linear combinations and limits of such functions. (1.15)
PROPOSITION.
Radon measure
a
on_ S
then
?
If
Let_ S = {x G G : |x| = 1}. There is a (unique) such that for all
u G L (G),
f u(x)dx = r fu(ry)r
da(y)dr.
J
Proof:
#
j
G
0 ji
let us define f on G\{0} by f(x) = |x|""Qf ( Ixl^x)
fGC(S),
satisfies the hypotheses of Proposition 1.13.
clearly a positive linear functional on against a Radon measure
a
on
S.
If
0 jS
f ->- y~
is
C(s), so it is given by integration g 6 C ((0,»)),
f f d x I ' ^ g d x D a x = f f(x)|x| Q g(|x|)dx =
j
The map
w?
f(y)g(r)rQ"1da(y)d
then, we have
Since linear combinations of functions of the form dense in
L (G), the theorem follows.
Remark:
The measure
o
f(|x| x)g(|x|)
are
#
can be shown to have a smooth density:
cf.
Fabes and Riviere [l] and Goodman [2], (1.16)
COROLLARY*
Let
C = a(S).
Then if
|x|a-Qdx = C c T ^ - a 0 1 )
J
0 < a < b < ~
if
a t 0,
if
a = 0.
and
aG
a 0, set
is the conjugate exponent to g-Jx) = 0
otherwise,
p. Define
and set
g 2 = g-g 1 -
Since
W
- f*Sl
x
f*g2(a/2)'
it suffices to show that each term on the right is bounded by C
depends only on
we have
1
p -q > 0
p
and
q.
On the one hand, since
q
Ca"
- (p1)
where = r
and hence
g1 fx)|P'dx = p'f a 5 '" 1 *g (a)da < p>f a 5 '"s1 * (a)da J 0 l " J o V o
= ^ - M P ' - I = ±U^'/r = (a/2)pl. P'-4
Thus for all xG G,
|f* g ; L (x) I < llfllpllglllpI < a / 2 ,
1
> 0,
18
which implies that
A
(a/2) = 0 .
On the other hand, since
,]V[
,00
|g (x)|dx =
A J0
S
(a)da = 2
q > 1,
.00
A (M)da + A (a)da •'0 s -"M S
and hence by Proposition 1.18,
p But then
g
(a/2) < [2llf*g 2 ll p /a] P
P _, pr(l-q)/q pr(l-q)/qp' P P n fl) < (£.) (_2_) tSL)
= C(p,q)a" ,
so we are done. §
We now summarize the basic facts about approximations to the identity. The following notation will be used throughout this monograph: a function on G
and t > 0,
we define
t = t"Qcj)o 6 1 / t ,
We observe that if G L
then
if $ is
< j > by
i.e., cf)t(x) = t~Q(j)(x/t).
.(x)dx
is independent of t.
19
(1.20)
PROPOSITipN.
(i)
If
feLP
(ii)
Lf
f
llf**.-afll T t
oo
->• 0
(iii) then
Suppose
(1 < p < « ) ,
i^GL1 then
and
U(x)dx = a.
llf* -afll
-> 0
as
Then: t + 0.
i s "bounded and r i g h t uniformly continuous, then
as —
If_ f
t -*• 0. ijs_ "bounded on G and continuous on an open set ft c G,
f*4>, - af •* 0 uniformly on compact subsets of ft as t -> 0. Proof:
If f
f^x) = f U y " 1 ) .
is any function on G
If f G L P ,
(1.21)
and y&G,
let us define
1 < p < «, it is easily seen that
llf^-fl! -*• 0 as y -> 0.
(Use the fact that only if f function.
C
is dense in LP.) If p = «,
(l.2l) holds if and
is (almost everywhere equal to) a right uniformly continuous We observe that f*cj)t(x) -af(x) = |f(xy""1)t""Q4)(y/t)dy-af(x)
=
f(x(tz)"1)4)(z)dz-af(x)
=J> Hence by Minkowski's inequality, llf*, < IIf Z - f l l |Uy( vz ) | d z . y - a f II t p - J p " Since
llftZ-fll
< 211 fII , under the hypothesis of (i) or (ii) it follows
from (1.21) and the dominated convergence theorem that
llf*.-af II •> 0. L p
20
The routine modification of this argument (with (iii) is left to the reader.
C.
p = »)
needed to establish
#
Derivatives and Polynomials
There are three common ways of viewing the elements of the Lie algebra g
of
G:
(l) as tangent vectors at the origin,
vector fields,
(2) as left-invariant
(3) as right-invariant vector fields. We shall have no use
for the first interpretation, but we shall need both of the others. Accordingly, let us denote by
Q
and
and right-invariant vector fields on of identifying
g
with
g
G.
the spaces of left-invariant We shall follow the usual custom
g , and in particular we shall think of the
exponential map as going from
gT
to
G.
(This point is not entirely
JJ
trivial, since the map which sends with
X
Xeg
to the unique
XGg-, which agrees
at the origin is an anti-isomorphism rather than an isomorphism:
that is,
[X,Y]~ = [?,X].
formula to
Hence if one applies the Campbell-Hausdorff
g , one obtains a different, although isomorphic, group law for
G.) We recall that in Section A we fixed a basis consisting of eigenvectors for the dilations d
r
l
d
,...,r
n
. The
X.'s o
differential operators on basis for
gR:
Thus, for
f G (T
6
X ,. .. ,X
for g
with eigenvalues
are now to be regarded as left-invariant G,
that is, Y.
and we denote by is the element of
Y , ...,Y gR
the corresponding
such that
Y.|Q = X.|Q.
,
X.f(y) = -£rf(yexp(tX.))|, n , j at j 't=0
Y.f (y) = -£-f (exp(tX. )-y) | . j at j 't-u
21
The differential operators
X.
and
Y.
are homogeneous of degree
d.,
for Xj(f°6 r )(y) =^f((ry)exp(r
J
tXj)|t=Q
d. „ d. = r d ^-f((ry)exp(tX.)) I n = r J(X.f ( dt j 't=0 j and similarly for
Y..
We adopt the folloving multiindex notation for higher order derivatives. If
I = (i ,...9in) GlT n ,
we set
2
••• X n,
X1 = X^X
Y1 = Y "4 2 ••• Y n.
By the Poincare*-Birkhoff-Witt theorem (cf. Bourbaki [l], I.2.T), the operators X (resp.
Y ) form a basis for the algebra of left-invariant (resp. right-
invariant) differential operators on
G.
Further, we set
Thus
|l| is the order of the differential operators
d(l)
is their degree of homogeneity, or, as we shall say, their homogeneous
degree. by I
We shall denote by
A
If .
A
is the set of all numbers
We observe that i c A
We pause to make two useful remarks. translations are isometries on skew-adjoint.
and
Y , vhile
the additive sub-semigroup of JR generated
0,d ,...,d . In other words, ranges over
X
2
since
d
as
=1.
First, since left and right
L , the operators
X.
Thus,
J(xJf)g = (-D^jftfg),
d(l)
Jf(Yxg) = (-D^
and
Y.
are formally
22
for all smooth infinity.
f
and
g
such that the integrands decay suitably at
Second, the operators
X
and
Y
interact with convolutions
in the following way: XJ(f*g) = f t t ^ g ) ,
YI(f*g) = ( Y ^ U g ,
( X ^ U g = f*(YTg).
The first two of these equations are established by differentiating under the integral sign, while the third is established by integration by parts: (XIf)*g(x) = |xIf(xy)g(y"1)dy =
(-1)I1'jf(xy)XI[g(y"1)]dy
= |f(xy)(YIg)(y"1)dy = f*(YIg)(x). We now investigate polynomials on called a polynomial if £,...,£ for
g,
Po exp
G.
A function
is a polynomial on
the basis for the linear forms on and we set
r\. = £. o exp J
J
. Then
which form a global coordinate system on polynomials on
G.
G
g
_ i (n = n 1
T
n , ...,n n
degree. If
N G I
—
will be
We denote by X ,.. . ,X
are polynomials on
G
G
can be written uniquely as
i ••• T^11, a^ffi) a
vanish.
Clearly r\
d(l), so the set of possible degrees of homogeneity
for polynomials is the set refer to its degree
G
and generate the algebra of
where all but finitely many of the coefficients is homogeneous of degree
on
dual to the basis
j.
Thus, every polynomial on
p = E^n
g.
P
A
introduced above.
that is, max{|l| : a
If
^ 0}
P = £aTn , we shall —
as its isotropic
Further, we define its homogeneous degree to be max{d(l) : a^ f 0}. we denote the space of polynomials of isotropic degree
< N
by
23
P
, and if
degree
< a
aGA
by
we denote the space of polynomials of homogeneous
P . Since a
p c P* so c pN N dN
for
1 < d. < d - j -
for
j = l,...,n, we clearly have
NGI.
We can now give a more explicit description of the group law in terms of the coordinates
n . • Since the map 3
(x,y) -> n.(xy) J
is a polynomial on
GxG
which is jointly homogeneous of degree d. (that is, J d n.((rx)(ry)) = r n.(xy)), and since the Campbell-Hausdorff formula 2, ~
we must have (1.22)
ru(xy) = TK(X) + nj (y) + I ^ 0 > J ^ u
for some constants
C. . Since the multiindices J
I
and
J
in (1.22) must
satisfy
d(l) < d. and d(j) < d., it follows that the monomials 3 3 can only involve coordinates with degrees of homogeneity less than and in particular can only involve the coordinates
n 9. • . 9ri.
n ,n d., 3
. We note
two special cases: (1.23)
d. = l:
n.(xy) = n.(x) + n.(y).
(1.2U)
d. = 2:
n.(xy) = n. (x) + n .(y) + L
3 (1.25)
3 PROPOSITION.
3
3
For_ anv_ a G A ,
V V
_-, _n C.£n (x)n (y). 1
3
the space
k
l
P
is invariant
under left and right translations. Proof: function of Since the
From (1.22) it is clear that x
n.'s 3
for each
y,
n.(xy)
is in
and also as a function of
P y
as a for each
x.
generate all polynomials, the result follows immediately.
#
2k
Remark: G
P
is Abelian). (1.26)
is not invariant under translations (unless
PROPOSITION.
We have
' V
Proof:
P.. ,Q._ JK Jk
For
or
Consequently, it will not be of much use to us.
=X
k ^ j, and
N = 0
V
=
° ^
d
k < dj ^ ^
d =d
k J SSi
are homogeneous polynomials of degreee
xGG
define
different iable function
f
on
L x : G -> G G
by
Lx(y) = xy.
cL-d. K J
if
Then for any
and X G G ,
X.f(x) = (X.f)oL (0) = X,(foL )(0) = (3/3n.)(foL )(0) 3 J x j x j x since
X. agrees with 1,
#
—
will occur
3 will always denote this G = ]Rn
with equality when
and
|»|
is the Euclidean norm. (1.36)
LEMMA.
Proof:
Since
If
aGA
then
|l| < d(l)
On the other hand, since
d
max{ 111 : d(l) < a} = [a] .
for all
= 1,
for
I,
d(l) < a
implies
I = ([a],0,0,...,0)
|l| < [a].
we have
|l| = d(l) = [a]. # (1.3T) THEOREM (TAYLOR INEQUALITY). k = [a]. There is &_ constant class
C
cm
G
and all
C
> 0
degree
P a.
aGA
(a > 0),
such that for all functions
and f
x,yGG,
W where
Suppose
d(l)
is the right Taylor polynomial of
f
at_ x
of_ homogeneous
of
30
Proof: while
Let
YJg(0) = 0
g(y) = f(yx)-P (y). Then
Y g(y) = Y f(yx)
1 < m < k+1, that if
for
d(j) > a.
a-m < d(j) < a
for
d(j) < a,
We shall show by induction on
m,
then
|Y J g ( y ) | < C m I |
(1-38)
The desired result then follows by taking First suppose
a-1 < d(j) < a.
m = k+1
and
J = 0.
Then by the mean value theorem (1.33),
YJg(0) = 0,
since
|YJg(y)| < C I*=1 | y M s*P|z| a
then
Y g(z) = Y I f(zx),
so
S.
is dominated by the right
j
«J
hand side of (1.38) (since d(j)+d. > a-m+1 3 obtaining
sup
3 > l ) . If d(j)+d. < a we have ~* J ~* and we can apply the inductive hypothesis to
Y g(z),
z|°(Y) = exp Y, ^ X
where
. (Y) = [•••[[exp Y,exp X. ],exp X. ],...,exp X. ] X 1 l "" 1j ^l 2 j
[x,y] = xyx~ y~ .
By the Campbell-Hausdorff formula, for any
X,Yeg
we have [exp X,exp Y] = exp([X,Y] + higher order terms). Therefore, if we identify the tangent spaces of B Vn
and g
i s given by
and G
at the origin with
respectively, we see that the differential of ^. X l " # Xj
at 0
d°(O)(Y) = Y, X, ] , . . . 2
Now consider the map
from the (ZQ"" 1 ^ )-fold product of B
with itself into
G. Since
V
33
generates
g,
the preceding remarks (together with another application
of Campbell-Hausdorff) show that the differential onto
g.
Consequently, there exists
includes all of
G
xGG
with
is a product of
|x| < 6. 3 # 2 J -2
be written as the product of whose norms are at most as the product of |x|/ 0
d(j)(O)
such that the range of
Since a commutator of
elements, any J
xeG
J
N = Z^" v (3'2 -2)
exp(V )
j+1
with
$
elements
|x| < 6 can
elements of
By dilation, then, any
elements of
is surjective
xGG
exp(V )
can be written
whose norms are at most
#
G
is stratified, we have
A = If,
to be the space of continuous functions
derivatives
X f
and for f
are continuous functions on
on G
connection it is worthwhile to note that since
kGlf
G
whose
for
V
we define (distribution)
d(l) < k.
generates
g,
In this the set
of left-invariant differential operators which are homogeneous of degree j
—
that is, the linear span of
linear span of the operators
(l.Ul) There exist
{X : d(l) = j}
X. ••• X. ix ij
with
STRATIFIED MEAN VALUE THEOREM. C > 0
and
b > 0
is precisely the
1 < i < v - k -
Suppose
such that for all
|f(xy)-f(x)| f C | y | s u P | z | ? ) | y | j l ^ v
Proof;
—
G
fG C
for
k = l,...,j.
is stratified. and all
x,y6 G,
|x.f(xz)|.
The proof is identical to the proof of Theorem 1.33 except
that one makes the initial estimate only for Lemma 1.1+0 instead of Lemma 1.31.
#
yGexp(V )
and then uses
(1.1*2)
THEOREM (STRATIFIED TAYLOR INEQUALITY).
stratified.
For each positive integer
_____________-
______
G
there is a constant
is_ C
such
j£ _______
feCk
that for all
k
Suppose
and all_
x,yGG,
|f(xy)-P x (y)| < C k | y | k n ( x , b k | y | ) ,
where
P
is the left Taylor polynomial of
________
•£
degree
k,
_ _
______ _______
b
f
at
x
____
of homogeneous ___
_is_ as_ jLri Theorem l.Ul, and for
r > 0,
n(x,r) = s u P | z | < r j d ( I ) = k lx f(xz)-XIf(x)|.
Proof:
Let
g(x) = f(xy)-P x (y),
We shall show by induction on
|j|= k
then
X P
that if
= 0
for
d(l) < k.
d(j) = k-m
then
is a constant function, hence
X J P x ( y ) = X J P x ( x ) = X J f(x) m = 0,
0 < m < k,
X^O)
|X J g(y)| < C.|y| m n(x,b m |y|).
(1.1*3)
If
m,
so that
and so
X J g(y) = X J f(xy)-X J f(x).
(1.U3) is just the definition of
| j | = k-m+1,
and
suppose
| j | = k-m.
n.
Thus for
Suppose (1.U3) is true for
Then by Theorem l.Ul, since
X J g(0) = 0,
|x J g(y)| < C | y | s u p | z | < b | y | 5 l ; . f v
X.X J is a linear combination of J so by inductive hypotheses,
But
XIfs
|x.X J g(xz)|.
with
D(l) = d(j)+l = k-m+1,
|XJg(y)| j in If
GS
S
i f and o n l y
and
yGG,
y(x) =
(xy),
let y
us
Il.-IL x -> 0
for a l l
N.
define
c()(x) =
cf>(yx),
$(x) =
^(x"1).
(This notation will be used consistently in this section, but not afterwards . ) (1.U6)
PROPOSITION.
that for a l l
Moreover, Proof:
6 S
and
IIy- IL v -> 0
For each
N e l
there exists
>0
such
n
yGG,
and
C
Ily(|)-(J)II, , -> 0
?is_ y -> 0 .
F i r s t , b y Lemma 1 . 1 0 ,
Next we observe that
(YI$)(x) = (-1)'I'(X1^)(x"1),
and by Proposition 1.29
we have
" E|j|d(l) P IJ Y '
P
UGPd(j)-d(l).
37
Now
| j | < |l| < N
implies
d(j)-d(l) < d(j) < d | j | < QN,
(N+l)(Q+l)+d(j)-d(l) < (2N+1)(Q+1),
hence
and thus
-1 The estimate for
then follows immediately since
y
• 0 That
II 0.
#
Convolution is continuous from
N G IT
there exists
C
> 0
By Lemma 1.10,
ay. #
S^5
to_ S.
such that for all
More
C(>,IJJGS,
38
The dual space G.
If
fGS'
and
S'
of
(J> 6 S
S
is the space of tempered distributions
we shall denote the evaluation of
f
on
on
cj) by
(x)dx. Convergence in
S'
if
< f. ,cj> > -> < f , >
and o n l y i f If
feS
f
will always mean weak convergence:
and
(> G S
for
we d e f i n e
f# G S
In particular,
Proof:
and
If
S'
f#
by
f*cj> is continuous; in fact, I.
there exist
and for any
The continuity of M6l, |
feS'
in
N G 3N
and
C > 0
such
xGG,
f*(J)GS?,
to the existence of
for all
3
.
x)dy =
It follows easily from Proposition 1.1*6 that I
f. -* f
GS.
the convolution
f(y)*(y
thus
|
f
C > 0
i> Q S
we have
as a linear functional on such that )
for
S
is equivalent
39
Thus by Proposition 1.U6, if
N = (2M+l)(Q+l)
we have
= || < C(] The verification of the second statement is a simple exercise which we leave to the reader. (I.U9)
PROPOSITION.
feSf,
\\JGS and
# Suppose
ijj*cj>, -> aij; in
. 6 S
S
f*cf>, -> af
t
Proof:
and
L(x)dx = a. in
t
S1
•
as
Then for any
t -> 0.
~—~~
For the first assertion we merely repeat the proof of
Proposition 1.20, using the norms
II II / v instead of
necessary estimates are provided by Proposition 1.U6. follows from the first:
since
$ =
and
L
norms; the
The second assertion
($) = ( G S
we have , ,i|i> = -> a t t
as
t -»• 0.
#
The remainder of this section is devoted to some technical results which we shall need later.
The first one is a global version of the
Taylor inequality (1.37) for Schwartz class functions. (1.50) THEOREM. N = [a]+l. of_ cj> at_ x
If
(j)GS and
whenever
xGG,
let
of homogeneous degree
There is a constant
d(l) < a
a 6 A,
Suppose that
Px
a,
C,
independent of
and
|x| > 2y$ |y|.
b = min{b! e A : b f > a},
and
be the right Taylor polynomial and let
R (y) = (yx)-P (y).
, such that
ko Proof: Y at
x
If
d(l) < a
then
Y P
of homogeneous degree
is the right Taylor polynomial of
a-d(l),
and
[a-d(D]
= N-l-111 .
Thus by the Taylor inequality
(1.37),
M Now J
Y Y
|z| < 3 |y| Z
implies
|z| < |x|/2y
is a linear combination of
|K| < |l|+|j| < N.
and hence, since
Y
Kf
s
d(J)
and hence with
|zx| > |x|/2,
d(K) = d(j)+d(l)
and
and
Therefore,
|l|+|j| < N
implies
d(l)+d(j) < QW,
The next sequence of lemmas deals with estimates for functions of the form 0
For every
such that
Nf = N+j(2d-l).
N,jG K
and every multiindex
I
there
Proof:
Since
Y (\p*9J 0
such
that su
where
W,s o ,..., £
Nf = N+Q+l+(Z^j.)(2d-l).
Proof:
The case
k = 1
is Lemma 1.52.
If
k = 2,
for
0 < sn < 1
h we set
\JJ! = ij;*8 S
U
S
2-
l
. S l
j
By Lemmas 1.52 and 1.53,
S
l
S
l
S
2
S
2
N+Q+l+j (2d-l)
)
I +j
+j
Since this holds for all
s 6 (0,1],
the assertion is valid for
The proof is now completed by an obvious induction on
k.
k = 2.
kk (1.55) PROPOSITION. there exists
Given
cj) G S and N,j
with
A . =
C > 0 such that for all J
f, . ^N, h
(1.56)
j 6B
k
sup__ ^n j(1+ 'x ) 3s y Lemma 1.36,
S We have proved the case
°
U»P = 0
N =1
-
The general case is now established by induction on and PGP
J
cf>P = 0
M4d]-
(,
for all
immediately.
= EX.4> 3 3
where
M
Pe
^ffdlN'
fr
°m
which the desired
N.
If
(j> 6 S
L P = 0 j3
for all
X1*^
where
result follows
#
(l.6l)
(a)
then
By inductive hypothesis, *. = l ^ ^ ) ^ ^
= 0
(where
for all P e P .M f °
for all
THEOREM.
For_ anv_ N G l
depends on, N)
L^P =
M P
there exist
cf)1,. . . 9^9ii)19.
. . ,i|;M 6 5
such that:
= 0 for_ all_ PeP , 1 < j < M, = 6.
Proof:
First pick
(|> 6 S
such that
U = 1
J polynomial
P
without constant term.
and
UP = 0
for every
J
(For example, let
cf) be the inverse
[Euclidean] Fourier transform of a Schwartz class function which is identically one near the origin.)
Set (j)' = d ,/dt | ,_-, • Since $. satisfies the same t t-~l t , T U ) = $(t£). o
If 4>GS, then to
f e S ' , we say that
f*c{>, ->• 0 t f
in
S»
as
f
vanishes weakly at infinity if, for any
t -> » .
f G LP
For example, if
vanishes weakly at infinity, since if
q
where
1 < p < «> , —
is the conjugate exponent
p,
l l f # 4 > . II
t»-
{1.6k) THEOREM. for any
f G 5f
< l l f l l I I * . II =
e
•tdt/t -> f
(j>cS,
I I f II llll
p q
t""Q/p.
U = 0, and J which vanishes weakly at infinity,
I
Suppose
p t q
I (J),dt/t = 6. 0 t
J
Then
51
Proof:
Let
we can write
a =
f1 Jo
4>,dt/t, t
$(£) = E £.$.(£)
3= with
f°° Ji
cj>,dt/t. Since t
°° .
£,
so
a
is
X
|(3/3^) $(^)| < C N (l+|c|)" $(t?)dt/t |^| > c,
for any 3
c > 0,
But
is also smooth near the origin.
and hence also
3 = 1- a = l-a(0) = 1. ,OO
3,
and are
Now observe that for
3 = 6—a = 1-a, 3,
so
s > 0,
,00
so that
rA fG5f,
then,
f*cj) dt/t = f*3£-f*3A-
Proposition 1.^9> and if A -> °° .
#
f
But
f*3
•> f
vanishes weakly at infinity,
as
e -> 0
f*3A "•" 0
3
is in
3 = dt/t = (|),dt/t, s j 1 st Jg t
If
N,
agrees with a Schwartz
class function except perhaps near the origin.
and
for any
and all of its derivatives
In other words,
Therefore
C . Also N
as
by
S,
52
Our final result shows that if
cj) G 5
and
U = 0
then
J always converges in
S',
Sf
THEOREM.
If_ 0, A -> °° i°_ iiL distribution which is
and homogeneous of degree Proof: with
(j) dt/t C
Then, if
converges in
away from the origin
-Q.
As in the proof of Theorem 1.6k we write
.GS. J
t
although usually not to the 6-function.
f (1.65)
cj) dt/t
JQ
I > Q+d
and
|^|
$(c) = 2^.$.(?)
denotes a homogeneous norm on g
r n dr1 |$(t^)|dt/t = |Z t ) •'O 100
J
^.$(t^)|dt J
d. -1
d.
t J kl J(] < CExn[
'JO 0
t
J
|c|
J
dt + I
J
t
k|
J
dt]
= C.
This shows that
Therefore
$(t£)dt/t •'0
I dt/t
J
t
converges pointwise and "boundedly, hence in
converges in
S'.
Moreover, for any
i|; 6 S
and
r > 0,
r
rA (• rA r rA/r (J), (x)i|>(rx)(dt/t)dx = 4>+(x)i|;(x)(dt/t)dx = +(x)i|;(x J t J J JQ e G J£ rt G Je/r * Letting
e -»» 0, A -»• °°,
distributions that
we see from the definition of homogeneity for
0.
(j) dt/t is homogeneous of degree
>
t
S'.
-Q. Finally, if
53
K c G
is a compact set which does not contain the origin and
multiindex, bounded as
X (x/t) t •*•«>,
vanishes to infinite order as
uniformly for
t -> 0
I
is a
and remains
X G K , S O the integrals
X 1 f . (x)dt/t = f t - Q - ^ 1 5 " 1 XX(|)(x/t)dt converge uniformly on
K.
Thus
. dt/t J
F.
0
is
C
away from the origin.
#
t
Covering Lemmas
In this section we present two useful covering lemmas, which are variants of classical results on IR
(1.66) WIENER LEMMA. positive function. open,
Suppose
(finite or infinite) sequence
Proof:
E c G
and
Assume that either (a)
| E | < °°, and B(r(x),x) c E
are disjoint, and
due to Wiener and Whitney.
E
for all
{x.}
in
E
r : E •> (0,») JLS_ an arbitrary ±s_ bounded, or_ (b)
xeE.
E
is
Then there exists a
such that the balls
B(r(x.),x )
E c W . B(Uyr(x.) ,x.) . 0 J J
We may assume that
sup
automatic, whereas in case (a), if
r(x) < °° .
sup
In case (b) this is
r(x) = °° there exists
xGE
XteHj
such that that
E c B(r(x),x),
so there is nothing to prove.
r(x ) > 1/2 sup x G £ r(x).
wise, we continue inductively: E. = E\V^ B(^yr(x. ),x. ). J 1 1 1 such that
If
If
E c B(Uyr(x1),x )
having picked E. = 0 j
Pick
we are done.
x ,...,x.,
we stop.
x GE
Other-
we set
If not, we pick
r(x. ) > 1/2 sup r(x). Observe that if J "t"-L — XGili . r(x.) < 2r(x.) (otherwise, we made the wrong choice of
such
i < j
x
GE. j +Jj
then
x . ) . Hence if
51*
B(r(x.),x.)
intersects
B(r(x.),x.),
we have
Uyr(xi) < |x~ x.| < y(r(xi)+r(x.)) < 3yr(x ) which is a contradiction.
Hence the balls
We claim t h a t the "balls
B(*+yr(x.) ,x .)
B(r(x.),x.)
3 3 cover E.
3 J is finite this follows from our construction.
{x.} 3 balls
B(r(x.),x.) °° .
Hence if there existed
xeE\\u/T B(l*yr(x.) ,x.) we would have r(x) > 2r(x ) for -i J J K. large, contradicting the choice of x . #
k
sufficiently
K.
(1.67) WHITNEY LEMMA. in
G,
and
r ,r ,... 1
C > 1.
Suppose
There exist
E
is an open set of finite measure
x ,x o ,...
in
E
and positive numbers
such that:
c.
(a)
E = \J. Btr^x.),
(b)
the balls
B(r.Ay,x.)
(c)
B(Cr.,x.) n E c = 0, «3
(d) where
M
are disjoint,
J
M [ R A C Y 2 ( 1 + 2 Y ) ] Q ,
M < [8CY3(1+2Y)]Q.
#
The Heat Kernel on Stratified Groups
In this section we assume that
G
is a stratified group.
On such
groups there is a natural analogue of the Gaussian kernel on IR , which plays an important role in analysis. As in Section C, we let d. = 1, 3
j = l,...,v
and we define the sub-Laplacian
L -- ^ .
be those indices for which L
of
G
by
The heat operator associated to
L
is the differential operator
3, + L
_____
on
Xi
Gx ]R,
where
3, = 3/3t
is the coordinate vector field on IR. By
a celebrated theorem of Hormander [l], L That is, if u (resp.
is a distribution on G
(3^ + L)u)
(1.68)
is C
and
3 + L t
(resp.
G*1R)
on some open set ft, then
PROPOSITION.
There is a unique
are both hypoelliptic. such that
u
must be
C°° function
h
Lu C
on ft.
on_ G*(0, 0, h(x,t) = h f x " 1 ^ ) ,
and
jh(y,t)dy = 1
for all
t > 0. (iii)
h(-,s)*h(«,t) = h(«,s+t)
(iv)
h(rx,r2t) = r"Si(x,t)
Proof:
for_ all s,t > 0.
for all. x G G , t > 0, r > 0.
By a theorem of G. Hunt [l], the operator
unique family
{y }..n of probability measures on G X>
for all s,t > 0
L
determines a
such that y * y
u^U
and such that for every
uGCL(G), U
Moreover, the fact that
L
h
u
"0
t
is formally self-adjoint implies that
be the distribution on Gx (0,°°) defined by
= \
\ u(x)v(t)dyt(x)dt
S >X>
3,(u*y, ) = - (Lu)*y, . y, is
symmetric (that is, dy (x~ ) = dy (x)). Let
= \i
Xi
S
y, :
( U G C Q ( G ) , vG c£( (0,»))).
57
Then we have
, Lu®v> =
r (
Lu(x)v(t)dy, (x)dt =
j
O jG 0
Jo
t
(l.u*y, ) ( O ) v ( t ) d t = t
J
0 JG
Lu(x)v(t)dy, (x t
i
)dt
- f 3, (u*y. ) ( O ) v ( t ) d t J t t
(u*y, ) ( 0 ) 3 , v ( t ) d t = t
r (
t
J
I f u ( x ) 3 , v ( t ) d y , (x)dt t t 0 jG
= < h , u ® 3,v> . x> But this says that
h
is a distribution solution of
by the hypo ell ipti city of dy,(x) = h(x,t)dx,
3 + L,
h
(3 +L)h = 0, so
is C°° on G*(0,«>).
Clearly
so properties (ii) and (iii) follow from the corresponding
properties of y . As for property (iv), we observe that since
x>
i(uo 0
by Corollary 1.70.
This again follows from the hypoellipticity of
-
~
—
G x B\{ (0,0)}. 8.+ L.
~
r(x,t) = (rx,r t ) ,
then
immediately that for any of degree
-Q-d(l)-2k,
h
kGl
X h(x,t)
as a homogeneous group with dilations
and any multiindex
I,
-Q.
It follows
k I 3 X h t
is homogeneous
that is,
(1.1k) PROPOSITION. Since
G x JR
is homogeneous of degreee
t)
Proof.
#
\j
We observe that if we regard
that
on
G
#
Proof: ~
c"
i
On the other hand
Corollary,
—
is
e •> 0.
(1.72)
—
h
as
+
r W h ( x , t ) .
h(-,t)eS
h(«,t) = 0
for
for each t < 0,
vanishes to infinite order as
t > 0.
it follows from Corollary 1.72 t •> 0
whenever
x ^ 0.
More
60
precisely, for any su
Nel
and any multiindex
P| y |=l 1X^(7,8)1 < C I N s N
But then for any
x f 0
which shows that
h(•,t)G S.
Remark.
G
and
t > 0,
0 < s < 1.
by (1.73) we have
In view of this result, the operators
can be extended to act on for all
in
for
I,
!
S ,
and we have
H.f ->• f
H, in
defined by (I.69) S'
as
t -*• 0
f 6 S'.
(1.75) PROPOSITION. is a constant
C > 0
For each
kel
such that for all
and each multiindex
I
there
t > 0,
J| 9 Jx I h(x,t)|ax 0 we observe that by (1.73), |8Vh(x,t)| < C(/t + | x |
where
C = sup{ | a V h ( y , s ) | : /s" + |y| = l}. Therefore f t -MQ + d(l))/ 2 d x + c f
| x | -Q-d(l)- 2 k d x
61
Notes and References Sections A through E:
Some of this material is folklore, and some of
it is derived from Knapp and Stein [l] and Folland [l]; see also Goodman [l]. The Taylor inequalities (1.37) and (1.42) and the results in Section E are new. Section F: [2].
For the original theorems of Wiener and Whitney, see Stein
The variants presented here, which are valid on arbitrary spaces of
homogeneous type, are in Coifman and Weiss [l], [2]; see also Koranyi and Vagi [1]. Section G:
These results are due to Folland [l].
62
CHAPTER 2
Maximal Functions and Atoms
HP
Here we begin our development of the basic ideas of After reviewing some facts concerning maximal functions on
theory. iP,
p > 1,
we turn to the "grand maximal function" in terms of which we define Atoms are also defined, and it is proved that "atomic HP q,a
is contained in
H ",
H .
namely
HP.
We shall be working on a fixed homogeneous group that if
P
(j) is a function on
G
and
t > 0,
we set
G,
and we recall
cj> = t
o 6 , ;
this notation will be used throughout. If M f
feS1
and
t(y)| : I x ^ y ] < t, 0 < t < «>},
(2.2)
M°f(x) = s u p 0 < t < a > |f#4>t(x)|.
The same definitions will apply if such that example, if M.f < M.f
-
(x,t) -»• f*. (x)
f
and
0,
6k
(ID)
IIM(A)fll
Proof: of
llfll
F i r s t we prove ( a ) .
M^f.
1
fcL ,
Given
ER = Then for each that
1
< C'p(p-l) p - A
xGE
|x~ y| < t
a > 0,
and
We f i x and
{x : Mf(x) > a
we can pick
fGLP,
for a l l
p
1 < p < .
A > Q and w r i t e R > 0,
and
Mf
instead
let
| x | < R}.
y = y ( x ) , t = t ( x ) , and cf> e A^
|f*.(y)| > a.
Thus
We write the last integral as a sum of integrals over the regions and
2kt < | z""1^-1 < 2 k+1 t -~
tQa < f
(k = 0,1,2...).
Since
(j> 6 A. A
—1
|f(z)|dz + ro 2' k A f
"
JB(t
'y)
|f(z)|dz
B(2 k+1 t,y)
< (1 • r 2- k(X - Q) ) SU p 2- ( k " l ) Q f |f(z)|dz. J B(2kt,y) ° Hence if we set A = A ( X ) = 2Q(1 (which is finite since
A > Q),
(2 k t)- Q f J
+
^2"k(X-Q))
for some
B(2Kt,y)
k = k(x) we have
|f(z)|dz > a/A.
|z y| < t
we obtain
|f(z)|dz + I" 2"k:
< f
such
65
But
|x y| < t,
so
B(2 t,y) c B(y2
t,x), whence
|f(z)|dz > f (2 k t) Q = — 2 — |B(Y2k+1t,x)|.
f B( Y 2
k+1
A(2
t,x)
^
•p
In other words, for each r(x) = y2 k(x)+1 t(x))
xGE
there is a ball
such that, with
f
B(r(x),x)
A' = (2y)QA,
|f(z)|dz > j,
J
B(r(x),x)
By the Wiener lemma (1.66), we can choose a sequence that the balls cover
B(r(x.),x.)
are disjoint and the balls
{x.}
in
E
so
B(Uyr(x.),x.)
E . Then a E K | 0,
be as above and set set
g(x) = f(x)
if
A
= (Uy)QAf.
|f(x)| > a/2A-L
Given and
fG L P
(l < p < »)
g(x) = 0 otherwise.
66
Then
|f| < |g| + a/2A , whence
Mf < Mg + a/2, whence
{x : Mf(x) > a} c {x : Mg(x) and thus by part (a), if
A(a)
> a/2}
A(a) = |{x:Mf(x) > a}|,
< -~r ngiL = —- f
|f(z)|d
Therefore
(Mf(x) P dx = p f aP""1X(a)da
J
J
< P
0
J
aP
[2A a
|f(z)|dz]da
u
0
J |f|>a/2A
2 Al |f(z)|
aP""2da|f(z)|dz
= 2A p I I G
0
2An(2A1)P"1p t
= -^-i
|f(z)|Pdz,
from which the desired r e s u l t i s immediate.
(2.5)
COROLLARY.
|(j)(x)| < A(l+|x|)~
If_
is_ a_ measurable function on
for some A > 0 and
(a)
|{x:M f(x) > a } | < AC^IIfll /a
(b)
HlVLfll t(y) = f*ipt(x) where
i|;(z) = 6 S
is
Then there is a ball B(r,0) we have
B(l,x) C B(rt,0),
on which so
+ ~"v9 - r(l+ Y M ~ ^ B(l,x) From this it is clear that p > 0
%
M x6L
only when
p > 1.
However, for any
we can exhibit large classes of distributions whose grand maximal
functions are in
L . The problem is to ensure that the maximal functions
vanish sufficiently rapidly at infinity, and this can be accomplished by assuming some vanishing moment conditions. We proceed to the formal definitions. If
0 < p < 1
and
aG A, we shall say that
a > max{a' G A : a1 < Q(p If in addition
-l)}. (if
a
only the case
p = q = 1.)
supported (i)
is p-admissible if
A = TT, this means that
1 < q < °°, we shall call the ordered triplet
admissible if
Suppose
a
is p-admissible and
(p,q,a)
L^
function
is admissible. f
there is a ball
p < q.
A
a > [Q(p~ -l)].) (p,q,a)
(The latter condition excludes
(p,q,a)-atom
is a compactly
such that B
whose closure contains
supp(f)
such that
llfll < |B|
Recall that homogeneity.
A
is a set of real numbers generated by the exponents of
See the definition on p. 21.
72
(ii)
If
B
j
f(x)P(x)dx = 0
for all
PeP . a
is any ball satisfying condition (i), we shall say that
associated to
f
is
B.
Condition (ii) in the definition of atom is the essential one. (i) merely imposes a normalization on later; it implies that
fG L
f
Condition
whose utility will become apparent
and that
lf| p < Finally, if
p > 0
we set
N = min{N G IN : N > min{b G A : b > P Thus if
p > 1
we have
N
=0,
while if
p < 1,
the smallest element of
A
which is p-admissible.
N
= [a]+l
(if
A = U
where and
a
is
p < 1,
The point of all these definitions appears in the following theorem.
(2.9) constant
THEOREM.
If
(p,q,a)
C = C(p,q,a,N) < °°
is admissible and
such that
N > N , there is a _ p < C for all (p,q,a)-atoms
IIM/__xfII ^
j
p _
_
f. Proof:
Lef
f
be a
(p,q,a)-atom
associated to
B = B(r,x ). Since
all the relevant definitions are invariant under left translations, we may assume without loss of generality that shall estimate
M/ sf on
B
and
B
x
= 0.
Let
separately.
B = B(2y$ r,0).
We
73
On
B
we use the maximal theorem (2.k).
If
q > 1
we have
j^ ( N ) f(x) P dx < (JM (N) f(x) a}.
Then f o r a l l
a > 0,
|Eo n B| < min{|Ej Ej , |fi|} ^/a,
|fi|}
The last two quantities in curly brackets are equal when Thus, since (2.11)
a = |B|"
.
p < q = 1,
I M,N)f(x)Pdx =
pa P
|Ea n S|da
|B|~ 1/P
= C". Next, suppose and
G S
and II II /N \ < 1- Let b = m i n { b ' G A : b ' > Q(p~ -l)}
c = max{c' G A : c' < b } , and for each
x G G let P
polynomial of f at x of homogeneous degree
be the right Taylor
c. Then by Theorem 1,50 there
is a constant
C > 0,
independent of
|(y-1x)-P (y" 1 )! < C|y|b
(2.12)
X
Therefore, if
Since to
, such that whenever
a
yeB
and
Q b
—
xGB°,
is p-admissible we have
a > c,
and hence if
q'
is the conjugate
q, = |t" Q |f(y)[*((y-1x)/t)-Px/t(y-1/t)]dy|
|f(y)||y|bdy
This being true for a l l
x e B°
and a l l j G S with
11*11 ( N \ < 1 5
Proposition 2.8 we have
J M ( N ) f(x) P dx < C
But
b > Q(p" -1),
(2.13)
(-Q-b)p < -Q, and hence
M (N) f(x) P dx < G|B| ( b p / Q ) " 1 + P |B| X - ( Q + b ) P / Q = C .
| B
BC so
|x| > 2y$ |y| ,
C
Combining (2.13) with (2.10) or (2.11), we are done.
#
75
After these preliminaries we now make the following definitions. If
HP
0 < p < °°, we define the Hardy space
to be
HP = {fcSf : M(N )f6LP}. P If H
(p>q.5a)
P
is an admissible triplet, we define the atomic Hardy space 00
to be the set of all tempered distributions of the form *
q,a
(the sum converging in the topology of (p,q,a)-atom,
X. > 0,
and
Sf)
where each
f.
E-A.f. 111 is a
z!°X? < °°.
Several remarks are in order concerning these definitions. (1)
If
p > 1
then
(2)
The condition
HP = LP,
and
H1 c L1,
by Theorems 2.U and
2.7. II4>II / v < 1 in the definition of M/ sf is P P essentially the weakest one which allows the arguments in the proof of Theorem 2.9 to be carried out. 1,
However, the )< 1
W/w
the condition
are
P
II^IJ,
s < 1 means that |(x)| < (l+|x|)~ , and one can P replace the number Q+l by any X > Q as in Theorem 2,k. We shall not pursue here the point of precise decay conditions on that in some problems the optimal conditions on
0 = N . Moreover, it will follow p
H? * = H P
for all
(p 5 q 5 a)
is admissible.
that one needs some control over the functions grand maximal function, and the smaller
(k)
If
p
called an atomic decomposition of We now define topologies, on p > 1 and
we use the P
p q,a
L
H
= H
N < N . The moral is
€ S
which enter into the
is, the more control one needs.
f G H P , the representation q, a
combination of atoms is far from unique.
p
even when
Bearing this in mind, one sees from the
preceding remark that the theory breaks down when
P
N > N
On the other hand, we shall also show in Chapter 3 that
whenever
if
it follows from Theorems
f = E~X.f. of _L i i
f
as a linear
Any such representation will be
f. H
norm on
and
H
for p < 1. (Of course, q,a H .) Namely, we define the quasi-norms
by
p P (f) = inf{EA P : ZX.f. q, a l ii into
is an atomic decomposition of
(p,q,a)-atoms}.
f
77
(f,g) -*• p P (f-g) q,a respectively, -which make them into topological
It is easily verified that the maps HP
are metrics on
and
H
(f,g) -> pP(f-g)
q,a vector spaces (not locally convex, unless P
nontrivial point is that
p (f) = 0 q_,a
p = l).
implies
and
The only slightly
f = 0,
but this follows
from the next proposition. (2.15)
PROPOSITION.
If
(p,q,a)
HP c HP c Sf, q,a
is admissible then
the inclusions being continuous. Proof:
Let
we have (since
C = C(p,q,a,N ) be as in Theorem 2.9. p p < l)
pP(f) = |[M (N ) (EA.f.)] P < ZXP |[M (N
Hence -> f | for a l l #
Jn
J
and
Remark:
The same proof shows that if
given the obvious topology, the inclusion all
if
H?__v H^\
c
is defined, by (2,lU) and 5'
is continuous, for
N6I. HP
is complete.
(2.16)
PROPOSITION.
Proof:
We need only consider
{f.}
is a sequence in
converges in
HP
and it suffices to show that EpP(f.) < «>, the series
such that
Ef.
H . However, the partial sums of this series are Cauchy in
H , hence in
S1
by Proposition 2.15, so the series
to a distribution
f.
p
P
p (f) < Ep (f.) < «
so the series converges in
If
f
converges in
and
P P
fGH .
Similarly,
H . #
We conclude with two more remarks about atomic (2.17)
Ef. 3
We have
p P
hence
p < 1,
is a
(p,q,a)-atom
then
p
HP
spaces.
(f) may be strictly less
than one, since there may be more "efficient" atomic decompositions of than
f
such that write
itself.
p (f) > 1-e. q,a
f = EA.f.
would obtain for all
However, for any
P
pP
with
e > 0
there exist
If not, then for any
EA? < l-(e/2).
(f) < (l-(e/2))2,
j, which would imply
(p,q,a)-atom
Decomposing each
and by induction,
f = 0.
(p,q,a)-atoms
f. pP
f
f f
we could
similarly, we (f) < (l-
79
(2.18)
If
N f = E X.f.
is a finite linear combination of (p,q,a)-atoms,
then
j|fp < SJ jxPlfJ* < zJxP,
hence j| j|f |* hence
___________
independent of
#
f, i, and a,
—
_____
such that
Proof:
~~™~~~""~
Let
u , ...,TT J_
m
(m = dim P ) be an orthonormal basis for
with respect to the norm (3.5).
Then by the properties of
X
J
J
1
X
"
x
J
a
£.,
1 = ( L ) " 1 [ h . ( y ) | 2 C . ( y ) d y > |B(2r x ) f 1 f J
P
a
B(r/1+Yx)
U.(y)|2dy J
B(IAY,O) where
TT.(Z) = 7T.(x(r.z)). j
j
i
Since
dim P
are equivalent), there exists C > 0 1 sup,T|
w
< °° (so that all norms on
such that for all
TT ., J
we obtain
-
1 J. h/ »
PGP, a
|p(z)|2dz)1/2.
, , - l Y ^ z ) ! < C_([
|1| (x) = (r /t) Q f*$ J-
where
O
1
( x ) - (P.C.)*, (x) X .
1
$(z) = 4>( (r. /t)z)c(x(i\z~ )). If
|x. x(r.z
1
U
$(z) # 0 we must have
)| < 2r., which implies that |z|
N.
——_
87
Proof:
Suppose
(T^ri,xi) Case I :
eS,
llIL
v < 1,
and
t
> 0.
n Q C. t
< r.. — i
We w r i t e
b.*cj), ( x ) = it
f * $ , (w) - ( P . C. )*. ( x ) t lit
-1
If
zG supp $
and since
then
|x7 w(tz~ )| < 2r.,
whence
|x^ x| > ^r^^ > . -1
-1 X. X
-1 X. X
i X. X
W
x. x
i X.
2yr.
-1 - 21 Therefore, if
Pick
|l| < N,
t '•
by Lemma 3-7 we have
-1 I
K. X
_ - 1
where
since
t/r. < 1.
Also, if
y e supp b.
and
x^B.
we have
|y """x| > cjx^xl, so by Lemma 3.8,
< C,(r./|xT 1 x|) (N+1)(tl+l) Mf(w) +V t-« 1 2 ~ 3 1
since
t < r., Case II:
b < N,
and
r. < |xT x|.
t > r..
Let
a' = a
if
a < N
.,x.)
and
a' = min{a"GA : a" < H}
1
if
a > IT; thus
we write at
z
a' = max{a" G A : a" < b}
(yz) = P (y)+R (y) where z z f
of homogeneous degree
a .
P
z
and
N > [a']+l. For any
zGG
is the right Taylor polynomial of
By Theorem 1.50,
R
satisfies z
(3.3A)
|YXR (y)| < C 7 |y| b - d ( l ) |z|- Q - b Z
Also, if (3.15)
d(l) > b
—
then
|Y\(y)|
2Yj3M|y|).
I
—
YIRz(y) = Y ^ y z ) , (
(
C fl | Z |- Q - d(l)
)
(
so
)
(|l| < N,
d(l) > b,
| Z | > 2y|y|).
Now, by the construction of b.*cj>, (x) = t 1
Q
t
b.
we have ((yxT1)/t)dy
b.(y) R n (x.xj/t
J 1
X
JPi(y)ci(y)R
((yxi1)/t)dy,
_±
where (r.z)w
x
= R
If
z G supp $ 9
(3.16)
we have, as "before,
|z| < C r./t,
which now implies that
and 2
Y
3
(r.z)w"" x. |-^ ±
N
"bounded by a constant. |j| < N
, x i lx ,
T.
By Lemma 3-7, the derivatives of
(3.16), for
~)?.(w(r z" 1 )).
£.(w(r.z
)) with respect to
we have
-' -""^
(r
iz)w
X
i,b-d(l) ,Xi X -Q-b
x. x 10
- c i r tj I t I
C
/jtxQ .
10
are
Therefore, by the estimates (3.lU), (3.15), and
r
C
z
I
J
\
r
i
-i
xQ+d(l) /
t
90
since
|x. x| > r..
Therefore, since
supp $ c B(C ,0),
we have
and hence
K^/t^f*^ (w)| < ^^(r./lx On the other hand, by (3.lJ+) and Lemma 3.8,
X
-1 -1 i ,b ,Xi X
Combining these last two estimates, we are done.
and
(3.17)
THEOREM.
f 6H
There is a constant
.
Suppose
0 < p < 1, A^,
N = N , p
a
independent of
is p-admissible f, i, and
a,
such
that
Mb.(x) P dx < A q f Mf(x) P dx. g Moreover, the series
Eb.
converges in
i H , and _if_ L
is as in (3.U),
P fM(Eb.)(x) dx < LA f Mf(x)Pdx. 1 ^ in 'a
J Proof:
By Lemmas 3.12 and 3.13, we have
< A P f Mf(x)Pdx + A^aPf (r /|x^-x|) p((iH)) dx "
3
\
BC. '
91
where
b > Q(p~ - l ) .
Hence
p(Q+b) > Q, so
BC 1
Hence, since
B. c ft9 fMb.(x)Pdx < C j [
< 2C
Mf(x)Pdx + a P | B . | ] B.
f Mf(x) P dx. i
This proves the first assertion, and since
H
is complete, the second
follows from the estimate
Z. |Mb.(x)Pdx < 2C Z. I Mf(x) P dx < 2LC I Mf(x) P dx.
Remark: Mf(=M/ Eb.
vf)eL
If we replace the assumptions
N = N , p
f6HP
#
by N > N , - p
, we obtain the same conclusions, except that the series
converges in the topology defined by the maximal operator (3.18)
THEOREM.
Suppose
M• >. •
N > 0, a G A , and f e L 1 . Then the series
Eb.
converges in L , and there is a constant
and
a,
A^, independent of
such that
E|bi(x)|dx < A 6 j|f(x)|dx.
Proof: By Lemma 3.8,
i
+A a|B |
f, i,
92
Hence by (3.M and the maximal theorem (2.U),
S ( M1
N , 0 < p < I)
"good part" (3.19) A7,
and for
fGS1
such that
f S L . We now investigate the
g = f-Zb.. LEMMA.
independent of
Suppose f
and
Zb. a,
converges in
S1.
such that for all
There is a constant
x G G,
Mg(x) < A7aZ.( r-i ) ^ D + Mf(x) X Ax), " T X Ix xl+r n where
b
is as in Lemma 3.13.
Proof:
If
x^Q,, by Lemma 3.13 we have Mg(x) < Mf(x) + Z,Mb,(x)
Mf(x) + Z A a(r /Ix^xD^^
since that
|x. xl > r.. 1
1
'
x6B. , and let K
On the other hand, if
xGft
let us choose
k
such
1
J = {i:B. n B. f 0}. Then IK
card(j) < L, —
and as
93
above we have
^
2
Q+b
Hence it suffices to estimate the maximal function of As in the proof of Lemma 3.13, we fix Suppose
(f)GS,
IIC>II /N\ < 1 5
and
g+E. , b. = f-E
b..
wGB(T~r ,x,) n Q,C. t > 0.
If
t < r , we write
where -1
We observe that
r\ = 0
on
B ,
so if
z G supp $
K.
where
C
> 0,
and hence T 33rrkk//t) | < Y(|y| + Iw^xl/t) < Y(|y|+T
Therefore, by Lemma 3.T 9 for
111 < N
we have
and
y = z((w
x)/t),
K
C
o
< C.a
r. ,
let
x)| =
Also, by Lemma 3.13»
K.
*(z) = ^(zCCw^xJ/t)).
by Proposition 1.U6 we have
xQ+b
t < r . ~
If
k
II*II, ^ < C ,
Since
I w ^ x j / t < T.r / t
T r.
i
since
w^^.
Hence
< (C6+l)r.
N , a is p-admissible, - P Mg e L , and there is a_ constant A n , independent of f
_______
___
such that
_______________
Q
JMg(x)dx < Agcx1"1? JMf(x) P dx. (ii)
Suppose
N > 0,
aeA,
__ constant A ,. independent of Proof:
(3.21)
f
and
f e L . Then
and
a,
such that
gGL°°,
II g I! < A a.
(i) By Lemma 3.19,
JMg(x)dx < A1al± f ( — ^ 'Xi x ' + r i
Let C =
) Q+b dx+ f Mf(x)dx. nc
and there is
Then the first term on the right of (3.21) is bounded by A^CctE.r; = A^CaE |B. | < LAvCa M = f
i
i
(
i
i
-
C'aM.
f
Hence
|Mg(x)dx < C f a | n | + [ Mf(x)dx < C'a-cT P [ MfU^dx + a 1 ^ f Mf(x) P dx < C ' a 1 ^ JMf(x)Pdx. (ii)
If
feL
then
g
and t h e
1
Thus by Lemma 3.8, for for almost every
1
xeft
x6fl°
11
we have
we have
b.'s
are functions,
and
1 1
QC
|g(x)| < LA^a, while by Theorem 2.6,
|g(x)| = |f(x)| < CMf(x) < Ca.
#
This completes our discussion of the Calderdn-Zygmund decomposition. As an immediate corollary, we obtain the following important result. (3.22)
COROLLARY.
Proof:
If
decomposition of
If
0 < p < 1,
fGH
and
a > 0,
f
of degree
a
let
HP n L1
is dense in
f = g a + Eb?
and height
a
HP.
be a Calder6n-Zygmund
associated to
Mf = M/
xf, P
were
a
is p-admissible.
By Theorem 3.1T5
p P (E.b a ) < C f 1 X
so
pP(E.ba) •> 0
as
"
a -> ~.
by Theorems 3.20 and 2.7.
#
Mf(x) P dx,
/
• {x:Mf(x)>a} Hence
g a -> f
in
HP
as
a -»- °°, but
g^L1
97
Remark: "good parts" to
M, vf
N > N and JVLT>>feLP - p \N)
The same proof shows that if g
of the Calderon-Zygmund decompositions of
are in
L
f
then the
associated
and [M(N)(f-ga)(x)]Pdx + 0
B.
as
a -• co.
The Atomic Decomposition
We now aim to prove that Hardy spaces coincide with atomic Hardy spaces. Suppose
0 < p < 1,
N > N , a
is p-admissible, and
such that
f
k
~D
M/ sfeL . For each
Zygmund decomposition of
f
kGE,
of degree
let a
is a distribution k
f = g + E.b.
and height
2
be a Calderonassociated to
M/-,xf. We shall label all the ingredients in this construction as in Section A, but with superscript
k's:
for example,
fik = {x : M(fj)f(x) > 2 k } ( We now need two more definitions. of on
k P., P a
we define
-bk = (f-Pk)?k,
B k = B(r k ,x k ).
First, by analogy with the definition
k+1 P.. to be the orthogonal projection of
k+1 k (f-P. )c
with respect to the norm
IIPH2= (J ? k+1 )- 1 ||F(x)| 2 C k+1 (x)dx.
(3.23) Tc+1
That is, P..
is the unique element of
P
Second, we define Bk
= B(2r k ,x k ).
such that for all
Qe?a>
(3.2*0 B.
LEMMA.
c B(T2r.,x.).
for which
B.
+
Proof:
If
I"]
B.
("b)
For each where
L
j
r^ +1 < Uyr^ and
there are at most
L
is_ as_ in. (3.M.
AV
n B. + 0 we have
|(xJrV; +1 | dist(x. ,{Q ) ) > T r. .
Thus _ k+l _. ,f k+l / o 3ON k+l l8y 3 r. = T 2 r. < dist(x. ,(
so that
From this and (3.25) it follows that
values of
i
99
so that if
~k+l y 6 B. , J
This proves (a), and (b) follows from (a) and (3.^). (3.26) k,
LEMMA.
There is ji constant
A ~,
#
independent of
i, j , and
such that 1, v 1 . o k+l (y)| < A2 Proof:
The argument is essentially the same as the proof of Lemma 3.8,
and we indicate only the necessary modifications. orthonormal "basis for show that for some
P a
C > 0
If
IT , ...,TT
is an
with respect to the norm (3.23), it suffices to independent of
But by Lemma 3.8 and its proof (with
IP^ty)! < C2 k+1 ,
i, j , k, and £,
P.,C.
l^y)! < C
replaced by
for
Hence :+lx-l fpk+1
r k r k+li
k+1
so we need to show that
r1 f f t ^ 1 ! < c2k+1.
T,
P.
11
k+1
, C.
)>
100
Now
Mr where
WG B(T r k + 1 , x k + 1 ) n (^ k + 1 ) C -j
J
./ x
/ k+lxQ/f k+lx-lr
so it suffices to show that i
and
j
k k+ln, / k+1 -lvv
) l7^-^
$(z) = (r. P ( k .
those values of
and
«]
li$ll/ % < C.
J(w(r. z )),
However, we need only consider
A ^k+1 k B. n B. ^ 0,
such that
k k+1 C.C. vanishes identically, and for these values of 3.7 and 3.2U yield the desired result. (3.27)
LEMMA.
For every
Proof: C
k+1
For each
(x) $ 0.
x
x tthe series
and
j, Lemmas
) = 0, where the
S'.
j, P
and by Lemma 3.2U there are at most Thus for each
k+1 k+1 E. (E .P . \ . i J IJ J
there are at most
Moreover, for each
i
#
k6E,
series converges pointwise and in
since otherwise
k+1
L
L
values of
is zero unless
values of
k+1 k+1 E.E.P.. (x)c. (x) i 3 ij
J
i
j B
for which k
n B k + 1 f 0,
for which this happens.
is actually a finite sum,
and by Lemma 3.26, i k+1 k+1 L . L . \r . , \X. ) C, .
i V - f
-> 0
f in
HP
as
k -> + °° , while by Theorem
k ->--«>. Therefore
(convergence in
Now, using Lemma 3.27 together with the equation
„
Lk+1=
E . C .D.
k+1
X i D . =
, k+1 b .
we have
JJ
=
(3.29)
1J1J0
E.h.
where all the series converge in
5'
be the
as in the preceding lemmas, where
uniformly as
-g )
f = g +E.b.
and
h^ = (f-P^)c^- Z.[(f-P^+1
S1).
102
From this formula it is evident that ihk(x)P(x)dx = 0 Moreover, since
for all
k+1 E.£. = x
P k r k + rks
But
|f(x)| < C J /
\f(x) < C 2 P 2.6, so "by Lemmas 3.8 and 3.26,
P
k+1
r k + 1 +Z
for almost every
llh B
i cx, 1 (2C 1 + A 2 + 2 L A 2 + 2 L A 1 Q ) 2 k
k+1 P.. = 0 k
Lastly, since
Lemma 3.2U that
h.
unless
a.
is a
*
k+1
rk+1
x^^
by Theorem
C^.
~k ^k+1 B. n B. f 0, it follows from (3.29) and k k
is supported in
x!f = C 2 2 k T^ / p |Bj| 1 / p we see that
P
J = C, IIMfll p .
n
Therefore, if we set
and a^ = h^/xj,
(p,°°,a)-atom,
oo
Bf^r^xJ.
and that
p a p " 1 | { x : Mf(x) > a } | d a
103
k k E E.X.a. K. i 1 1
Thus the series decomposition of
converges in
D Ir and defines an atomic °° 5 a
f.
It remains to remove the restriction that arbitrary element of in and
HP n L1
fG L . If
f
is an
H , by Corollary 3.22 we can find a sequence pP(f_ ) < (3/2)p P (f), p P (f ) < 2~ m p P (f) 1 ~ m — f = Z.A1f1 be the atomic decomposition of m i m m
such that
f = z!°f . Let lm
constructed above.
Then
f = E E.X f m I m m
{f } m for m > 1, f m
is an atomic decomposition of
f,
and
(3.30)
THEOREM.
(i)
If
(p,q,a)
(ii)
If_
fGS1
N > N ,
Suppose
0 < p < 1.
i s admissible then then
f G HP
HP = HP
i f and o n l y i f
pP ^ pP
and M, x f G l ?
.
f o r some
p P ( f ) * IIM ( N ) fll P .
and
Proof:
(i)
(p,r,a)-atom
I t i s e a s i l y checked t h a t i f
is also a
(p,q,a)-atom,j
l < q < r < ° °
emu. hence ncii^c and
F H
r 5a
r~ H M c
then every . Therefore
Q_ 5 a
by Proposition 2.15 and Theorem 3.28, c HP c HP5 HP c HP °°,a q,a where the inclusions are continuous. (ii)
feHP
If
then
M, s f e L P
for all
Conversely, the proof of Theorem 3.28, with
N
N > N
since
replaced by
M/ vf < M/ N
(cf. the
remarks following Theorem 3.IT and Corollary 3.22), shows that if then
(i),
f G HP °°,a
fGH
P
for any p-admissible
and
P
p (f) * "M (N) fll£.
a,
#
and
x
pP (f) < CllM/-Txf IIP. °°,a vNj p
M,NvfGLP Thus by
Theorem 3.30 is the rock on which our subsequent investigations wi be founded, and we shall frequently use it without referring to it explicitly. dense in
As a first application, we prove that smooth functions are
H .
(3.31) and
C > 0
LEMMA.
C > 0
$GS.
such that for all
Proof: and
Suppose
For_ anv_ N 6 l
there exist
fG S',
We first observe that for any
N6 JT
there exist
feS'
sup
Nf > N
such that for all cj),^G5,
(This follows from Proposition 1.1*9 and its proof.) if
N1 > N
From this we see that
and ,t(ieS,
£ ,t>o
! f ** e **J *
sup
£ 0
M ( K 1 ) ( ( f - g ) * + e ) + lim
Hence by the maximal theeorem (2.U), for any
a > 0,
|{x : lim sup £ _ > ( ) M (Nt) (f*cj) e -f)(x) > a } | < C'llf-gl^/a < C'6/a.
Since
6
is arbitrary, we are done.
#
in
and the dominated convergence
M/ ,>>(f*(j) -f)
This is certainly true if
has compact
106
oo
Remark: and
C
fP = 0
oo
p
is not a subset of
for all
PGP
constant multiple of a
where
H a
(p,°°,a)-atom,
for
p < 1.
However, if
is p-admissible, hence
f
fG C
will be a
fGHP.
We conclude this section with some comments about vector-valued functions. X-valued
If
X
is a Banach space, we can consider the space
tempered distributions on
linear maps from
S
into
X.
G,
Sj, of
i.e., the space of continuous
The whole of
HP
theory up to this point
can be developed in this context, merely by replacing absolute values by X-norms
in appropriate places.* For example, if M f(x) = sup y
|x y| X, a
we set
PT(X) = AUJTTTT. Then for any
Q G P , a
L(Q) =
QP dy. I -I i
Thus the construction
of the
polynomials
However the reader should take care because not all results in H^ theory are extendable mutatis mutandis to the case of Banach space-valued functions. Some theorems require the L 2 boundedness of appropriate operators, and those may be essentially restricted to the case when the Banach space is a Hilbert space. See also the remarks preceeding theorem 6.20 below.
107
P.,
etc.,
in the Calderon-Zygmund and atomic decompositions can be carried
out in the Banach space setting.
C.
Interpolation Theorems
In this section we prove two results on interpolation of the real method.
We recall that if
X
and
V
H
spaces by
are quasi-normed linear spaces
embedded in some topological vector space, the Peetre K-functional on
K+V
is defined by
K(t,f) = inf{llgllx + tllhlly : g e X , h e V, f = g+h}
and the interpolation space
[X^L
(t > 0 ) ,
( O < 0 < 1 , 0 < q < « )
is defined by
( t " 9 K ( t , f ) ) q d t / t ] 1 / q < 00}.
We refer the reader to Bergh and Lofstrom [l] for a detailed exposition of these matters.
(We remark that to fit
setting, we use the quasi-norm
(3.3*0
THEOREM.
q" 1 = (l_0)p~ 1 + e r " 1 ,
Proof: [ ,] 8,q that
If
(p )
r = °°.
[H p ,H r ] f i
into this
p .)
0 < 0 < 1,
and
= Hq.
By the reiteration theorem for the interpolation functor
We may also assume that Thus we suppose that
r
boundedly, so it maps
[LP,L°°]Q = L q ,
and
p < 1,
0 < p < 1,
First, the subadditive operator oo
b,q
(p < l)
rather than
0 < p < r < °°,
then
spaces
(cf. Bergh and Lofstrom [l], Theorem 3.11-5), it suffices to assume
well known.
L
H
M,
p o o
P ~ q
O < 0 < 1 ,
maps
H
to
and L
q = p/(l-0). and
L
to
-Q oo
LH ,L J
N >N ,
N
since otherwise the result is
f,q
to
[L ,L ]
8,q
whence i t follows that
boundedly.
[HP,L°°L
o ,q_
But c
Hq.
108
To prove the reverse inclusion, by Corollary 3.22 it suffices to showthat
H q n L 1 c [HP,L°°]
. If f G H q n L 1 , let F be the nonincreasing
rearrangement of Mf = M,
\f on (0,«>), and for t > 0 let f = g + £b. p be a Calderdn-Zygmund decompositon of f of degree a and height a = F(t P ) associated to Mf, where
a
is p-admissible.
Then by Theorem 3.17»
IIM(rb*)llp < c f Mf(x) p dx = c f F(s) p ds. 1 P J ~ Mf(x)>a Jo Therefore, making the change of variable
t P -> t
and then using Hardy's
inequality (cf. Stein [2], p. 272), ,00
(3.35)
,00
f
t
P
(t~9IIM(£b.)ll ) q d t / t < C t " 9 q ( x p Jo " Jo Jo
= Cp"1 r J
F(s)Pds)q/pdt/t
J
o
o
= Cp-V q/P [V 6 q / p (tF(t) P ) q / p dt/t Jo
= C
[ F(t) q dt
= c'IIMfllq. q.
Moreover, by Theorem 3.20, (3.36)
["(t1-9^*!! )4dt/t < C rt ( l - 6 ) < 1 F(t p ) < 1 dt/t 0
J
0
"1 r
= Cp
I t^ 0
= C'llMfil'1.
^/H/^F(t)Vddt/t =
Cp
_1 J
0
109
But c l e a r l y +tllg t !l oo ,
K ( t , f ) < IIM(Zb^)ll so "by adding (3.35) and (3.36) i f to them i f
q > 1,
or applying Minkowski's i n e q u a l i t y
we have [
so that
q 0, let f = g+Zb.
a is p-admissible.
a and height
Then each
in the notation of Section A ) ,
X. = lib. II |B. p 1 / P ) - 1 5
T
to_ the space of measurable functions such that
Zygmund decomposition of f of degree M/p.\f9
and suppose
llTfllP < CpP(f)
T is weak type Proof:
L
0 0,
let us define the tangential
by
if and only if
AeL
P
,
provided
A > Q/p.
In defining the nontangential maximal function
replace the cone for any
eS9
{(y,t) : |x~ y| < t < °°} by
a > 0 without changing the p > 1,
L
M,f
we could
{(y,t) : |x~ y| < at < °°}
properties.
it follows from Theorems 2.k and 2.7 that if
G S
and
U = 1 then (U.3)
llM^fll ^ llM^fll ~ IIM, T vfll * P 4> P (N ) p
for all
fGHP.
If
G = ]Rn,
this result remains true for all
p > 0.
The crux of the matter is the following result, which shows how any tyeS can be expressed in terms of (k.k)
PROPOSITION.
such that any tyG 5
B*^I(N)
0
can be written as
Moreover, for any m , N 6 l such that
If
and its dilates:
there exists
0 ^ 2 - ^ 1 * 1 1 (H).
C
> 0,
independent of
\\>9
116
Proof:
Since
Taking Fourier transforms, we see that (U.5) is equivalent to
$(0) =
|C| < e ,
U =
1,
there exists
e > 0
k
and hence
| $ ( e 2 ~ £ ) | > 1/2
—
for
such t h a t k
\$\ < 2 .
—
partition of unity on 3R supp C. J
c
then (i»-.6) obviously holds. (k) II\|J "fivrV
reader.
and
Let
supp C
for
{r }" be a K (J
~
such that
B(2 J ,0)\B(2 J ~ 2 ,0),
|U)| > 1 / 2
c B(l,0),
II (3/3£;)Ic .11 < C2"' 5 ' 1 '. J °° -
The estimates for
11$
If we define
and nence
"(ro}>
for
follow easily from this construction; details are left to the
#
We do not know if this proposition remains true for an arbitrary homogeneous group non-Abelian.
G;
certainly the above argument is worthless if
is
However, we shall now show that a variant of this proposition
is true for general
G
when an additional restriction is imposed on
and from this we shall deduce the relations (k.3) for such
Definition: such that
G
= 1
's.
a commutative approximate identity is a function and
I
*, = ,*cj) S t T> S
for all
,
GS
s,t > 0.
We postpone until Section B a discussion of the problem of finding commutative approximate identities.
For the present, we assume that we have
such a function in hand and proceed to work with it.
If
denote by
with itself.
the N-fold convolution product of
N
H
observe that (^)* = U * \ and J/ = ( f^
N
$
eS,
we shall We
117
(k.7)
LEMMA.
Suppose
0 < J < N < «» and and
5
a)
then
3^*'
N+1
N S
' = 0
SS
Proof:
and
rh. = j.
1—
Since
J
3
the commutativity of
XI
is a limit of difference quotients of (j) *(3^ ) = (9g(f)s)*(J)
cj> implies that
!
for an
s,
y J-
In particular, if N > 1,
(..8)
a s ,f^ - ^ f * O A ) < ^ = (.+i)*«.O8*B, T
which proves the lemma for
s
T
sTs
s
j = 1.
We now proceed by induction on
8 U * * ) = zhbA * 3 S s Ys
Expanding
3 0
is_ a_ commutative approximate identity.
such that;
118
|(l+|y|)N|e(s)(y)|dy < CsNil^ll(3N+3), where
(ID) N
C
depends only on
and . Proof:
Fix
ceC°°([O,l])
0 < c(s) < sN/N! Also, let
w
(s)
for
= a/
N+1
1/2 < s < 1, '
and we claim that these (a)
such that
N+1
'
s)
0's
and
?(s) = sN/N! 3^(l) = 0
for
for
0 < s < 1/2,
0 < j < N+l.
he as in Lemma k.l. We set
have the required properties,
Consider the integral
'0 We integrate by parts the fact that
N+l times.
Because of the properties of
1 *(N+2) 3d *i|> remains bounded as
s -> 0
C
(by Lemma k.'J and
Proposition 1.58), there are no boundary terms in the first
N
integrations
by parts, and we obtain I = -(
S
But
jcj>*(N+2) =
S-U
(Uf+2 = 1,
JQ
S
S
so by Proposition 1.U9,
* * ( N + 2 ) » * I S =Q
T h u s b y Lemma ^ . 7 ,
f1
[\*e(s)ds. S
and
119
(b)
Observe t h a t
| 8 N + 1 c ( s ) | < CsN
and that
8 N + 1 ^(s) = 0
since
for
s < 1/2.
Hence we
need only show that
But this follows from Proposition 1.55(U.10) For any M,
THEOREM.
NGl
Suppose
there exists
xf(x) < CT f(x), Proof:
Suppose
as in Theorem U.9-
#
is a commutative approximate identity. C > 0
where
T
such that for all
f e S'
II^IL
, < 1.
UlM+Jj -
Then for any
Write
\|> =
x,yGG,
*^st* t
st+
(yz"1)||0(s)(z/t)|t~Qdzds
< f1 [ T " f ( x )([ x "Vst 1
- JJoo JJGG * N ,
x
f 0
J
x€ G,
is defined by (k.2).
^ G 5 and
f*
and
- N , i x v G
%
- l i
NNI
f 1 * 0 ( ) d s
JQ s
120
But if
|x~ y| < t,
then
-1 ^
| + 1 < y(l+ |w|) + l < 2 Y (1+ | W | ) .
Therefore, by Theorem k.99
M.f(x) < (2 Y )Vf(x) f f s-N(l+ |v|)N|e(s)(v)|dvds
from which the desired result is immediate. # (k. 11) feS', C,
and
COROLLARY.
Suppose
0 < p < °°.
If
independent
Proof:
of
_
f,
is_ a_ commutative approximate identity,
M.f 6 L P
—
^
pP(f)
such t h a t
f G HP,
then
< CllM.fll P .
-
|B(2 Y t,x)r 1 f J
|f*c|),(v)|raw
B(t/C6,y)
> (2 Y C 6 )"V r f*(x) r . This establishes the claim ana thus completes the proof of the theorem.
#
128
Combining this with Corollary 4.11, ve obtain the final result: (4.17) If
feS
1
COROLLARY.
and. 0 < p < °°,
(a) M°fGL P , Moreover
Suppose
is a commutative approximate identity.
the following are equivalent:
(b) M f 6 L p ,
(c) M f G L P for all i(i6S,
(d) f G H P .
pP(f) ^ llM^fll . ^ p B.
Construction of Commutative Approximate Identities
On a general homogeneous group the existence of commutative approximate identities is, as far as we know, an open question. group, one example comes immediately to mind.
Namely, let
Propositions
1.68
and 1.7^
we h a v e
eS,
h
be the heat
(f)(x) = h(x,l).
kernel discussed in Chapter 1, Section G and let
f
However, on a stratified
j = 1,
J
and
j (x) = t
Then by h(x,t
2
),
hence = h ( x , t 2 + s 2 ) = * .
4> * 0. I -
are formally skew-adjoint.)
In
is also a positive operator for all T T € G .
It is easy to construct examples of positive R-operators on any graded group.
For instance, choose
i = l,...,n and set
M G I
such that
M/kd. is an integer for
(which is possible since the exponents
n M/di L = EX. . Then
condition, suppose
TTGG,
L veS
d.
is positive by (1+.20). ,
and
&T\(L)V
= 0.
are all rational), To verify the Rockland
If
( , )
and
II II
denote the scalar product and norm on X , we have M/2d. 0 = (d7r(L)v,v) = Elldir(X ) vll. M/2d. 1 dir(X. ) v = 0
Hence
f o r a l l i , so M/2d.
0 = (d-n(X±) If
X
v , v ) = illdirUJ
M/Ud. o 1 vll.
M/Ud. is even, the same argument shows that
M/Ud.
is odd, we have
(M/Ud )+l 1 dir(X. ) v = 0,
d7r(X. )
v = 0. If
and hence as before,
i
dff(X.) d7r(X.)v = 0
v = 0.
Continuing inductively, we eventually obtain
for all i, which implies that either
v = 0
or
IT is the
trivial representation. For the remainder of this discussion we fix a positive R-operator which is homogeneous of degree
D.
We make
Gx B
L
into a graded group by
131
means of the dilations 6 (x,t) = (rx,rDt).
Thus if
3
denotes the coordinate vector field on 1R, regarded as a
differential operator on (U.21)
LEMMA.
Proof:
(GxB)"
TT G G
and
L+8
Gx]R,
9,
is homogeneous of degree
is an R-operator on
D.
Gx]R.
is easily seen to be isomorphic to
X G B , the corresponding representation
Gx]R: namely, if
p = p
-, of
Gx]Ris
TT,A
given by veS
,
p(x,t) = v j- 0 ,
and
e
TT(X) on t h e H i l b e r t space d p ( L + 9 )v = 0 ,
TT
X ,
and
S =
S .
If
we have
%
0 = In view of ( U . 2 0 ) ,
(dp(L+3t)v,v) =
(dTT(L)v,v)+ iAllvll 2 .
(dTr(L)v,v) > 0 ,
so by t a k i n g r e a l and i m a g i n a r y p a r t s
we o b t a i n (dTr(L)v,v) = This implies, first, that u •* (dTT(L)u,u) Thus
p
X = 0,
Xllvll2 =
0.
and second, since the quadratic form
is nonnegative, that
dTr(L)v = 0,
is the trivial representation of
Gx]R.
whence
TT is trivial.
#
We propose to construct a commutative approximate identity out of a fundamental solution for
L + 9 . To begin with, by (U.19), x> o
(regarded as a densely defined operator on operator for any positive integer [l],
L |c
m.
J.m|CL U
L ) is a positive Hermitian
By a theorem of Nelson and Stinespring
is essentially self-adjoint.
(Nelson and Stinespring state
132
their theorem for elliptic operators, but the proof uses only the hypoellipticity of by
I
L +1,
which follows from Proposition U.18.)
the unique self-adjoint extension of
I
We denote
L |C , noting that
L
= (L) .
is a positive self-adjoint operator, so it generates a contraction
2 semigroup
{A : t > 0}
on
t
resolution of
f°°
L : namely, if
J
AdE(A)
is the spectral
0
L, A, = exp(-tZ) = t
J
e" U dE(A). 0
By the Schwartz kernel theorem (cf. Treves [l], Chapter 5l), for each there is a tempered distribution
K( # ,t)
A t u = u*K(-,t)
Moreover,
K
on
G* (O,00).
complex conjugation,
K(»,t)
Since
such that
(ueS).
is a continuous function from
a distribution on
G
t > 0
A t
(0,°°) to
S1
and hence defines
is self-adjoint and commutes with
is symmetric about the origin, that is,
K(x,t) = Ktx" 1 ^). (U.22)
LEMMA.
(a)
(L+3t)K=0
in the sense of distributions on
Gx (0,-). (b)
K
(c)
Fpx all
Proof:
is_ C°° on xeG,
Gx (o,«). t > 0,
and
r > 0,
K(rx,rDt) = r~Sc(x,t).
The proof of (a) and (c) is the same as the proof of parts (i)
and (iv) of Proposition 1.68, and (b) follows from (a) by Proposition k.lQ and Lemma 1+.21.
#
133
•(U.23)
K(-,t)eL2
LEMMA.
for all. t > 0 ,
and
J|K(x,t)|2dx = t" Q / D ||K(x,l)|2dx. Proof: If u e L , let Tu(x,t) = (Atu)(x). Clearly T is continuous o from L to the space of distributions on G* (0,°°). However, the range of T
lies in the nullspace of L+d , on which the distribution topology
coincides with the
C
topology (cf. Treves [l], Chapter 52), so the linear
2 functional
is bounded on
f
Tu(O,l) = u(x)K(x,l)dx o U G S , so by the converse to the Schwarz inequality, K(*,l)eL . The
for
u •*- Tu(0,l)
L . Moreover,
desired result now follows from Lemma U.22(c). § We know that to
K is a smooth function on Gx (O,00).
G x B by setting {k.2k) LEMMA.
Gx]R
K(x,t) = 0 for t < 0. Suppose
D > Q/2.
and (L+3 )K= 6 where (Remark:
We now extend it
Then
K is locally integrable on
6 is the point mass at (0,0)eGx]R.
we shall show later that the hypothesis
D > Q/2 is
superfluous.) Proof:
Clearly
K is locally integrable except perhaps near
However, by Lemma 4.23, for any 6
f
0 > |x| 0,
R > 0,
|K(x,t)|dxdt < f [ ( |K(x,t)| 2 dx] 1/2 [f J
0 >G
^2[\
' |x| Q/2.
This shows that
and hence defines a distribution.
K£(x,t) = K(x,t) K
-> K
prove that
(L+3. )K = 6
is locally integrable on
Moreover, if we set
for t > e, Ke(x,t) = 0
shows that
G
for t < e, this estimate also
in the distribution topology as it suffices to show that
e •> 0. Hence, to (L+3. )Ke + 6
T>
distribution topology as
e -> 0, and this is equivalent to the assertion
that for all u G C ( G x E ) ,
(L+8 )(U*K £ ) -* u
U
(convolution on
in the
X>
pointwise as
e •* 0
Xi
G*]R).
To establish this, observe that by Lemma i+.22(a,b), (L+3t)(u^Kt)(x,t) = (L+3 )
rt-e r "e f J -oo
u(y,s)K(y
i
x,t-s)dyds
i Q
= j u(y,t-e)K(y"1x,e)dy.
Fix
t
and set u (y) = u(y,t-e)
and K (y) = K(y,e).
integral is u *K (x) (convolution on
W On the one hand, since
u
Then the last
G ) , and we have
o = ( V u o )#K e +( W u o ) UGC
Q
a n d
^ > Q/2,
by Lemma i+.23 we have
II (u -u n )*K II < IIu - u J L IIK IL < Ce-e~ Q / 2 D ^ 0
as
On the other hand, u.*K = A u -> u and since
L
commutes with
A
in
2 L as
e ->- 0,
on Dom( L ),
L m (u 0 *K £ ) = A £ L m u 0 + L \
in L 2
as
e -^ 0.
e •* 0.
135
Therefore, to finish the proof it suffices to establish the following: Claim:
If
m
is a sufficiently large integer then the elements of
Dom(L ) are continuous, and for each compact
Q c G
there is a constant
C
such that sup ^
|v(y)|
< C ( l l v l l 2 + !IL m vli 2 )
for
vGBom(Jm).
all
Helffer and Nourrigat [l] (Proposition 6.k) show that if
m
is
sufficiently large, we have the estimate
h(l)GL (G)
xeG
are invariant
0.
x
Then every satisfies
x
and
€ L (G) which is
d> *6. = fy^xfy for all S t t S
138
(Remark:
Of course, unless
exist any such Proof:
£
is reasonably small there may not
's.)
It suffices to prove ( a ) , as (~b) is an immediate consequence
It is easily verified that for any ,^6L ( G ) ,
thereof.
( and ip are invariant under
almost every
xGG
(namely those
x
T
for a e £ .
and under every
a e £, for
for which the convolution integral
converges), we have
a x (x)) =
(oax)#(ocFx)(x) =
The example we have in mind is the Heisenberg group
H
defined in
Chapter 1, Section A, with the standard dilations 6r(zl9...,zn,t) = We d e f i n e
and
for
define
x : H •> H n n
each
a
(rz1,...Jrzn,rt).
by J
in
the
a : H -> H an n
by
n-torus
T
aa(z1,...,Zn,t) =
= {ae(C
(Vl,
: |a.| = J
1
for
all
j } ,
we
139
It is then easily verified that
x
and
E = {a : a e T }
satisfy all the
conditions of Proposition k.2f. The functions which are invariant under and under every
aeE
is, the functions
are precisely the polyradial functions on * "
cj> for which there exists a function
on
x
H , that n [0,°°) x B
such that
We therefore conclude: (k.2Q) PROPOSITION.
If
eS(H ) is polyradial and
| = 1
then
is a commutative approximate identity.
Notes and References For
G = B ,
the results on the equivalence of various maximal functions
are due to Fefferman and Stein [l], whose arguments we have followed in proving Theorems ij-.lO and U.12.
For
G = B
with nonisotropic dilations, these
results are (implicitly or explicitly) in Calderon and Torchinsky [l]. For polyradial functions on the Heisenberg group, they are due to Geller [l], [2], who proved Proposition k.k for such functions by using the group Fourier transform.
Our use of commutative approximate identities and in particular
Theorem ^4.9 is novel, but it should be noted that such approximations have previously been found useful in other situations:
see, for example, Coifman
and Weiss [l], section III.3. Recently, Uchiyama [2] has found a new proof of the theorem implies
M, vfeL
for
GS,
in which the convolution integral
U = 1
on ]R
f*(j), (x) t
"M f e L
with nonisotropic dilations,
can even be replaced by more
general integrals of the form conditions.
f(y)$(x,y,t)dy
where
$
satisfies certain
Uchiyama [l] has also proved a version of this result on general
spaces of homogeneous type, for
p
very close to
1.
The results of this chapter lead to two questions:
First, whether the
analogues of Theorems 4.10 - 4.12 hold for more general approximate identities. Secondly, whether commutative approximate identities exist on any homogeneous group.
As for the construction of commutative approximate identities via
homogeneous hypoelliptic differential operators, this works only for graded groups, since such operators exist only for graded groups.
(This fact was
proved "by Miller [l].) A result related to Proposition 4.27 may be found in Kaplan and Putz
CHAPTER 5 Duals of
H
spaces:
Campanato Spaces
Campanato spaces are function spaces defined in terms of approximation by polynomials on balls, generalizing the idea of bounded mean oscillation introduced by John and Nirenberg.
Among them are the duals of the
spaces for
0 < p < 1,
own right.
In this chapter we prove the duality theorem for
H
and they are also of considerable interest in their H
and then
investigate the relationships between the Campanato spaces and the more familiar Lipschitz classes.
A.
HP
The Dual of
In this section we compute the dual space of description of
HP,
(H P )* will be of the following nature.
0 < p < 1. If
Our
(p,q,a)
is
admissible, the finite linear combinations of (p,q,a)-atoms are dense in HP,
so an element of
functions. q,a
(H P )* is completely determined by its action on such
We shall describe this action explicitly, obtaining for each
a different characterization of
(H P )*.
The fact that these character-
izations are equivalent will then lead to interesting results. If
L
is a linear functional on
H
and
(p,q,a)
is admissible, we
define yP (L) = sup{|Lf| : f q,a
Recall that this requires that a precise conditions are on p. 71.
is a (p,q,a)-atom}.
is sufficiently large, and
q > p; the
(5.1) Proof: p
P
q,a
if
y P (L) = sup{|Lf| : p P (f) < l}. q,a q,a -
LEMMA.
By (2.IT), for each
(f) > 1-e,
so
feH
p (f) < 1, q,a
and
f = EX.f.
with
y
P
which shows that
there is a (p,q,a)-atom
(L) > sup{|Lf| : p
Q.sa
P
Q.5a
~
for each
1
1
—
with
(f) < l}. On the other hand, ~
e > 0
there is an atomic decomposition
(L)(ZA P ) 1/P < y P
q, a
sup{|Lf| : p P
1
~
q,
(f) < 1} < y P -
q9a
-
y (L) < °°, and that q,a
y
(L). #
qjQ-
The usual elementary arguments show that and only if
f
£AP. < 1+e, so
|Lf| < ZA.|Lf I < y P ~
e > 0
L
is continuous on
is a norm on
q,a
HP
if
(H ) * which makes
(H P )*
into a Banach space.
every
Le (H )* extends continuously to the Banach space obtained "by completing
HP
We remark that the proof of Lemma 5.1 shows that
with respect to the norm llfll = inf{ZX. : f = ZX.f. i
Thus when
p < 1
l
l
is an atomic decomposition of f}.
we lose information in passing from
We now define the Campanato spaces of all open balls in C
a
G.
If
vu (u) = sup
g
Unf
. Let
a > 0 , l 0,
because
q,a H
is not a Banach space for
p < 1.
In fact, in view of the identification
of Campanato spaces and Lipschitz classes which we shall prove below, such results are known to be false:
cf. Stein and Zygmund [l].
B.
BMO
We now examine more closely the nature of the spaces
C
, q,a
with the case
a = a = 0.
It is an easy exercise to show that
0 For
q < °°, however, If
u
C
Q
is larger than
beginning
0 °° C^ ~ = L .
«> L .
is a locally integrable function on
G
and
B
is a ball, we
set ., r u(x)dx. B We then define
BMO
("bounded mean oscillation")
locally integrable functions
" U|I BMO
(5.6)
5
PROPOSITION.
SUP
u
on
G
such that
BG8
BMO = 0 ° ^ ,
and
v°>Q
0,
let
u = |B(2 k ,0)p 1 [
= m
BMO
u(x)dx. k
B(2 ,0) Thus
f
B(2 ,0)
We have (u(x)-yk)dx|
= A2 Q ,
functions:
and hence
y ~y | < A2it,
so t h a t for
k > 1
|u(x)-yQ|dx B(2 k ,0) Therefore,
K—J.
^
= 1
( l + 2 Q k)2" e k ) < «,
which yields the desired result since We can obtain more insight into If
u
(l+ |x|)~^"edx < ~. BMO by introducing the sharp function.
is locally integrable on G, we set
u (x) = sup{|B|
|u(y) - mu|dy : B
is a ball containing x}.
Clearly we have
The following result expresses the duality of H maximal functions.
and BMO in terms of
150
(5.10) and
THEOREM.
There is a constant
C
such that for all
f6 H 1
u G BMO,
f(x)u(x)dx| < C |Mf(x)u*(x)dx
Proof:
If
fGH
the proof of Theorem 3.28 yields an atomic
k k f = EX.a. IK 1 1
decomposition
k a.
(i)
,
(M = M ( l ) ) .
with the following properties:
k k k B. (= B(Tpi\ ,x. ) in
is a (l,°°,0)-atom associated to a ball
the notation of Chapter 3). (ii)
X. = C2 |B.| where
(iii)
For each
k,
is an absolute contant of the balls If
uGBMO,
C
\J.B. = Q L
is an absolute constant. where
such that each
Q
= {x : Mf(x) > 2 },
xQQ
is contained in at most
B. . then, by (i) we have |(f(y)u(y)dy| = |z.,Xk (ak(y)u(y)dy| j
IK 1 J 1
-m vu)dy| Bk
"1 J
|u(y)-mku|dy
B.
i
l
< E.. Xku*(x)
~ so t h a t ,
i n view of
(ii)
and
IK 1
(iii),
for
and there
xGBk, 1
L
151
f(y)u(y)dy| < E A k |B k |~ 1 f u # (x)dx k l
!
/
(x)dx
B
LCE,2 k f u*(x)dx. k+1 k Q c fi for all
Since
k,
we have
and therefore
|[f(y)u(y)dy| < LCjf(Zk 2 k X kk (x))u # (x)dx J fi < 2LC |Mf(x)u*(x)dx.
#
We next prove a localized version of this result, from which we shall deduce the John-Nirenberg inequality for (5.11)
LEMMA.
Suppose
There exist
A > 2y
and
feH
and
BMO f
functions. is supported in
B = B(r_,x n ).
u u that if
C > 0,
independent of
Proof: and
r0', and
x , such
B = B(Aro,xQ), f Mf(x)dx > Cp^ Q ( f )
(J>e5
f,
(M = M ( l ) ) .
Without l o s s of g e n e r a l i t y we may assume t h a t ll 2yr
Suppose we
152
have f*t(x)| =
< Cf 1
||f(y)|dy
l-Q-1
Therefore, if
A > 2y,
>Ar
Q
Mf(x)dx < C^r.p1 - d. 0 °°,C
Jf).
= (C
On the other hand, by Theorem 3.28 there exists Mf(x)dx Thus if we take
Q
C
such that
(f).
A = max(2C2/C ,2y) we have
jjWf(x)dx > (C 3 /2)p^ Q (f). # (5-12)
THEOREM.
such that for all
f6H
Let
A,B,B
be as in Lemma 5.11.
supported in. B
and all
|ff(x)u(x)dx| < C f Mf(x)u#(x)dx
There exists
u G BMO,
(M = M, J .
C > 0
153
Proof:
k k f = EX^.
Let
be as in the proof of Theorem 5.10.
In
addition to properties (i) - (iii) of this decomposition listed above, we need one more:
(iv)
If
k B.
does not intersect the support of
f
then
k a. = 0 .
Let I
= {(i,k) : B. n B i 0
and radius
(B.) < r }
I
= {(i,k) : B k n B ± 0
and radius
(Bk) > r }.
t-
1
1
—
U
Then in view of (iv), we have
f = f-L+f2,
where
f. = Z_. x V S «3
On the one hand, since
A > 2y we see that
proof of Theorem 5.10, with
Q
f
redefined to be
is supported in B. The { x 6 B : Mf(x) > 2 }, then
shows that (5.13)
|If (x)u(x)dx| < C
On the other hand, if
Moreover,
|f = 0
and
(i,k)el
f
= f-f
we have
f Mf(x)dx.
Ha. II__ < |B.|" < r
is supported in
B.
Thus
f2(y)u(y)dy| = | f2(y)(u(y)-mgu)ay|
- C 3 r 0 p«o,0(f) JJu(y)-«gu|dy < C 3 A Q p^ o (f)u # (x)
for
xeB.
, and hence
If we multiply both sides of this inequality by
Mf(x) / f Mf(y)dy, integrate over
(5-1*0
B,
and apply Lemma 5 « H 5 we obtain
|Jf2(y)u(y)dy| < C 3 A Q p^ Q (f) [f ^Mf (y)dy]" 1 J_Mf (x)u*(x)dx < C^ f Mf(x)u*(x)dx.
Combining (5-13) and (5.1*+), we are done. (5.15) u e BMO,
THEOREM.
every ball
#
There exist constants B,
and every
0,0'
such that for every
a > 0,
|{xGB: |u(x)-mBu| > a}| < c|B|exp(-Cf a/Hull^). Proof:
It clearly suffices to assume that
is real-valued.
Given a ball
B
and
a > 0,
Hull M Q = 1
and that
u
let
E = {xeB : u(x) -nvu > a}. r>
Then
B
X (x)(u(x)-KLu)dx =
E
-B
-nLXP)u(x)dx. JB (x-ni(x) E -B E
Now, the function
f(x) = xE(x) - (mBxE)xB(x) = xE(x)-|B| 1 | is bounded and supported in
B,
and
f = 0.
Thus
multiple of a (l,°°,0)-atom, so by Theorem 5.12, if
f B
is a constant is the ball concentric
155
with
B
whose radius is
A
times as large as that of
XT?(x)(u(x) -mu)dx| < C B
I Mf(x)dx B
(since
B, II u II ^ = l ) .
Also,
Mf(x) < MxE(x)+ |Br 1 so that
Mf(x)dx
2C , let
156
The same argument yields the same estimate for the measure of F = { x e B : u ( x ) - mgU < - a}, so we are done. # (5.16)
COROLLARY.
If U G B M O
and e < C
then
e £ ' U ' is locally
integrable on G.
C. If
Lipschitz Classes
a > 0, the elements of C q,a
are continuous (after correction on
a set of measure zero) and in fact belong to certain Lipschitz classes, depending mainly on the size of a. In the case where
G
is a stratified
group, we obtain below a precise global characterization of C Lipschitz space (although our results for ae M
as a
are not quite complete).
For the general case, we content ourselves with stating the following description of the local smoothness properties of the elements of C , q,a which follows from results of Krantz [l], [2]. Notation: space of order
If a > 0, we denote by A (-1,1) the classical Lipschitz a on the interval
1 < j < n, we define — — (5.IT) ueC
(-1,1)
(cf. Stein [2]). If x e G and
y^ : (-1,1) ^ G by y^(t) = x-exp(tX.). x x j
PROPOSITION.
Suppose
a > 0, 1 < q < °°, and a e A . If
and d(l) < a then X u is continuous, and moreover q,a (-1,1)
for. x e G , 1 < j < n.
157
For the remainder of this section we assume that
G
is a stratified
group. We shall work from scratch, without using Proposition 5.17«
First,
a few details to set the stage. (1) Since elements of
A = ~E for a stratified group, we shall denote the
A by
N
rather than
a. Ca
(2) By Corollary 5-5, we have (Actually, C ,, = C q.,JN
J^
= C^
for a > 0 no matter what
by a modification of the arguments given below. of the chapter.) We shall therefore assume that subscript
N
a > 0 and N > [a]. is, as can "be shown
See the notes at the end q = «
and
suppress the
Thus,
q henceforth.
(3) Also by Corollary 5-5, if N -L
so it suffices to consider to H
for
> N —
> [a] we have c. ~
c" = c" + P IN..
O
, i
N < [a], (The cases N < [a] are not relevant
theory, but we shall obtain results for them which are of interest
in their own right.) (k) In the definition of the seminorm convenient to identify the balls in V
N(U) =
su
Pr>0,x G G
inf
PSPN
eSS
v
it will henceforth be
G by their center and radius. Thus, SUP
y 6 B (r,x) ' " " M * ) - P(x) | .
Next, we define the Lipschitz classes with which we shall be dealing. These are homogeneous versions of the spaces called accordingly, we shall denote them by
r Om .
V
in Folland [l], [3];
We recall from Chapter 1,
158
Section C
that
that
is continuous for
X u
C
is the set of continuous functions d(l) < k.
If
a > 0
and
u
on
G
such
a
is not an
integer, we define
rf m == {{uu66CCta] : |u|a [a]
If
a
< «},
where
is a positive integer, there are two reasonable definitions of a
Lipschitz class of order
a.
The one which occurs most frequently is the
"Zygmund class" : |u|o < - } ,
where
|xIu(xy)+XIu(xy"1)-2XIu(x)|/|y|. However, we shall also encounter the "naive" Lipschitz class f*Om = {usC 0 1 " 1 : |u|a < « } ,
where
lUla = SUp d(l)=a-l For the sake of completeness, we mention that for of Folland [l], [3] is the set of all for
a
a > 0,
such that
the space I
X u
?hom_ ' a
are obviously seminorms on
W
N = {uer a
u -*• |u| | , u -*• |u
h o m
a
:|u|
=
' 'a
o } , '
N = a
{ u e r h o m : |u|* = o } . a
' 'a
r
is bounded
0 < d(l) < a. The functionals
rhom
u6r
hom
159
(5.18)
PROPOSITION.
is an integer, w—
If
a
is not an integer, W
for d(l) = k. Conversely, if ueC k U
K.
XXueP
for
Corollary 1.1*5.
d(l) = k
then
XJu = 0
Since it is obvious that
vanish if and only if immediately.
v
is constant,
W
for
d(j) = k+1, so (0 < a < l)
|v|a
i.e.
veP_,
and
UGP
by
|v|^
the assertion follows
#
The corresponding assertion for be that
a
hi - P a—l . a
Proof: If U G P . then x\e? and
= Pr -,. If
W
when
a
is an integer ought to
= P . It comes as something of a surprise that this is true
only when
G
is Abelian.
functions
u
on
G
In fact, recalling that
such that
uoexp
P
is the set of
is a first-degreee polynomial on
g,
we have: (5.19) PROPOSITION.
If
a
is a positive integer,
W = {ueP . : X ! u 6 ^ S O a a+1 1 Proof: W
= P
G = ]R .
We first prove the proposition when
Then
a = 1,
namely that
The proof proceeds in five steps.
P
= P
, so we must show that
law additively, we have that (5.20)
d(l) = a},
It suffices to prove the assertion for
n P^SO.
Step 1.
for
ueW
P
W
is Abelian, i.e. = P . Writing the group
if and only if
u(s+t) +u(s-t) - 2u(s) = 0
It is thus obvious that
G
for all
s,teG.
c M . On the other hand, suppose
U G W . Given
i6o
xjGG,
we take
s = (x+y)/2, t = (x-y)/2
and then
s = t = (x+y)/2
in (5.20), obtaining u(x)+u(y) - 2u((x+y)/2) = 0 = u(x+y)+ u(0) - 2u((x+y)/2). Therefore, setting
v(x) = u(x)-u(0),
v(x)+v(y) = v(x+y) Since that
v
for all
x,y6G,
is continuous, it follows easily that
v
is linear, and hence
ueP^ Step 2.
For any
Returning to the general stratified
xeG
and
Yeg
the function
(5.20), so by Step 1 it is of the form C|)6CQ(]R)
with
U(t)dt = 1
(5.21) Let
we have
and
G,
suppose
f(t) = u(x-exp(tY)) f(t) = u(x)+Ct.
t(j>(t)dt = 0:
ueW_. 1
satisfies
Let us choose
it follows that
Ju(x-exp(tY))cf>(t)dt = u(x).
$ : E n -> G
be as in Lemma 1.31, that is,
4>(t1,...,tn) = (exp(tX1))(exp(tX2))---(exp(tXn)), and define
where
J
^GCL(G)
by
is the Jacobian determinant of
$.
Then by (5.2l),
u*i|;(x) = ju(xyH(y- 1 )dy = Ju(x(exp(tX1)) • • • (exp(tXn)) )$(t1) • = u(x). Therefore
u
is
C
on
G.
Step 3. u(0) = 0.
If
U G W , "by subtracting off a constant we may assume that 1
Then, as in Step 2, it follows from Step 1 that
u(exp(tY)) = tu(exp Y) let
uf
for any
be its differential at
yGG. 0.
By Step 2, u o exp
Then for any
is differentiable:
Yeg,
u(exp(tY)) -u(0) -u'(tY) = t[u(exp Y) -u'(Y)]. By definition of
u1 , the quantity on the left is
this can only happen if which means that Step h. Yeg, X,Yeg,
u(exp Y) = u'(Y).
u e N . Then
u(x«exp(tY)) - u(x) then, we have
u
t -»- 0,
is linear on
t,
hence
X 2 u = Y 2 u = (X+Y)2u = 0,
Y u = 0.
For any
so that
[X,Y]u = 2XYu.
X,Y,Zeg, UXYZu = 2X[Y,Z]u = [X,[Y,Z]]u.
Applying the Jacobi identity to this equation, we obtain (5.23)
XYZu+ ZXYu+YZXu = 0.
On the other hand, by (5-22), (5.2*0
and
is smooth by Step 2, and for any
is linear in
(XY+YX)u = 0,
Therefore, for any
uoexp
as
ueP
Suppose
(5.22)
Thus
o(t)
2XYZu = |-[X,[Y,Z]]u = |[[Z,Y],X]u = [Z,Y]Xu = ZYXu-YZXu.
Subtracting (5-23) from (5-24) and using (5-22) again, XYZu = ZXYu+ZYXu = Z(XY+YX)u = 0.
g,
162
Since
G
is stratified, any
of terms of the form
XYZ
Therefore, X u = 0 Step 5*
X
with
where
whenever
d(l) = 3
X,Y,Z
are homogeneous of degree 1.
d(l) = 3,
We have now shown that
so
so that
u
usP
n P
ueP
W_ c (p _L
suppose that
is a linear combination
by Corollary 1.1*5.
n P_
c.
). Conversely,
_L
and (without loss of generality) that
is a linear combination of the coordinate functions
Chapter 1, Section C, with
d. < 2.
u(0) = 0, r\ in J
Then by (1.23) and (1.2*0,
u(xy) = u(x)+u(y)+ EPi(x)Qi(y) for some
P. ,Q. e P
which vanish at
0.
Since
u o exp
and
Q. o exp
are
linear,
From these equations it follows immediately that We now return to the Campanato spaces of lemmas we always assume implicitly that observe that if
u G C , x G G,
and
uGW . #
C . In the following sequence N < [a]. To begin with, we
r > 0, the map x |u(x)-P( X )|
is continuous from
P
to [0,°°) and tends to
so by local compactness of (5.25)
For each (5.25).
ess sup^^/
x 6G u (P
r
'x0 no confusion.)
and
w
P,, there exists iM
x |u(x)-P^
r > 0
v
(x)| =
°° as sup
P
r, x
inf^
D
GP
u
and
N,
\ |p(x) | ->• °°,
such that
i\i
e s s sup,,,,-./
we fix once and for all a
also depends on
/
P
r, XQ
„
GP
I>I
x
|u(x)-P(x)
satisfying
of course, but this will cause
163
all
(5-26)
LEMMA.
For each
xQeG,
r > 0,
s > 1,
N6l
and
there exists
|P(x)|
By making the change of variable
to show that for all
Q G P^
and
But this is clear since Q
P
(5-27) and
eSS S U p
for
d(l) < N,
Q(x) = P(xQ(rx)),
it suffices
SUP
for
d(l) < N,
XGB(1,O) i Q ( x ) l'
is finite-dimensional and the functions
* supx6B(i,o) lQ(x)l'
are both norms on
r > 0,
lQ(x)l i C l s N
XeB(s50)
such that for
s > 1,
|XIQ(0)| < C 1 s u p x 6 B ( l j Q ) |Q(x)|
SUp
> 0
PGPN,
jX }
Proof:
C
Q
* SUPS>1
sup
xeB( s ,o) S " N |«( X )I
P . #
LEMMA.
There exists
C2 > 0
such that for all
uecj,
X
O
GG
'
s > 1,
x 6 B(sr,x 0 ) I u ( x |u(x)-P (x) I < C v"(u)sa(l + log s)ra r,xQ ?,xQ)
if
a = N.
16k
Proof:
e S S SUP
k—1 k 2 < s < 2 . Then "by Lemma 5.26,
Suppose
xGB(sr,x0) iu(
|u(x) - P < ess sup p r X xGB(2*r,x0)
(x)|
< ess sup |u(x) - P (x)| xGB(2 r,xQ) 2 r,xQ (x)-P
ess sup
a/
(x)| 2Jr,xQ
k va
w o < vN(u)(2 r)
1k
°
!
sup
xGB(2Jr,x0)
2
xGB(2Jr,xn)
2 J -"-r
vN(u)(2 r)
v£(u) [ (2 k r) a +
Thus if
a > N,
by summing the series we obtain
|u(x)-P 2Jr,xn
165
eSS
SUP
xSB(sr,x0)
[2a
a a r s ,
•whereas if
a = N,
s). (5.28) LEMMA.
If u e c j ,
then
|u(x)| = 0(1+ | x | a )
a.e. if a > N,
|aa)log(2+ |x|)) a.e. if a = N. |u(x)| = 0((l+ |x| Proof:
In Lemma 5«2T» take
|P(X)| =0(l+|x|N)
(5.29) LEMMA. (a) (b)
for all
r = 1, x = 0, and use the fact that
PeP .
Let (j) be a measurable function on G such that
| 2.
[0,1].
Since H u -> u in S', u u
#
is
0(t
2
' ^"" ) if
In any case, we have
i " X i J 1 Wo
1
fl
(a/2) < k < (a/2)+l. k-1
times in
a < 2,
t,
we
0( |log t|)
if
119 H ull^ is integrable on
168
But t h e l i m i t on t h e r i g h t e x i s t s i n t h e uniform norm, and T h e r e f o r e we can c o r r e c t
u
H.ueC .
on a s e t of measure z e r o t o make i t c o n t i n u o u s .
Once t h i s i s done, we have f1
k
(5-32)
(H - I ) u = 1
(where by
9 H t a
J
we mean
f1
••• ( 3 H , ) - . . ( a , H 0 J 0 t l \
9.H | ), t t t—*a
)udt • • • d t 1
K
the i n t e g r a l converging uniformly,
But also (H - I ) k u = 1
( - l ) k u + Z ^ C - l ) ^ 1 ^ ) ^ .u. 0 j k-j
00
Since
j
H
.u is C , to prove that X u is continuous it suffices to J k prove that X (H -I) u is continuous, and this we shall do by differentiating under the integral in (5.32).
Observe that since
H
t
• • *E
l
u
Therefore,
i
t
t
\
i
\
t +###+t
i
t
k
= H
\
,,
V" \
V^""^
b y Lemma 5 » 3 O w e h a v e
• • • [ I I X J ( 9 H ) - - - ( 9 H, )ull d t • • • d t I t t_ Z Z °° 1 K T k t
and the last integral converges provided that provided that
d(j) < a.
Hence for such
AJ(9.H,
0
z Z
l
)-..(3.H z
\
(a-2k-d(J))/2 > -k, that i s ,
Jfs
the integral
)udt •••dt. 1
K
169
converges absolutely and uniformly, so we can interchange differentiation and integration to conclude that
X u
is continuous for
We return to the study of the polynomials assume that
P . If r,xQ
and observe that
and
X
0
J
0
6G
a (r,xQ) = 0
LEMMA.
if
There exists
We define
C
> 0
such that for all
ueC°|,
r > 0,
with
If
Lemma 5-26, since
d(l) = N
then
X1?
when
d(l) = N.
is constant for all
P6PN
N.
|a I (2yr,x 0 )-a I (2 Y r,y 0 )| < C 5 ^(u)r a ~ N Proof:
ue C N
#
is continuous by Lemma 5«319 so henceforth we shall replace
u
"ess sup" by "sup" in (5.25) and similar expressions.
(5.33)
d(j) < a.
%x 0
sup _/ \ P_ (x) - P~ (2 2yr,y_ ^xeB(r,x_) ' 2yr,x n u u u
v IP_ (x) - u(x) I + sup _/_ v |u(x)-Po < C_, r~ [sup _/_ - 1 -^xGB(2yr,x_) ' 2yr,x ' ' ^x6B(2yr,y^) ' 2yr,j
< 2 a + V c , v"T(u)ra"N. #
170
(5.3*0 0 < e < 1,
LEMMA. and
There exists
C^ > 0
such that for all
ueC°J,
r > 0,
x e G, if
| a i (r,x 0 ) -a I (er,x 0 )| < C6v^(u)(l + |log e|) Proof: suppose that
We may suppose that 2
< e < 1.
d(l) < N,
if
d(l) = a = N.
since otherwise
a T = 0.
First,
By Lemma 5.26, ) (x) |
vN(u)[r + (er) ]
Now suppose that
2
+1)
< £ < 2~ k .
Then by the result for
2~X < e < 1,
|a].(r,x0) - a;[(er,x0) |
If
d(l) < a
it equals
the last sum is less than
k+1, which is comparable to
(l-2
'~a)~
1 + |log e|.
}
#
whereas if
d(l)= a
171
(5.35)
LEMMA.
If
uecj
then whenever
limr. 0 a i ( r ' X 0 } for all
x~GG.
xIu(
Moreover,
(5.36)
and
=
d(l) < a,
lajCr^)V
J(XQ)
=
lim ^ 0
a
T^ r ' x n^*
The existence of
Let
v_(x~)
is guaranteed by Lemmas 5.31 and 5*3h9 and the estimate (5.36)
will follow from Lemma 5-3^+ once we have shown that Suppose to the contrary that there exist such that and let degree x
0
x
Proof:
v_(x0) ^ X u(x ). Let P
k.
k
Also, let
Q r,xQ
of homogeneous degree
v (x ) = X u(x Q ).
x 6G
and
J
with
be the integer such that
be the left Taylor polynomial of
u
at
x
thus
Q
r,xQ
(x) = P
of homogeneous
x x
r,xQ
d(j) < a
k < a < k+1,
be the left Taylor polynomial of
k:
u(xQ)
(n) 0
P
r,xQ
unless
(x) is obtained from P (xnx) r X 'X0 ' 0 omitting the terms which are homogeneous of degree N. Then
a = N = k+1, in which case
X Q (0) = a (r,x ) for r,xQ 1 0 in
P. k
as
d(l) < k.
r •* 0 Since
Q
^
r
d(l) < k, -
to a polynomial XJQ(O) ± XJP(O)
and it follows that
QeP, such that J£ there exists
r
at
Q
converges
r,xQ
X Q(0) = v_(x ) for l u < 1
and
C
> 0
such
that - 2C_r f
for
r < r_. ~ 1
Also, from the stratified Taylor inequality (1.1*2) it follows that there exists
r2 < r
SUp
such that
x6B(r,0) l u ( x 0 x
172
and hence s u p x G B ( r 5 Q ) |u(x Q x)-Q(x)| > C T r k
(5.37)
On the other hand, if
sup
X6 B(r,0)
while if SUp
r < ly
a > N,
I u ( x 0 x ) - Q r,x 0 ( x ) l =
a = N,
for
Sup
x6B(r,0) l u ( x 0 x ) " P r , x Q ( x 0 x ) ' - V N ( u ) r " '
by Lemma 5•3U we have for
r < 1/2:
x SB (r,0) l u(x O x) - Q r,x n (x) l *
SUp
x eB (r,0) l u ( x 0 x ) - P r,x 0 ( x 0 x ) l + S U P x 6 B(r,0)
l P r,x Q ( x 0 x ) " Q r , x Q ( x ) I
r|r k+1 ]
Moreover, by Lemma 5•3^, SUp
xeB(r,0) l Q r,x 0 (x) - Q(x) l t Cl0Sd(l) N+l
then
C® = P .
In cases (a) and (b) the seminorms
d(l) = N,
Suppose
and
x,yeG
as a Lipschitz
N > a.
a > N.
C^ = r£ om .
(a)
Proof:
C
v
and
| |
(or_
| | ) are equivalent.
N < a < N+l. By Lemmas 5.33 and 5.35, if uGC°J, -
N
we have
|x I u(xy)-X I u(x)| < |x I u(xy)-a I (2 Y |y|,xy)| + | a^y
+ |a I (2 Y |y|,x)-X I u(x)|
|y | ,xy) - a I
Ilk
so that |u|
uerhom
if
a < N+l
< C_~v (u) or
|u|" < C
) or respectively, and u
ue f
xQ6G,
and
uGfhom
if
a = N+l; moreover,
v (u) respectively. ( a e l ) then for
let
P
G P^
Conversely, if
N = [a]
or
N = a-1
be the left Taylor polynomial of
at
x of homogeneous degree N, and let 0 by the stratified Taylor inequality (1.1*2),
Q x
(x) = P x
0
(x
x ) . Then
0
vij(u) < sup „„ ^~ sup ^f N r""a|u(x)-Q N ^ G G . r X ) px6B(r,x0) ' \
This proves (a) and (b). Finally, if that if UGPN
U G C
then
N
X u
by Corollary 1.1*5.
N > a.
v
dominates Proof:
and
If
d(l) = N+l, and hence
# C
when
As before, it suffices to consider
(5.^0) THEOREM.
then Lemma 5»35 implies
vanishes indentically for
It now remains to characterize and
a > N+l
N
a
is a positive integer N = a.
is a positive integer, then
^om C^ c r r^
and
| L. If
ueC
N
5
Lemma 5-35 implies that for
d(l) = N-l, ) - 2XJu(x)
< |aI(r,xy)+aI(r,xy"1) -2a;[(r,x)|
x^fxy" 1 ) - aI(r,xy"1) | + 2|xIu(x) - a ^
x,yeG,
r = hy |y| ,
175
,xy
) - 2aT(r,x)I +l6y C,-v^(u) |y| I ' o
|XX(P
r,xy
+P r,xy
. - 2P -1 r,
r,xy
We estimate
T
as in Lemma 5«33-*
1-N
r,xy ,1-N, N,
»N+1 2
= h To handle
Y
T», we make the following observation:
Q(xy) - Q(x) (l.23) since n. 3
with
depends only on Q
y
and not on
is a linear combination of
d. = 1.
Taking
3
Q = X P rx3T
QeP ,
x.
Indeed, this follows from
1
and the coordinate functions
, then, we see that
^ 1 ± r,xy r,xy r,xy Thus, by the stratified mean value theorem (l.ij-l),
r,xy
for any
r,xy
r,xy
176
X.X 1
But
i s a constant function for T
< C
X K 's
i s a l i n e a r combination of
l
| | E
= N
d(K) =
N and
with
d(K) =
N,
and
X
P G P , so by Lemma 5 • 33 5
|aK(r,xy)-aK(r5xy" )
t C"|y|vJ(u). Therefore, finally,
|XIu(xy)+XIu(xy-1)-2XIu(x)| < [l6y\ + ^ V ^ and we are done.
#
The reverse inclusion
r
c C
is more problematical.
this relation is definitely false when any
u6 C
satisfies
|u(x)| = 0( |x|
G
x •> °°.
is non-Abelian:
log|x|)
Proposition 5-19 there exist elements of as
+ C"]vJ(u) |y | ,
r
N
as
°m
However, we shall now show that
In the following lemma and theorem we take
x ->• °°,
c C
G = Bn
additively, but continue to use the notation
by Lemma 5*28, whereas by
which grow like
T
X
Indeed,
when
G
|x| is Abelian.
and write the group law
for left-invariant (i.e.,
constant-coefficient) differential monomials. (5.^1)
LEMMA.
Proof:
Let
If
v(x) =
uGr^ Om (]R n ) then
u(x)-u(0).
|v(2x)-2v(x)| =
|u(x)
Then f o r
all
| = 0( |x|log|x| )
x e l
n
,
| u ( 2 x ) + u ( 0 ) - 2 u ( x ) I < lul , | x |
as
ITT x = 2Jy,
Setting
we have | v(2 j+1 y) - 2v(2jy) |
< 2-J-1|u|1|2Jy| = |u|x|y|/2. Hence for any positive integer v(y) - 2~ v(2 y)| < Z "
k,
12~^v(2 y) - 2~
v(2^
y)I < klul
so that |v(2ky)| < 2 k - 1 k| U | 1 |y|+2 k |y(y)|. Setting
C = sup, i .. |v(y) | and sup
Therefore, if
r > 1,
z = 2 y,
we obtain
. |v(z) | < 2k~1k|u| +2 k C. X |z| 0
and several generalizations) seems
to appear first in Nagel and Stein [l]; see also Jerison [l].
181+
CHAPTER 6 Convolution Operators on Kr
In this chapter "we study the action on
H
of certain types of
convolution operators which include the classical singular and fractional integrals.
As an application, we prove a Marcinkiewicz-type multiplier
theorem for functions of the sub-Laplacian on a stratified group.
A.
Kernels of Type
(a,r)
The convolution kernels we shall be considering are the following. Suppose
0 < a < Q
is a function
K
and
on
G
r
is a positive integer.
which is of class
l Y ^ M l < Ajlxl 0 1 ^"^ 1 5
(6.1)
C
for
A kernel of type
on
G\{0}
|l| 0
LEMMA.
L,B
0 < a < Q
such that for every kernel
(6.5) where
Suppose
K
L .) We shall discuss some examples First, a couple of technical lemmas. and
r > 1.
of type
There exist
(a,r)
N6l
and every eS,
| C
< C(A 4-A^
if_ a > 0
and
C]. < C(A +A.J. + B)
±f_ a = 0,
and
are as in (6.1) and (6.3). Proof:
K° = nK,
Fix
n G C°°(B(l,O))
K°° = (l-n)K.
\Yh"(x)\
Then
such that
n = l
K°° is of class
0,
exponent. and
Since
fix
p
with
1 < p < Q/(Q-a),
|K°(x)| < A Q | x j a ~ Q
and
and let
p'
be the conjugate
supp K° c B(l,0) we have
K°e L P
UK II < C A Q , hence
|x|/2.
Thus if
and hence, if
pf
|(TKf)* 2y | z | and hence
y€B,
is the conjugate exponent to
(t > 0,
p,
191
But a-Q-d(l) < a-r-Q < a-Q(p" 1 -l)-Q = a-(Q/p) =
-Q/q,
dx = Cg|: . =C8|B|C I t follows t h a t (M(TKf)(x))qdx
and combining this with (6.11) we are done. (6.12)
Remark:
In case
G
#
is stratified, we can obtain the same
conclusion under somewhat weaker hypotheses on to assume that for
d(l) < r
Y K
is continuous on
rather than for
we must assume in addition that satisfies
|x.K(x)| < clxl"^ 1
G\{0}
|l| < r. X.K J for
K.
Namely, it suffices
and satisfies (6.1) merely
(in case
a = 0
is continuous on j = l,...,v
and
G\{0}
(i.e. for
r < d and
d. = l)
in
order to obtain the result for 2 < p < ° ° . If r > d this is implied by the estimate for Y.K(x) (j = l,...,n) by Proposition 1.29.) The proof j
is identical to the one given above except that the stratified Taylor inequality (1.1+2) is used instead of (1.37) to estimate
M(TT.f) on B°.
We now discuss an important class of examples of kernels of type (a,r), class
namely the homogeneous kernels. C
on
G\{0}
If
K
is a function which is of
and homogeneous of degree
X-Q
where
0 < Re X < Q,
192
it is easily verified that
K
is a kernel of type
is to show that a similar result holds for
(Re X>r). Our object
Re X = 0.
To begin with, we
have the following structure theorem for homogeneous distributions of degree -Q. (6.13)
PROPOSITION.
Let_ k
which is homogeneous of degree defined in Proposition 1.13. (6.11+)
defines a_ tempered distribution
degree Then
-Q y
mass at
= 0
K
-Q
and satisfies
f
= 0,
k(x)cf>(x)dx
where
y
is
UeS)
PV(k) which is homogeneous of degree
-Q.
i_s_ a_ tempered distribution which is homogeneous of
and whose restriction to and
y
G\{0}
Then the formula
> = lim
Conversely, suppose
be a continuous function on
K = PV(k) + C6
G\{0}
for some
i_s_ a_ continuous function C 6 (C, where
6
k.
iji the point
0.
Proof:
If
y = 0, K
the limit in (6.110 exists for any
ijieS, because
lim e _^ 0 I k(x)(x)dx |x|>e = lim
k(x)[(x)-(O)]dx+
-cf>(O)]dx+
J
k(x)(J)(x)dx
k(x)(j)(x)dx, ||
the last integrals being convergent since
| cf>(x) - (j)(0) | = 0(|x|).
formula it is clear that PV(k) is continuous on
S,
easily checked that < PV(k) , o 6^ > =
From this
and from (6.lk) it is for any
r > 0,
so that
193
PV(k)
is homogeneous of degree
-Q
as a distribution.
is a homogeneous distribution which agrees with K-PV(k)
is supported at
derivatives.
But
0,
y
= 0.
of
KeS1
Consider the distribution
F
(As above, this is well defined since K
away from
of degree
-Q,
0,
for any
so again 6 S
keC
and its
so by
(G\{0})
k(x)(j>(x)dx
F-K = Ea X 6.
and
r > 0
However, for
- = 0.
is the
defined by
r
which is bounded as
-Q-d(l),
then
6
which is homogeneous of degree
k(x)[ f#(kx )
>2}, in the
-00
E k, L
N T =
O N T +T .
converges i n norm b e c a u s e
T.f = f*k. 3 3
Since
L feL
as .
k
is
square-integrable
N -> °° t o
kx »
On t h e o t h e r hand,
so since
[f(xy"1)~f(x)]k(y)dy,
T°f(x) = J
the convergence being uniform in set
For
M -> -~, 2 and we claim that this convergence also takes place in the L norm.
Indeed, i f on
(0,r).
2
K = I k. -°° 3
N -»• +«>,
oil G\{0},
In the terminology of
00
If
C
x.
Since
T f
is supported in the compact
{xy : xGsupp f,|y| < 2}, the convergence is also in
L .
197
In order to prove (6.3), it therefore remains to show that the operators Tw M
are uniformly bounded on
Q
IIT.II < Ilk.II =
Hence
L . First, we observe that
f
llT*T.II < C 2 l J —
M ~ Q d y = C.
|k(y)|dy < C f
and
llT.T*ll < C 2 l «J
for all
i,j, so by Lemma 6.18 it will
suffice to show that
llT*T.II < C 2 " l 1 ^ ' i j
whenever
~"
and llT.T*l! < C 2 " ' 1"t5 ' i j
|i-j| is sufficiently large; in fact, we shall obtain these
estimates for
|i-j|
> 3+log 2 y-
We observe that T*f(x) = |f(xz"1)k(.(z"1)dz, and hence T±T*f(x) = ||f(xy~V1)k^(z~1)ki(y)dzdy
= f*G..(x) where
We can then estimate
llT.T*ll
the same form except that
by estimating
k(x)
IIG..I1 . Also,
is replaced by
arguments will yield the same estimates for
k(x
T*T.
is of
), so the same
llT*T.II. Moreover,
198
T.T*f = (T.T*)*f = f*G.. J ^-^ J 1J i
and
j.
where
G..(z) = G (z~ ) , so we can interchange ^-0 -^-0
In short, ve are reduced to proving that i-j > 3 +log
Given such an
i
and
j , let
E = {(y,z) : 2 1 < |yz| < 2 1 + 1 , 2^ < |y| < 2^ + 1 }, — — Then since G
y
, f [k.(yz)-k.(z)]k.(y)dy-k.(z)
^ ( y z ) = k(yz)
-I (y,z)eE
1 +
for
k (y)dy
(y,z)eE,
|k(yz) -k(z) | |k^(y) |dydz + J f |k(z) - ^ ( z ) | |k^. (y) |dydz
I2.
we have
hi < Y( Also,
= {y : (y,z)€ E}.
(z) = I k.(yz)k.(y)dy-k.(z) fk.(y)dy
J |F±J(z) |dz = ^
If
E z
= 0,
f
Since
y.
|yz| < y(|y| + |z|)
and
Y < 21'5'3,
199
and in particular I
|z| > 2|y|.
< sup
C
In
Ip
case
Thus by Proposition 1.7,
|k(yz)-k(z)| |k.(y)|dy
dz
supE
the integrand vanishes unless |k.(z)-k(z)| = |k(z)|.
|z| < 2
Also, for
or
|z| < 2 1
|z| > 2 and
, in which
(y,z)eE,
so that
(Our condition on |z| > 2
1+1
and
i-j
ensures that
1-Y2 J "" 1
> 3/k.) Likewise, if
(y,z) 6 E , |z| - 2 1 + 1 < |z| - |yz| < Y |y| < Y 2 J + 1 ,
so that
Hence
Ip
is dominated by
200
)|z|-Qdz]
Therefore,
On the other hand,
= JJ |k.(Z)||k.(y)|dydZ EC The integrand vanishes unless which case either then, if
|yz| > 2
2 1 < |z| < 2 1 + or
|yz| < 2
2i+1-
since
2^ < \y\ < 2 J + , in (y,z)^E.
As above,
|yz| < 2 1 ,
lzl-2 1 < |z|-|yz| < y|y| < y2*+1, while if
and
so
|z| < 2 ^ 1 + Y 2 ^ i + 1 ) ,
|yz| > 2 1 + 1 , |z|
< |yz|
- |z|
< Y |y| < Y 2 ^ + 1 ,
Hence, as in the estimate for I_,
which completes the proof for
X = 0.
so
|z| > 2 i+1 (l -
y2^±).
201
The proof for
X ^ 0
2^ < |x| < 2^ + 1
annuli
is exactly the same, except that we replace the
by the annuli
R^ < |x| < R^ +1
R = e2lT''X',
where
and use Proposition 6.15 and the equation (6.l6) instead of Proposition 6.13 and the equation
y
= 0. #
These results can be generalized to vector-valued functions.
As in
the concluding remarks of Chapter 3, Section B, if
X
is any Banach space
•we denote spaces of functions and distributions on
G
with values in
by appending a subscript Banach spaces, and let to
V. We define
X:
thus,
B(K9V)
etc.
Suppose
X
and
V
are
be the space of bounded linear maps from
B(X,/)-valued
scalar case, except that
L?,Sw,
X
kernels of type
X
(cx,r) just as in the
|Y K ( X ) | is to be replaced by
IIY K(x)llo/«/ y\
in (6.1), and (6.3) is to be replaced by llf*Kll
T
o
< Bllfll
V-L t o v ; .
T
We then have the following generalization of Theorems 6.10 and 6.19: (6.20)
THEOREM.
Q/(Q+r) < p < Q/a, I£ K
Suppose
r
is a positive interger,
(l/q) = (l/p)-(a/Q),
is_ a_ B(X,y)-valued kernel of type
is bounded from
H?
(b) Suppose Hilbert spaces.
If —
on
G\{0},
to
r
K 6 S p / y ^x o^A , / )
then
and
X
(a,r),
and
V
0 < a < Q,
are Banach spaces.
then the operator
f •> f*K
H^.
Re X = 0,
-^————
C ^
(a)
K
is a positive integer, and is homogeneous of degree
X X-Q
and
V
and of class
——
is_ a. B(X,V/)-valued
kernel of type
are
(0,r).
202
Proof:
In view of the remarks at the end of Chapter 3, Section B,
the proof of (a) is the same as the proof of Theorem 6.10, with absolute values replaced by norms in appropriate spots. 2 L^
spaces, then so are
and
2 Iy,
If
X
and
V
are Hilbert
so Lemma 6.18 still applies.
The proof
of Theorem 6.19, with complex conjugates replaced by adjoints, then establishes (b). # Further results concerning kernels of type applying the duality theorems of Chapter 5attention to the scalar case.) Campanato spaces is given by dense subspace of of the operator
(a,r)
(For simplicity, we restrict
The pairing between the
H . Thus, if
T-. : f •* f*K is.
K
spaces and the f
is a kernel of type
in a suitable
(a,r),
is, at least formally, T~, where Jtv T~u = u#K K
be divergent, so one must be careful in interpreting kernel of type
(a,r) whenever
we see that —
again, formally — (H P )* to
H
(f,u) -> fu, at least for
(We say "formally" because the integrals defining
operators from
can be obtained by
K
T~.)
the dual K(x) = K(x" ).
are likely to
Since
K
is a
is (by the equivalence of (6.1) and (6.1'))
kernels of type
(H^)* for appropriate
These results as applied to Campanato spaces one to show that convolution with a kernel of type local Lipschitz smoothness by the amount
aQ
(a,r) p
define bounded
and
C q,a
q.
with
(aQ,r)
a > 0
allow
increases the
(in the appropriate sense).
This can be deduced by applying the duality and using the observation that 00
if
q
is a fixed
is continuous from
C.
function of compact support, then the mapping (X
oo
C n L q,a
to
Qi
C
q,a
f ->• f'
. The local regularity results,
however, can usually be obtained by more elementary direct arguments:
see
Folland [l], Koranyi and V&gi [l], Nagel and Stein [l], and Rothschild and Stein [l]. Here, we wish to consider
BMO
in more detail.
203
Suppose A-Q
with
KeS'
is of class
Re A = 0.
C
on
G\{0}
and homogeneous of degree
Then by Theorems 6.10 and 6.19 and Corollary 5.7, K
defines a bounded operator
TT_ on BM0/P_, namely the dual of T~ on K U K We shall now describe this operator explicitly. Let K (x) = K(x) if |x| < 1
and
K (x) = 0
otherwise, and let
K°° = K - K . The proof of 0
Theorem 6.19 shows that the operator since
K
f ->• f*K
has compact support, it follows that
L
2 L . However,
is bounded on f*K
2 locally
is well defined as a
2 function whenever
Corollary 5.8) whenever Suppose then that (l,°°,0)-atoms.
f
is locally in
L , and in particular (by
f e BMO. feBMO
and
g
is a finite linear combination of
We clearly have
J(f*K°)(x)g(x)dx = Jf(x)(g*K°)(x)dx, so that
T K
H .
is the dual of
T^Q. K
On the other hand, since
g = 0, *
g*K°°(x) = JK00(x~1y)g(y) l ) . But this is immaterial because T__ IV
is only supposed to act on Next, suppose
K
theorems imply that The convolution
is a kernel of type
K
f*K
BMO/P , i.e.,
BMO
modulo constants.
(a,l),
defines a bounded operator
0 < a < Q. T^
need not converge for arbitrary
so (almost everywhere) when
f
from f6 L
Then our
L
to
BMO.
, but it does
has compact support, so we can define
T__f IV
in general by a limiting process. We now present a direct proof of a slightly stronger result. (6.21) T^
THEOREM.
K
weak L Q ' a
is bounded from Proof:
If
is a kernel of type to
(a,l),
0 < a < Q,
then
BMO.
For simplicity we write
T
instead of
T-_, and we employ the XV
terminology of distribution functions and nonincreasing rearrangements introduced in Chapter 1, Section A.
If suffices to show that there is a
constant
for all compactly supported
C
such that
llTflL..n < C
f e weak L
rJMU —
such that
W Q /=
1#
Given such an
f
and a ball
B , we wish to study
the behavior of Tf on B. By translation invariance we may assume that B = B(R,0),
and we set B = B(2y3R,0).
= f X g and f" = f-ff = f x . B -1 -1 by q~ = p " - (a/Q). Then
Let f
Fix p such that 1 < p < Q/a and define by Proposition 6.2,
q
205
(x)|qdx < [|Tf(x)|qdx < C ( f | f ( x ) | P d x ) q / p J
i
B ap/Q A,
such that a < 1.
Then if rT
(a-Q-d.)rf < -Q J
for
j , and we have
B°
|f(y)||y
a-Q-d.
a- Q
If (y)
"dj
f+
BC
B | ( a-Q-
(a-Q-dj)/q I
r)
BC
|B| But
f |
(a-Q-d.
f*(t) = f*(t)
J|)/Q
Hf 1I
+
if t < Xf(A)
| B|
and
(
(1/r f ) + (a-(J-dj)/Q
f*(t) = 0
otherwise, so since
Xf(A) Xf(A) llf.IL = 1 1
Also,
f*(t) =
llf*ll = 1 J - i n
f*(t + Xf(A))
Xf(A) f*(t)dt < "Jn
and
f*(t)
t " a / Q dt
< llfgll^ < A,
so
207
ip,.
- MX M
= [
(
f^t^dt]"1
A f (A)
,A-Q/a
:•}•
Ardt +
< C [
Therefore
(a-Q-d )/Q
(l r
/ ')+(a"Q-dj)/Q
i_(a/Q)
-d /Q I-DI
J
and so by (6.23), we have (6.2*0
|Tf"(x)-a | < nC Cg
for
xeB.
Finally, combining (6.22) and (6.210, we obtain
iBf 1 f |Tf(x)-a^|dx < C . The theorem now follows immediately from Proposition 5.6.
#
208
B.
A Multiplier Theorem
In this section we assume that
G
is a stratified group.
L, h(x,t),
from Chapter 1, Section G that
and
Laplacian, heat kernel, and heat semigroup on
(H }
G.
We recall
are the sub-
{H }
is a self-adjoint
2 L , so it has a spectral resolution:
contraction semigroup on
H t = f e" X t dP(X). (The integration is over the open interval Htf = f
for all
f = 0.)
If
operator
M
M(L)
t,
we have
(O, 0 0 ),
L
feL
llfll^ < II f H2llh( • ,t) II g + 0
is a bounded Borel function on on
for if
(09«),
as
p
and
t -*» «,
hence
we define the bounded
by
M(L) =
J
M(X)dP(X) 0
Our aim is to prove the following Marcinkiewicz-type multiplier theorem for the operators M(L): (6.25) THEOREM.
Suppose
M
is of class
sup, _ | X J M ^ ( X ) | < C < « , IL
r
is a positive integer and
oil H P
for
C^S'
on_ (0,«>) and
0 n|x| Proof:
then
1
First, let
for l < i
0
such
and
yeB
xGG. xeB
. The second assertion is a theorem of Jenkins [l]. # X
y(x) = e
. Thus by Lemma 6.26 we have
: y(x)y(y), f
= B(l,0),
The first assertion is obvious, since if
Next, let
If
B
is a measurable function on
G,
y(x) > e we define
llfll = f|f(x)|y(x)dx. (6.27)
LEMMA.
Proof:
llf^gll^
0.
is a bounded Borel function on
be the distribution kernel of M/ x(X) = M(tX),
< «, for all
M(L). Then for any
the distribution kernel of
TA^AL)
(0,°°)5
t > 0, ijf is_ K ^ .
let
K
210
Proof:
The h o m o g e n e i t y o f
L
means t h a t
[L(fo a/n su
I ia -nIxI .a -nA P|x|>A Ul e I I = A e .
Then by (6.33) and (6.31*),
< C a |m| a + ( Q / 2 ) + 1 .
|m|+e9|m|(e
#
by (6.31),
|m| > a/0. We then choose
and hence
:|a|E (x)|dx < C'(6|m|/n)a+(Q/2)
m
212
If
With these p r e l i m i n a r i e s out of the way, we can get down t o business. (s) M i s a function of c l a s s C on (0,°°), we define HMl / x = Z* HM( 0
where
and M
s > a + ( Q / 2 ) + 2.
|x|a|K(x)|dx < C
so that
F
Let_ K be the distribution
K e L 1 , and.
kernel of M(L). Then
Proof:
is a function of class C
S a
HMll ( s ) .
Let F(t) = M(-log t) for 0 < t < 1 [e~ ,e~/ ] and the C
is supported in
are comparable.
Expand
F
and F(t) = 0 otherwise,
in a Fourier series on
' norms of F (-TT,TT):
and M
F(t) = E°° a e i m . _ 00
Then
Ea = m
F(0) =
0,
and
M(X) =
and hence
|a
| < llFll . * ( l + | m | ) ~ S . m — _^s j
F(e""A) =
Z00
-oo
Ifl
But
a [exp(ime"A) - l ] , m
K(x) = Z a E (x). The result now follows from Lemma 6.30: -°° m m x | a | K ( x ) | d x < 2°° IIFII , . ( 1 + | m | r
s
f|x|a|E
(x)|dx
< C IIMII , ,(l l , | m r S + a + ( Q / 2 ) + 1 ) . # - a,s c ^ s ) m +^ ° n (6.36)
LEMMA.
Under the same hypotheses as Lemma 6.35,
and for every multiindex
I,
< CI,s,a
K
is C ,
213
Proof: of
M (X) = e M(X),
M (L). Then
norms of so
Let
M
and
K = h(« ,1)*K
Since
and let
K
be the distribution kernel
M
satisfies the same hypotheses as
M
are comparable.
= K *h(- ,1).
M,
Moreover, M(L) = e
Hence
K
is
and the
C
M (L) = M (L)e
,
C°°, and
h(*,l)eS, by Lemmas 1.10 and 6.35 we obtain
|ay
(C ) II M_ v n + C s,0 s,a7 1
< CT IIMil / x, - I,s,a c (s) and similary for
Y I K(x).
Proof of Theorem 6.25:
# Suppose
sup A>Q |X J M^'(X)| < C < oo for kernel of
M
0 < j < s,
M(L). We shall show that if
continuous on likevise for
G\{0} Y K.
and
is of class and let
(r^ K
(0,°°) and
be the distribution
s > r+(3Q/2) + 2
Ix^Cx) | < C | x| ~ Q ~ d ^ I ^ for
on
XJK
is
d(l) < r,
and
then
The desired result then follows from Theorem 6.10 and
Remark 6.12. Fix
ij/e CQ( [1/2,2]) with
ty. (x) = i|;(2"Jx),
and then set
i)i > 0
on
(1/2,2).
For
. (x).
j G TL let Thus
{*.}.c77
is
2lU
a partition of unity on £
ll^.^ll^ < C2~ ^. kernel of
Let
M,(L).
such that
M.(X) = M(X)(j).(X),
By the hypotheses on
llMr\ < C l~ j
(O,00)
—
C
and
let
K.
X -* M.(2 X)
—
satisfy the hypotheses of
norm bounded independently of
|X K.12
and
be the distribution
—
s > a+(Q/2) + 2
]
(0 < £ < s),
1
Lemmas 6.29 and 6.36, if
,2
we have
(^)2-iJ2-^-i;o = c , 2 -^
1 u
which implies that the functions Lemma 6.35 with
M
supp (j). c [2
j. Hence, in view of
we have
x)| < C ^ ^
|x|
,
or in other words,
(6.3T)
IX^.WI < 2(J/2)(^(l)-a) j
Next, for
-
x / 0
and
I ,s ,a d(l) < r
we write
J I 0 I A M X ; - L_oo A K. AX) + L
where
j
|x,-a_
I Aft.U j ,
+1
is an integer to be determined later.
(As we shall see, the
series on the right converge uniformly on compact subsets of estimate the terms with
j < jn
T
(6.38)
r.
""
To estimate the terms with and use (6.37) with
l3>j
To
a = 0: n
I x Y U ) ! < c I.. 2(j/2)(Q+d(D) < c,2 0
"—"0
(6.39)
we use (6.37) with / n , T
G\{0}.)
— 0 j > j
"" we pick
e > 0
a = Q + d ( l ) + e:
Ix^tx)! < C l.>y 2'^2 |x|-
such that
e < s-r-(3Q/2)-2
215
V2 Finally, for each
x ± 0
we choose
j
so that
2
, ,-i < |x|
(J0
< 2
Then the right hand sides of (6.38) and (6.39) are "both dominated "by |x|
. The same argument also works for
Y K,
so the proof is complete. #
Notes and References The
Ir
theory,
p > 1:
For the classical theory of singular and
fractional integrals on ]R , which has a long history, see Stein [2] and Stein and Weiss [2]. Theorem 6.19 is due to Knapp and Stein [l]. Other conditions which guarantee the
2 L
"boundedness of singular integral operators
on homogeneous groups have been investigated by Goodman [2], Ricci [l], and Strichartz [l]. Once the operators type
on
(l,l):
Ir
o
L
(l < p < «)
theory is established, the boundedness of such can be proved by showing that they are weak
see Fabes and Riviere [l], Coifman and Weiss [l], Koranyi and
Vagi [l], and Strichartz [l]. Our proof of Theorem 6.21 is adapted from an argument of Stein and Zygmund [l]. The
H
theory,
p < 1:
For the case of Riesz potentials on IR ,
Theorem 6.10 is due to Stein and Weiss [l]; for kernels of type
(0,r)
on ]Rn
it is due to Fefferman and Stein [l], but an earlier version is in Stein [2]; for homogeneous kernels on the Heisenberg group it is due to Krantz [3]. See also Calderon and Torchinsky [2], Coifman and Weiss [2], Hemler [l], Mauceri, Picardello, and Ricci [l], and Taibleson and Weiss [l] for related results. Multipliers:
For multipler theorems on ]R , see Stein [2], where
earlier references are given; also Calder6n and Torchinsky [2], Coifman and Meyer [l] and Taibleson and Weiss [l]. Theorem 6.25 is joint work of Hulanicki and Stein [l]; details of the proof appear here for the first time.
deMichele
216
and Mauceri [l] have proved a multiplier theorem for the three-dimensional Heisenberg group which includes Theorem 6.25 for case
p > 1
and
M(A) = A
e
m(t)dt
where
G = H_ , p > 1.
m
is bounded on
0
(which implies that all
M
For the (O,00)
i (i)
is analytic and that
su
PA>0
U M
(A)| < «> for
j ) , the result is contained in a general theorem of Stein [3], p. 121.
Note that by the use of Theorem 3.37 it follows that the multiplier operator M(L)
(of Theorem 6.25) is of weak type
(l,l),
whenever
s > |Q+3.
217
CHAPTER 7. Characterization of
HP
by Square Functions:
The Lusin and Littlewood-Paley Functions
In this chapter we show that a distribution in
H
can be character-
ized by analogues to the Lusin and Littlewood-Paley square functions. material here breaks up into four parts: implies
S (f)eL P ,
First, the fact that
and its variants, (Theorems 7-7 and 7.8),
The
feH which follow
easily from the results on boundedness of convolution operators obtained in the previous chapter.
Second, the converse direction for
(Theorem 7.10), which is proved by a duality argument. direction for
p < 1
(see Corollary 7.22).
1 < p,
Third, the converse
which is the most difficult result in this chapter Finally there are, as a consequence, corresponding
results for stratified groups for square functions fashioned out of the heat semi-group. Suppose that
feSf,
0 < a < «>, and
(|>eS, and that
define the Lusin function (or area integral)
S,f
U = 0.
We
by
|f**.(y)|2t-Q-Vlt]
S"f(x) = [f f
We shall be mainly concerned with the case
a = 1,
and we set
S.f = Also, suppose that
0 < X < °°.
We define the Littlewood-Paley functions
218
= [f
g.f(x)
Gjf(x) =
The functions
g f,
f
t
0 JG
t
t+|x
S.f, and G f "bear roughly the same relations to
each other as the radial, non-tangential, and tangential maximal functions O X M.f, M.f, and T.f, and they may be considered as
cj) these maximal functions. how
H
P
2 L
analogues of
The principal object of this chapter is to show
can be characterized in terms of Lusin and Littlewood-Paley
functions.
We begin, however, by deriving some inequalities relating the
latter functions. (7.1) then
THEOREM.
S . f GL ,
Suppose —
0
. I f C,
depending only on
p,
S,f6LP
A^|aA
, |EJdtdX]
0 J0
< Ca Q [f"|s f | P + f"
Jo *
rXP"3t|EjdXdt] t
h jt
" 1 |E t |dt]
It therefore remains to prove (7.3).
Setting
p(y) = inf{ |y
"we have
i: i , . n B(at,y)|t Q 1dydt
0 Jp(y) 0
and
fA -1 dt. j £ (**).t ( y ) t A -> »,
K^
converges in
5'
to a
224
distribution Also, since
K
which is
feS,
f*K
IIg fllg =
Next, let
X
C
on
•> f*K
G\{0}
in
f*K(u)f(u)du
1
S .
and homogeneous of degree Hence, by Theorem 6.19,
< llf#Kll 2 llfll 2 < Cllfllg.
L2((0,~),dt/t).
denote the Hilbert space
X-valued distribution
$
on
G
does belong to
X
Proposition 1.1+9, since
because it is = 0 )
(feS).
0(t
0(t)
as
) as
t -> °° and
t -> 0.
Moreover,
g,f(x) = llf*$(x)llv, so we have just proved that the map (p
bounded from
P L
A
to
2 L».
Define the
by
| f ( x ) < | ) t ((x)dx
-Q.
Furthermore,
$
is given on
integration against the smooth X-valued function
+
C
G\{0}
is
by
$(x)(t) = cj> (x) which t
satisfies
< C ' t- 2 «- 2d(l) - 1 |x/t|- 2H dt J " 0
f -»- f*$
(by
i|x|
t ^ ^ ^ a t
.
For s i m p l i c i t y we assume t h a t
IIS. flip = f f f
and 0 < a < °°,
t
so the result follows from Theorem 7«7«
226
The argument for Theorem T-T-
p / 2
now follows the same lines as the proof of
To wit, we set X = L2({(y,t) : 0 < |y| < t < ~} ^ " ^ d y d t )
and we define the X-valued distribution
$
on
G
by
< f , O ( y , t ) = ff(x)cj), (xy)dx. Then
S.f(x) = llf*$(x)llv, and
for all
$
is an X-valued kernel of type
r,
since
f
< cf
|/2yJ|x-ly||x|/2Y J | x -l y
The second term on the right is a constant times the first we observe that if it follows (if we take by
x|
N > Q+d(l))
then
, and for |y| > |x|/2, whence
that the first term is also dominated
#
We have now shown that if = 0.
feHP
then
gfGLP
and
SxfGLP
for
It is obvious that the converse cannot hold
without some additional restrictions on
(j) and
f.
For example if
G = ]R
227
and the Fourier transform of
is supported in
vanishes identically (and hence so do Fourier transform is supported in require that
U = 0
g.f
(-«>90).
and
(O, 00 ), S.f)
then f#, t
for any
feSf
whose
Moreover, we must in any event
for the integrals defining
much hope of converging, and this implies that
g f
and
S.f
g f = S.f = 0
to have whenever
f
is a constant function. We shall make use of the terminology and propositions in Chapter 1, Section E.
We call attention, in particular, to Theorems 1.6l and 1.62,
which guarantee the existence of Schwartz class functions which satisfy the hypotheses of the following theorems.
We shall restrict our attention to
distributions which vanish weakly at infinity, in order to exploit Theorem 1.6k.
The following elementary result provides reassurance that this
restriction is reasonable: (7-9)
PROPOSITION.
at infinity.
feHP
If
More precisely, for any
t
We observe that
then
f
vanishes weakly
0, A -> ».
If we set
we have
f(x)n(x)dx|
M 1
c
rA r j
JG e JG
f*. (u)i|;+ (u"" 1 x)^U)t" 1 dudtdx t *
cA ® f* k,
there are at most
N!
k' < k,
there are at most
N"(2y)^ k ~ k '
values
k
n B ' ^0; J
i = 1,2,3,... for which
and
~k ~k' B. n B. f 0.
231
k 0 B. is obtained from B. by dilation by the factor 3 3 it suffices to assume that k = 0. First, if xe^lj B° then
Proof: (2y) k ,
Since
3n
IL B.
3 n
c B(^Y C , X ) .
But then since
B(l/2y,x.) c B. 3
N ( 2 y ) " Q = |Sj!JB(l/2y,x. )
1
and hence B. n B.
< |B(llY2C,x)
3
= (Uy2C)Q,
h "
N < (8y C) , which proves (a). Next, if ^ 0,
we have
k1 > 0
and
then
x. €B(yC((2y) kt + l),(2Y)k'x.) c B(2yC(2y)k',(2y)k'x.). i
3
By part (a) with N' = (l6y C) B° n B k ' f 0
C
replaced by
values of for
3
2yC, this can happen for at most
j , which proves (b). Likewise, if
% = 1,...,M
then
(2Y)k'x. G B(2yC,x.),
k' < 0 hence
x. eB((2 Y ) 1 " k 'c,(2Y)' k 'x.), so that B(l/2Y,x. ) c B (2~ 1 +(2Y) 1 " k t yC, (2Y)~k'x.) c B((2Y)2-k'c,(2y)'k'x.) J X £ But then ?B(l/2Y,x. )| < | B ( ( 2 Y ) C , ( 2 Y ) ' x . ) | = (2Y) ( J £ that
M < (l+y2C)Q(2y)"k'Q. This proves (c). #
Next, let c
k _
j -x
,v°°
yLi=ix
and
232
The sum in the denominator always assumes one of the values 1,2,...,N •where N is as in Lemma 7.1k, and we have
E.C.(x) = 1 JJ
for all x e G .
Also, let I k = { t e l : (2y) k + 1 < t < (2y) k+2 }. Then
Z. , C k (x) X v (t) = 1
for all
(x,t)G Gx (o,»).
At this point we change our notation slightly, let B = {Bk : 1 < j < oo, -oo < k < «}. Henceforth we denote elements of 8 j
and k
simply by
B, dropping the indices
(which will be used with other meanings later on).
B = B k = B(r,x) G B J
Also, if
we shall write £ B = Ck>
I B = I k , B* = B(5Y3r,x).
Now, returning to our distributions
f
and F,
for each
B G B we
set (7.15)
F (x) =
I Cp(y)f#*+(y)^+(y"1x)dydt/t.
From (7-13) and the properties of (7.16)
C-D and I , it follows that
F = IBGB FB,
the sum converging in 5'. We make two elementary observations concerning F
B: (i) F^
is some
is a
C
function supported in B*: this follows since ty
C°° and the integrand in (7-15) vanishes unless tGL n
(because
supp \\> c B(l,0)).
B n B(t,x) ^ 0 for
233
(ii)
FP = 0 IB
Hence the
for a l l P e P , a
b e c a u s e t h e same i s t r u e of ip.
are constant multiples of (p,00, a)-atoms.
F 's
the equation (T.l6) is not an atomic decomposition of norms of the For
F rs do not add up properly. 13
BeB,
B LEMMA.
For_ all.
j
l/2 |f*cf) t (y)| | 22dydt/t] dydt/t] l/2 .
Be 8
and all multiindices J,
C depends on J but not on B. Proof:
By the Schwarz inequality,
| x V ( x ) | = |f B
But
We must be more subtle.
< CSB|B|-(l/2Ma(J')/Q),
11^1. where
f, because the
let us define SB =
(7.17)
Hovever,
j
I
J
[ ? (y)f^,(y)XJij;(y"1x)dydt/t| B
XJi|;t(z) = t" Q " d(j) (X J ip)(z/t).
ti
t
Hence if we set
a = 2 Y | B | 1 / Q , the
expression in square brackets is bounded by
J
G
J
a
_ n -Q-2d(J) _ . I I -a.-\ ^-u.\ u / / ^/ — UOt — U -D •
n tf
Now we are ready to bring in the Lusin function
S.f. 9
For
kGZZ,
let = (x: S.f(x) > (2y)k}9
a K
|B.| for
B,,
i < j. This is possible by Lemmas J.lk
and T»19» which guarantee that there are at most finitely many balls of a given size in and
8. . Also, for notational simplicity let us set
F. = F_
S. = S,, . Then J
B
We estimate the first sum on the right by Lemma 7«17:
Vi • I
< C B*
B.
Si a}, by Lemma T«1T and the left-invariant
version of the Taylor inequality (l.3T)» we have
B*|l+(d(l)/Q)
since
|B.|/|Bi| < 1.
| B |-(l/2)-(d(l)/Q) | B |-l/2g
Therefore, let
« „ = (|B.|/| B j |) ( l / 2 ) + ( b / Q )
if
a.. = 0
otherwise.
i X}|dX n *
CMIS A fil P .
This completes the proof. #
(7.22) = 0
COROLLARY.
0 < p < 1 , cf)1,. . . ,(j)N,i|;1,. . . ,i|;N G S ,
Suppose
for 1 < j < N , a n d if I cfAij/Jdt/t = 6 " " 1 ^o
Suppose moreover that for 1 < j < N , where
M e l
J
P= 0
ij3_ p-admissible a n d M > 0 7 2 .
infinity a n d S . f G L P cj>J Proof:
U
for a l l P 6 P r - i r -
If f G S'
for 1 < j < N , t h e n " "
By Theorem 1.62, there exist
in t h e sense o f (1.5-91 ) .
fGHP,
vanishes w e a k l y at a n d P P ( f ) < C E^lls .fllP. " p 1 cj)J p
1 N' 1 N' $,..., ,^ ,...,¥ G S
satisfy the hypotheses of Theorem 7-11, such that each 4> *n
for some
nGS
and some
IIS fII < Clls .fit , p ^ $k p "
j G {l,. . . ,n}.
$
which
is of the form
By Corollary 7*6,
so we can apply Theorem 7-11.
#
For the remainder of this chapter we assume that
G
is a stratified
group, and we investigate the Lusin and Littlewood-Paley functions associated to the heat kernel
h
on
G.
For
j = 1,2,3,...,
let
Then
(7-23)
U (j) (x)P(x)dx = jh(x,l)(-f.)jP(x)dx = 0
In particular,,
U ^
= 0
for all
j.
If
Sometimes it is convenient t o express of the heat semigroup
H, .
for
f e S ' , we set
g.f and S.f directly in terms ) whose maximal functions are in
Section B we show that for the purposes of
H
P
L . In
theory the class
S
of
test functions can be enlarged to include certain Poisson-type kernels, thereby making the connection with harmonic functions. Section C we investigate the H spaces.
Finally, in
behavior of Poisson integrals on symmetric
The Poisson integral on a symmetric space is of the type treated
in Section B only if the symmetric space is of rank one.
The study of the
general higher rank case (more precisely the questions related to "restricted convergence" of Poisson integrals) has a long history.
Here the main
feature of the problem is that we are dealing with approximate identities fashioned out of directions.
$
which are only slowly decreasing at infinity in some
This makes the analysis quite delicate, as can already be seen
in the early work of Marcinkiewicz and Zygmund, (see Zygmund [l], Chapter 17)* where n
E
is considered as the (distinguished) boundary of the product of
upper half-planes.
2kQ
A.
Temperatures on Stratified Groups
In this section we assume that
G
is a stratified group, and we
study the boundary "behavior of solutions of the heat equation on
Gx (O,"5).
(3 +L)u = 0
In addition to the facts about the heat kernel presented in
Chapter 1, Section G, we shall need the following maximum principle for 3 +L9 t
due to Bony [l]: (8.1)
PROPOSITION.
Let_ ft be an open set in
U G C (ft) be_ a_ real-valued solution of u
(3 +L)u = 0
GxR,
and let
cm ' ft. Suppose that
attains its supremum or infimum on ft at (xn,t ) G ft. Then if
Y : [0,1] ->- ft is any smooth curve such that Y'(T)-3, < 0 t where
for
0 < T < 1 -
b < 0 ) , then (8.2)
(that is, Y ' ( T ) = Za.(Y(T))X. +b(y(x))3, ,] J t
U ( Y ( T ) ) = u(x ,tQ)
COROLLARY.
y(0) = (xn,t ) and
The heat kernel
for
0 < T < 1.
h(x,t)
is strictly positive for
t > 0. Proof: would have
We know that h(x,t) = 0
h(x,t)dx = 1. (8.3) u
h(x,t) > 0.
for all
xGG
If and
COROLLARY.
(3 +L)u = 0
Suppose
GxE
and
on_ ft which is
supn|u(x9t)I = sup_n|u(x,t)I. ii5
u
we
t < t , which is false since
Suppose ft is a bounded open set in
continuous on ft. Then ——
multiplying
> 0
#
__ __ (complex-valued) solution of
Proof:
h(x ,t ) = 0 with t
did
|u(x , t Q ) | = sup |u(x,t)|
be a constant of modulus
1
where
(xQ,t )efi. By
we may assume that
u(x_,t ) > 0.
For any 8ft,
Xeg,
and
the curve
Re(u)
Y ( T ) = (x~ exp(xX),t ) eventually intersects
is constant on this curve, so
|u(x_,tn)| < sup. |u(x,t)I. U
U
—
oil
The reverse inequality is trivial. # If
u
function
is any continuous function on
u*
on
G
Gx (0,°°), we define the maximal
by u*(x) = sup
_1 2 |u(y,t)|. |x y| 0
Then
fx(xy 11\{ xy x)h(y,t)dy.
+ 1 |y|). Then there exists
as_ e •> 0,
and
u(x,t) = H.f(x).
(9+L)u=0 t such that HP
Consequently,
set of boundary distributions of temperatures
on
u
Gx(o,°o)
and
u(',e) •> f In is precisely the
oil G x (0,°°)
such that
U*GLP. Proof:
Given
by Lemma 8 . 5 - ) Clltj)ll/ x
eS9
let
F(t) =
We must show t h a t
f o r some
C > 0
and
lim
N6E
J
u(x,t ) 0
as
t •> »
F (k - l} (t) =
for all
k,
t"Q/2p.
so for
k > 1,
252
Let
N = [Q/2p]+l.
equal to
N,N-1,...,2
in (8.10) for
If
If
Q/2p
is not an integer, taking
k
successively
in (8.10) and using (8.9) to estimate the integrand
k = N,
we find that
Q/2p is an integer, the same argument yields
|F"(t)| < Cf!lll/
fl J F"(s)ds| < C"II(J)II(2N) (1+ |log t|) In either case, Ff
is integrable on
(0,l),
F(0) = F(l)-linL
exists and is bounded by f e5'
of
such that
Next, given Since
u*eL
that
Ff(s)ds
n
lim _^ _ u(-,e) = f.
e > 0,
let
v (x,t) = u(x,t+e)
and
w (x,t) = H, (u( • , E ) ) (x).
we have
£
P
U(',E)GL ,
and
v
and
w
u(-,e)eCL
q = max(p,l).
w , we see that for any
|v (x,t)-w (x,t)| < 26
Moreover,
(t < 1 ) .
Cll(j)ll,2 «,. This completes the proof of the existence
we can apply Lemma 8.7 with Lemma 8.7 to
when
are continuous on
by Lemma 8.6, so that
Applying Lemma 8.6 to
6 > 0
t > T
Xi
there exist
or when
u
T,R > 0
0 < t < T
|x| > R.
Gx [0,°°) and |v - w | < 26
£
everywhere. u(x,t) =
and such
and
v (x,0) = w (x,0) = u(x,e), so it follows from Corollary 8.3 that £
£
Since lim
6
is arbitrary,
v (x,t) =
£ ~ ^ U £
and we are done.
#
'
so
£
P
*^
lim
v
= w . But then
w (x,t) =
E - ' - U E
lim
H (u(-9e))(x)
£ ~ ^ U b
£
253
B. The
H
integrals. to
H
Poisson Integrals on Stratified Groups
spaces on TR
"were originally defined in terms of Poisson
Since the Poisson kernel does not belong to
S,
this approach
does not fall within the scope of our theory so far.
shall now show that
H
However, we
can be characterized by versions of the Poisson
integral in many cases. We begin by introducing a class of test functions which will include the Poisson kernels we have in mind. We adopt the following notation throughout this section: function on
G,
$ will denote the function on
$(x,t) = , (x) = t t x
and
t
(x/t). We observe that
of degree
-Q:
if
is a
Gx (0,°°) defined by $
is jointly homogeneous in
(rx,rt) = r~Q$(x,t). 00
Let (i)
$
K
denote the class of all
and all its derivatives in
(Gx [0,«>))\{(0,0)}, and (ii) since if
C
x
functions
and
$(x,0) = 0
t
t ->• 0,
for
containing the origin.
uniformly for
G
such that
extend continuously to
(J>(x) vanishes to infinite order as
to infinite order as
on
x + 0.
Clearly
x -> °° then x
S a R9
(x/t) vanishes
in any subset of
The other examples of functions in
R
G
not
in which we
are interested are the following. (l)
Let
is a unique continuous on
G
be a stratified group with sub-Laplacian
(J> G R G,
with the following property:
if
f
J
f(y)eR, for
2
$((z,t),r) = P((z,t),r ).
(z,t) = P((z,t),l):
then
255
(3) A formula very similar in appearance to the above Poisson-Szego kernel holds for the Poisson kernel associated with any symmetric space of rank 1.
(See Helgason [l], p. 59)• We omit any further details but state
here that the resulting
is also in
R.
We return now to the general situation. (8.11)
PROPOSITION.
If
(j)6R, then:
(a)
|Y 9^$(x,t) | < C
(t + |:
(b)
|YI(j)(x) I < C (1+ |x| )~^
( c \) (±j> GT L1 . Proof: t -> 0:
(a) follows from the homogeneity of
$
and its smoothness as
in fact, we can take C
I . = SUp t + |x|=l l ^ * ( x , t ) | . J
Next, we observe that since since
Y $(x,t)
is smooth as sup
$(x,0) = 0 t -> 0
we also have
for
Y $(x,0) = 0,
and
x / 0,
|y|=l,O 1,
the __
which annihilates
(l < q < °°)
S. )
have an
R'.
The proof of Proposition 8.11 (ID) shows that
is independent of
There exist P
Remark:
to
is an element of
obvious interpretation as elements of
(8.12)
R'
NGl
and
C > 0
such that for all
(p,00,a)-atoms
f
we have
where
Mf(x) = sup{M f(x) : li,o 1 » < 1,
and ll^ll^ Q, < 1 for |l| < N } .
257
(HP n L°°) c R'
(b) _If 0 < p < °°, the natural inclusion to &_ continuous injection of IIMfllP < CpP(f)
such that N = 0
when
Proof: Theorem 2.9: set
H
into
for_ all
extends
R' . Moreover, there exists
feHP,
where
Mf
C > 0
is as above (with
p > l). The proof of (a) is essentially the same as the proof of we assume that
f
is an atom associated to
B(r,0),
b = min{b' GA : b' > a}, N = the smallest integer > b,
B = B(2yg r,0). We estimate the integral of
(Mf) P over
B
and we
and by using the
maximal theorem (2.1+) (which is applicable in view of Remark 8.12), and we estimate the integral over
B
by subtracting off a Taylor polynomial from
(J>. The estimate for the remainder which we need is the following: If at
x
(J> G R
and
xGG,
of homogeneous degree
Let us prove this.
But if
let
|x| > 2y3N|y|
a.
P
be the right Taylor polynomial of If
|x
> 2y$ |y| then
By the Taylor inequality (l.37)»
and
|z| < 3N|y|
then
|zx| > |x|/2,
258
The desired estimate is now immediate, and the rest of the argument proceeds as before. functions
In the proof of Theorem 2.9 we estimated the radial maximal M f,
estimates for
but a routine modification of the argument yields the same
M f;
Proposition 2.8. If
alternatively, one can prove the obvious analogue of
Details are left to the reader.
p < 1, part (b) follows from part (a) and the atomic decomposition
theorem by the argument used to prove Proposition 2.15.
If
follows from the maximal theorem (2.k) and Remark 8.12.
#
p > 1, part (b)
In proving Theorem 8.13 we did not use all the estimates in Proposition 8.11.
The full force of the smoothness as
t -> 0, however, will be used in
the following arguments, which lead up to a generalization of Corollary U.17. (8.1^0 decreasing
LEMMA. (i.e.,
There is a
C
function
|e(s)| = 0(s"N)
£
for all
on_ [l,00) which is rapidly
N ) , such that
and
s c(s)ds = 0 Proof:
Let
for all positive integers
w = e
be the contour which goes from
^
[l,°°), to
makes an infinitesmial half-loop around upper edge of the cut.
k.
, and consider the function
on the complex plane cut along the ray Y
c(s)ds = 1 1
f°° k
Since
f
1 1,
where
f(z) = exp(-a)(z-l)
0 < arg(z-l) < 2TT. Let
along the lower edge of the cut, and returns to
is rapidly decreasing at
°° along the °°, by Cauchy's
theorem we have
-i- f f(z) — = f(0) = e"1;
[ zkf(z) — = 0 for k > 1.
27Ti J
J
Z
Z
From this it is easily verified that we may take
C(s) = —
Im exp(-(Jj(s-l)1//l1)
(arg s = 0 ) .
#
)
259
(8.15) ip(x) =
r
c(s)$(x,s)ds J 1_
Proof: so that
LEMMA.
> 0
6 R
then
and
C
is as in Lemma 8.lU.
If
i|ieS.
Clearly differentiation under the integral sign is permissible,
i|i G C . We must show that
However, for any C
Suppose
Y \p is rapidly decreasing for all
N 6 l , by the smoothness properties of
$
I.
there exists
such that
We observe that since polynomial vanishes.
(y,O) = 0 Hence if
the term with
x ^ 0
and we set
k = 0
in the Taylor
y = x/|x|,
t = s/|x
(s > l ) , we obtain YI*(y,t)
where
R (x,s)| < C (s/|x|) H . |R
But from this it follows that
|-Q"d(l) {C°EN(x,s)c(s)ds = which completes the proof.
#
As in Chapter h, a function approximate i d e n t i t y
if
U = 1
I
j e R w i l l be called a commutative and
f # = S
X>
(x
)
in his Lemma 6.2.)
The limiting relation (8.IT) therefore says precisely that for all
xGN
as
r -> 0,
when
f
is to study the maximal function
M
is bounded and continuous. on
N
(8.18)
Our aim here
with the object in mind of
obtaining almost-everywhere convergence results for properties of
f*cj) (x) ->• f(x)
f e L . We summarize the
(j) which we shall need in the following proposition:
PROPOSITION.
(a)
0
for_ all
x,
and
(b)
0,
b > 0 _
1 < j < n.
such that
for each
U(x)dx = 1.
j
x. for_
263
(d)
There exists
e > 0
such that
(e)
There exists
C > 0
such that
with
(l+ |x|) (x)dx < «.
(xy) < C are due respectively to Knapp
and Williamson [l] (Proposition 5-1) and Harish-Chandra [l] (Corollary to Lemma 4 5)• lc — ~\ f
as
r -> 0
for
fGC
.
Also, (i) implies that
1
|(x)| < C(l+ IxD" , so by (ii), + |x| ) (f>(x)dx < sup [(x) (1 + |x| )
which proves (d).
Finally, to prove (e), suppose
g ,gpGG.
H(g..g2) = H(g 0
K,
(J)(x) = e x p [ - 2 p ( H ( x
£^ = y
-1
,
normalizes
N).
Since
K(g 2 )
V c G
there
such that
|H(glg2)-H(g2)| < C
But
A
Then
g^ = x
-1
„ . ff
))],
for
g16V,
g26G.
so we o b t a i n t h e d e s i r e d e s t i m a t e by t a k i n g
26k
Our main result is the following: (8.19)
THEOREM.
Let
be a function on
N
satisfying the conditions
in Proposition 8.18 (which we shall refer to as properties (a) through (e)). Then there exists from
HP
to. L P
p
< 1 such that the maximal operator U for_ p > p .
M (p
is bounded ——————-
The proof is rather lengthy, and we begin by making some simple 1 reductions.
First, since
°°
(f> G L , M,
is trivially bounded on
Theorem 3.3^-, then, it will suffice to consider
p < 1,
L . By
and for this it is
enough to show that there exist p llM.fll < C whenever p > p^ and p - p 0
< 1 and C > 0 for p > pfi such that f is a (p,°°,0)-atom. (We shall need
no higher moment conditions on
however, see the remarks following
f;
Corollary 8.25.) Moreover, by composing with translations and dilations we may assume that
f
is associated to
denote a function supported in Also, we fix
Jel
B(l,0).
B(l,0)
In short,
such that
large enough so that
2
f will henceforth
IIf 11^ < 1
> 3y3.
and
f(x)dx = 0.
Since
IIM fll^ < HfllJI^IL < 1, we have (M.f(x))Pdx < 2 J Q = constant,
(8.20) J
'x| 2 . Let |x| > 2
x -> < x > and
be a
1 <
C
< 1 + |x|
cf)Z(x) = Z(|)(x), Thus we wish to estimate
function on when
G
|x| < 2.
cf>Z = U Z ) t ,
M f = M,f.
such that For
=
|x| when
zeffi we set
M Z f = M z f.
265
(8.21) S
LEMMA.
Let
S = {x : |x| = 1}
given by Proposition 1.15» and let
e
and
a = the surface measure on
be_ as_ in_ property (d).
For
x T G S,
set fi(x') =
Then
(S,a),
ftGL
and there exists
ft(x' )
for
such that
x i- 0, x 1 = x/|x|.
By property (d) we have r
fi(x!)da(x') =
r°° (j)(rxf )r
(8.22) ft(xf ) >
.,
(sxf)s *0
+£
r drda(x') =
x = rx 1
Also, by property ( b ) , if
Thus for
C > 0
£
(j)(x) < C ( l + |x| )
Proof:
(f)(rx')rQ'1+£dr.
d>(x) x
(r > 0, X ' G S ) ,
d s > (J)(rxf) ~
s^~ -^ 0
+£
d s = (Q+e)~
|x|
1,
On the other hand, if we set
6(Q+e)
we have
(by (8.22)), so for
(8.23) Re z < e
LEMMA. (where
There exists e
C
> 0,
independent of
is as in property (d)) and M Z f(x)dx < C .
2j J,
x
2^ < |x| < 2^ + 1 ,
and
Ixw"1] < 1
denotes the characteristic function of
we have
B(l,0),
MZf(x) < C
and thus
MZf(x)dx < C ]_ I
x(xw
h Jj-1
= C
vHfi(v')dw
= C I
r -1
(8.2U)
LEMMA.
independent of
f,
Let
b
j
«(wf )dcr(w' ) S
fi(w')da(w!),
= C log 8
and this is finite by Lemma 8.21.
dr
#
be as in property (c). There exists
such that i_f Re z = -(Q+b+d)
MZf(x)dx
and
j > J,
C
> 0,
268
Proof: 1 < i < n,
Since vGN,
and
is homogeneous of degree
1
for large
x,
for
Re z = -(Q+b+d) we have ZY.(J>(v)|
N-Q-d -Q-d.
Hence 4>*)(v)| = t "
i
|(Y14)Z)(v/t)| < C'|z|(t+ |v|
-Q-d.
so by the mean value theorem (1.33),
Now suppose implies
|x| > 2
(> 3 Y 3 ) ,
|vx| > 2|x|/3,
so if
|X" y| < t,
and
|w| < 1.
t < |X|/3Y,
IX" 1 /! > (2|x
t+ |vy| > |vy| > whereas if
-Q-d. (t+|vy|) \
i
-1
t > |X|/3Y 9
t+
Thus, for all
|vy|
> t >
|X|/3Y-
t > 0, „
d.
r \v\ 1 lxl
-Q-d. x
Then
|v| < 3|w|
269
Finally, since
f = 0,
for
= sup
|x| > 2
ve have
x y S 1 x|
J,
M Z f(x)dx < C |z| I
I
Proof of Theorem 8.19:
For
j > J,
r~ 2 dr < C Iz|2~
let
and for any measurable
T : G -> (0,«>) and any measurable
that
for all
|x~ n(x)| < T(X) (F
xGG,
(z))(x) = ( z - l - e ) ^ , x(
Lemma 8.23 shows that
bounded in norm by
T \X }
F
(z)
is an analytic
X.-valued
function of
Re z < e which is continuous up to the boundary and C . Also, by Lemma 8.2U,
IIF (z)llv < C 2"^ T,n X. - i
for
Re z = -(Q+b+d).
Therefore, by the three lines lemma (cf. Stein and Weiss [2], p. 180), IIF
T
(0)llv
,n
such
set
T , T)
in the half-plane
n : G ->• G
< C^"6Cn62"^e,
A. —
(j
1
where
9 = e/(Q+b+d+e).
z
270
Since this is true for all
T,n,
we have M°f(x)dx < C2" J 9 .
Let us now take
p
= Q/(Q+6):
then, for
p
(M°f(x))Pdx = Zj j >2 J
< p < 1,
(M°f(x))Pax
2 J
lk6
[ ] p , 13.
-
M , 62.
M ° 6 2 . M H L , 67.
Sets:
I I 5 158.
f*,
13.
f*g, 15.
M ? v 9 70.
| | , 158.
m U
r! »
1
^^*
' «p' p P ^ , 76. u
5
ll4
9-
t, 18.
B(r,x), 8. ffi, 1. E, 1.
| |, 8.
M , ^ , 70.
» '' (s)> 2 1 2 » hl,3)> 2 8 ° - " "(N)'35 u u; f a , 1U1. v ^ a > 1U2. v«, 157. pP, 76.
Other operations on functions: ^ f , 13.
T
s . , 2U1. J
Norms, quasinorms, seminorms: 11
G* 218.
J
A, 2k.
E, 1.
E°, 1.
|E|, 10.
H, 1 .
B , 1.
28U
Spaces of functions and distributions: n UQ?
19 A.d.
p^ U
^
"19 , 1 ^ .
C k , 33.
H P , 75.
P a , 23.
P^SO, 23.
weak L
P
5
Sub-Laplacian:
13.
Om
00
f C
,
n°° 0Q9
H P , 75. q5a R, 253.
r^ , 158.
L, 55.
TO 1^.
Om
BMO, lk6. no Id.
a
n U^^,
C(ft), 12. 1 iiP 14d.
L p , 12.
H , 158. ex
R», 256.
S, 35.
f^ , 158.
01
P 0N,
C , 12. "1 S 7 l>f.
W , 158. ex S', 35.