Lecture Notes in Mathematics A collection of informal reports and seminars Edited by A. Dold, Heidelberg and B. Eckmann,...
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Lecture Notes in Mathematics A collection of informal reports and seminars Edited by A. Dold, Heidelberg and B. Eckmann, Z0rich Series: Scuola Normale Superiore, Pisa Adviser: E. Vesentini
202 John Benedetto Scuola Normale Superiore, Pisa/Itatia University of Maryland, College Park, MD/USA
Harmonic Analysis on Totally Disconnected Sets
Springer-Verlag Berlin.Heidelberg. New York 1971
AMS
Subject Classifications (1970):
43 A 45, 4 6 F xx, 42 A
48, 42 A 72, 42 A 36
I S B N 3-540"05488-X Springer Vertag Berlin • H e i d e l b e r g - N e w Y o r k I S B N 0-387-05488-X Springer Verlag N e w Y o r k • H e i d e l b e r g • Berlin
This work is subject to copyright. All rights are reserved, whether the whole or part of the material is concerned, specifically those of translation, reprinting, re-use of illustrations, broadcasting, reproduction by photocopying machine or similar means, and storage in data banks. Under § 54 of the German Copyright Law where copies are made for other than private use, a fee is payable to the publisher, the amount of the fee to be determined by agreement with the publisher. © by Springer-Verlag Berlin • Heidelberg I971. Library of Congress Catalog Card Number 77-163741. Printed in Germany. Offsetdruck: Julius Beltz, Hemsbach/Bergstr.
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PREFACE
These and
Scuola
totally gin
to
notes
Normale
properties
the
of
is
the
background
a spectral
and
problems
[43]
, the
[31,
Vol,
2]
a deeper
many
of the
cussion
can be
study
• I have have
change.
pact
abelian
groups
ings.
thoughts ject
or
matter.
Brownian
important
masterful
new
are
developed
as
the
include
some
basic
with
standard
setting
For
notes,
for
of
intermediate
of K a h a n e
are
and
treatise necessary
other
along
with
and v a r i o u s
field seven
Appendix
that
extensions
included
two
it b e g i n s
Many
on
are
which
hand a dis-
with that
a self-contained with
one
the
latter
topic
attractive Katznelson
although
admittedly
refreshing
or
become
a
are
more
or
locally
certain
one
for
problems
another
groups
approxi-
is n a t u r a l l y
since
com-
the
in-
Galois
disconnected.
self-explanatory are
really
not
of
meant
extraneous
elementary
definition
and m e a s -
and
of the
available
are
[22]
problems
totally
of text
be
whereas
is
appendices
techniques A is
might
on [ 0 , 2 w )
structure
sections
which,
on p r o f i n i t e
than
this
Edwards
of the
different
analysis
and p a r t i c u l a r l y
I thought
example,
simpler
as u s e f u l
motion;
work
on the
here,
analysis;
is on [ 0 , 2 w ) .
conceptually
further
also
motivation
general
[54]
functional
Fourier
these
effect,
generally;
are
book
Helson
problems.
of d e t a i l
are
synthesis
of m a n y
questions;
deal
and
and to be-
pioneering
and Ross'
various
if e v e r y
is the
monograph
arithmetic-synthesis techniques
known
classical
of H e w i t t
discuss
spectral
source
a good
infinite
I have
the
the
included
group.
There
With
of R.E.
in the
of
here.
and
problem
books
theorems
terested
and this
of M a r y l a n d
analysis,
is not
in the
more
important
it
found
Further,
less
arithmetic
sections
a stultifying
meaningful
mation
of
major
are
The
is to
in h a r m o n i c
is p r e s e n t l y
Kahane's
concurrently
presentations
could
relevant
as w e l l
read
[57]
area
prerequisites
theory,
set,
at U n i v e r s i t y
purpose
in p a r t i c u l a r ,
research.
, and
of the
between
given
The
arise
presented
fundamental
The ure
this
I have
Pisa.
which
synthesis
much
Salem
for
sets;
material
Salem
and
sets
relations
such
set
lectures
Superiore,
disconnected study
Kahane
are
sub-headas
after-
to the
treatment
a probability
sub-
of space,
VI
develops This
the W i e n e r
inequality
portant
in the
In A p p e n d i x existence basic
process,
and the t e c h n i q u e s of h a r m o n i c
analysis
B I give
a leisurely
account
of non
spectral
and p r e r e q u i s i t e s , only
harmonic
synthesis
analysis
(outside
subset
(in c l a s s i c a l
The r e m a i n i n g (hopefully)
problems
since
of the terms)
sections
motivation
for
the
further
is u s u a l l y
has
disconnected
sets.
t h e o r e m makes
the
up n o t a t i o n
standard,
it re-
of e l e m e n t a r y
a closed totally
§ 2 gives
a general
arithmetic-synthesis
fundamental
im-
t h e o r e m on the
a knowledge
group E / 2 ~ Z ) .
inequality.
have b e c o m e
§ 1 sums
B, E is always
to deal with
present
Malliavin's
meaningful.
of A p p e n d i x
motion
of M a l l i a v l n ' s
our n o t a t i o n
circle
Salem-Zygmund
on t o t a l l y
sets.
a s c a n n i n g by the r e a d e r who
disconnected proach
and,
the
from Brownian
study
arithmetic-synthesis
quires
and p r e s e n t s
results,
ap-
questions.
techniques,
and
study.
J.B. , 1970
This
w o r k was
che"
of Italy.
supported
in part by the
"Consiglio
Nazionale
delle
Ricer-
TABLE
from
CONTENTS
i
Preliminaries
i i
General
1 2
Synthesis,
1 3
Distribution
1 4
Properties
i 5
Approximate
2.
Pseudo-Measures
2.1
Structure
2.2
Measures
2.3
Representation
2.4
Measure
3.
A Characterization
3.1
Introduction
3.2
Hyperdistributions
3.3
Riemann's
3.4
Pseudo-Function
4.
Independent
Sets
4.1
Independent
and
4.2
Examples
4.3
Arithmetic
4.4
Groups
5.
Kronecker's
Theorem
and
Kronecker
5.1
Dirichlet's
Theorem
and
Statements
5.2
The
5.3
Infinite
5.4
Wik
6.
Independent
6.1
Introduction
Notation
and
Analysis
Definitions
Arithmetic,
and
and
for
Inte~rati0n
Fourier
Uniqueness
Theory
Analysis
..... i
..........
Sets .....................
Theory ............................................ of
Identities
of
Totally
Associated
Disconnected with
Uniqueness
Arithmetic
Progressions
of
..............................
and
Non-Helson
Independent
Sets
and
..................
and
Independent
Sets of
Theorem
....................... Kronecker's
Theorem
and
Estimates
of
.....................................
Multiplicity
............................
...............................................
80 87
93
. . . . . 93
Sets ....................................................
Sets
69
S e t s . . . . . . 73
Sets ............
Related
59
69
Sets . . . . . . . . . . . . . . . . . . .
Symmetric
47 54
of U-Sets ....................
Progressions
40
46
........................
Progressions
29
46
Sets ................................
Kronecker's
Kronecker
...............
Principle ..............................
of A r i t h m e t i c
by
26
Sets .........................
Pseudo-Measures
Kronecker
Generated
20
...................
of P s e u d o - M e a s u r e s
Characterization
and
S e t s . . . . . . . . 20
........................
Distributions
Sets
16
Sets . . . . . . . . . . . . . . . . . . . . . . . .
of U n i q u e n e s s
Localization
Proof
Order
Properties
and
Disconnected
Distributions
of F i r s t
to
Totally
6
ii
.......................................
Supportedby
i
8
2~(F) ..........................................
Theoretic
Bohr
Fourier
OF
.. 103 112 120
124 124
VIII
6.2
Salem's
Theorem
6.3
The
7.
Helson
7.1
Equivalent
Definitions
7.2
Arithmetic
Properties
of
Helson
7.3
Uniqueness
Properties
of
Helson
7.4
Further
8.
Concludin~
Remarks
..........................................
159
A°
The
Process
..........................................
161
A.I
Probability
A.2
165
172
Existence
............................................. of
Rudin
Sets
.................................
Sets .................................................
Functional
Wiener
of
Helson
Analysis
Spaces
and
Sets
.......................
141
Sets
........................
141
Sets
........................
149
for
152
Criteria
Expectation
of
Helson
Random
Sets .........
Variables
.......
A
3
A
4
Gaussian
A
5
The
A
6
Homogeneous
Hilbert
Wiener
of
Chaos
A 7
The
A 8
Equivalence
A 9
Wiener
A
IO
Salem-Zygmund
A
Ii
Continuity Process
..........................................
Space
Measure
Variables
.....................
182
Wiener
Process
and
Homogeneous
Chaos ......
.............................................. Inequality
....................................
Non-Differentiability
a.e.
of
the
Malliavin's
Theorem
B.I
Malliavin's
Idea ............................................
B.2
Construction
of
B.3
The
Example
B.4
Tensor
B.5
Varopoulos'
Bibliography
Index
........................................
a Non-Spectral
Proof
Function
184 188 192
Wiener
B.
Algebras
177
..........................................
....................................................
Schwartz
169
179
the
and
161
...........................................
Process of
Gaussian
134
141
Independent Events .......................................... -c2x 2 e ...................................................... Variables
124
.....................
........................................
199
207 207 214 223
............................................
229
..........................................
239
....................................................
...........................................................
251
260
i.
Preliminaries
i.i
General Z is
plex
fined
and
the
of
ring
of
Analysis
Definitions integers,
respectively.
series
to
Fourier
Notation
fields,
vergent
from
is
numbers
L~(Z)
is
We
set
thus,
with
group
under
the
with
the
Banach
the
usual
space
compact
addition
quotient mod
2w
circle
ting
on
depending
measure
are
space
norm
of
the of
{a
real
and
com-
absolutely }ELI(z)
n
con-
is
de-
on
F
group.
on
B
group.
[0,2w)
. If
~:F÷~
is is
E
The
note
r I,@ j[
functions
right by on
F
hand
side
i ~ 2w < m ,@>
.
where
the
, E
group of
course,
As
such
we
shall
technical
(one
of t h e
Haar
norm
the
Banach
space
~
dual
Lebesgue Banach
@eLI(F)
is
f I@I ;
1
in
~(~,)d-~
JO
is t h e of
F
abelian
of is
~
and
identified
identified or t h e and
of) f I ,4 jr
integral
with
other
whim.
multiples
F
the
set-
Lebesgue Haar we
meas-
define
r2w
usual
LI(F)
with
t
2~
the
one
convenience
integrable i
on
also
use
constant
compact
subgroup
operation
is,
II@II
L~(F)
a locally
discrete
of
is
is
. F
JF the
LI(z)
a closed
r
where
of
EI2wz
I @ ~
and
~
Banach the
Analysis
Zla n I ;
dual
on is
a mixture
on
m
2wZ
~
~
topology
addition,
multiplicative
ure
and
Theory
be
F
is
the
Integration
Fourier
E
where
I{a n )11 1 and
for
and
LI(z)
complex
and
JF
of
Ll(r)
,
integral; space
of
defined
we Haar
to b e
also
de-
integrable
The
Fourier
series
of
ceLl(F)
is
^
¢(Y)~
[
¢(n)e InY
neZ where
¢(n) is the
{¢(n)}
C(F) tions
on
A(F)
is the
the
norm
set
where
Banach
the
Banach
of
12w J0 [2~¢ ( Y ) e - l n Y d y
of F o u r i e r
is the
F
z
CsA(r)
space
norm
space
coefficents
of
CsC(F)
of a b s o l u t e l y
is d e f i n e d
Banaeh
measures A'(F)
space
with
, the If
dual
norm
space
of
C(F)
~
continuous
is d e f i n e d
to be
convergent
Fourier
func-
series
where
[I~(n)I
is 2 ~ ( F ) ,
; and the 1 of p s e u d o - m e a s u r e s we
- valued
to be
II II
{a }ELl(z)
0.
of c o m p l e x
I I¢II A
The
of
;
define
the
Banach with
F({a
n
space
space
of b o u n d e d
dual
norm
I I I IA,
}) ~ ¢
where
of
A(F)
Radon is
n
¢(y)
~ [a
e inY
n
Therefore
we have
the
diagram
LI(z) ~ A(r) co
L (Z) ~'
where
F'
phisms,
is the and
adjoint
map
of
F
n
are
isometric
isomor-
where we
F({a
}) ~ ¢ . We d e s i g n a t e n the representation
define
F'TeL
E
as
(Z)
{T(n):neZ}
; and
thus
2~ZT(n)a -n
with
Fourier
coefficents
^ T(n)
since,
1 '"~;
~
~
LP(r
of
-iny>
formally,
-in7>
2W
tions
O,BneZ
sub-
if
and
E
is
a Dirichlet
set
if
Ve>O ~neZ
such
that
sup ll-elnTl o
is
strong
for
iny
In I-*oo
E
n.J = 0
if
n
O
if
independent
.
lim
for
O,njcZ
yl , • ..Tn eE,
collection
subsets is
all
=
sup n
IT(n) I
We'll
see
is the
in
case
§ 3 that if
and
E
only
and
E
is
a U-set
these
uniqueness
ty
it
if
is not
1.3
in t h e
let
wide we
a U-set,
Distribution We
ly
notions
is not
a U-set
in t h e
that
E
it
is
~o(E)
a set
is
an M - s e t
of
strict
functions
, be and
the for
vector
space
O
for
I.i
if
~ -
,
that
supp
TED(F)
by
for
TeDm(F)
,
T
and
T'eLI(F)
then
~Y T
= ° +
i
Y
an
absolutely
continuous
representation Now,
theorem for
each
function; is
an
just the
as we
did
for
corresponding
we'll
extension
TED(F)
^ T(n)
we
see
of
define
1 ~ --
,
e
thus,
,
for
each
TcD(F)
, we
series,
^
T ~ ~ T ( n ) e InY Y
The
following
neat
representation
Riesz
theorem
is
due
to
L.
Schwartz.
have
il
Theorem
1.2
a.
If
TsDm(F)
then
T(n)
=
O(Inlm),lnl
+
~
,
and ^
SNT
converges
in
D(F)
b.
to
If
K
[ T(n)e inY InI~ N
T .
{c
n
}~ ~ --
satisfies
:
e
O(lnlm),lnl
+oo
n
then
[ c e Inl~ N n
iny
converges
in
D(F)
to
TeD(F)
with the p r o p e r t i e s
^
that
T(n)
= c
for
n
Obviously thing we'll note
that
have
if
all
n
Theorem more
TeD(F)
and
TeDm+2(F)
1.2 gives
to speak
us an i m b e d d i n g
about
A'(F)C-~D(F)
in a d i f f e r e n t
has the p r o p e r t y
way
in
, some-
§ 2 . Also
that
sup N
TeL~(F)
then
and
IITII~ ~ sup
lls,Tti=
•
N
l.h
Properties
of
le~(F) ¢eC(F)
is p o s i t i v e ,
is n o n - n e g a t i v e
~O
for
solutely
continuous
CeL~(F)
(that
all
~(r)
TeD(F)
is,
on
and with
~
that
is,
F (recall
the
CEC~(F),¢~O respect
k>_O , if result
, then
to p o s i t i v e
is i n t e g r a b l e
with
CeC(F)
;F
~0 from
§ 1.3
Te2~(F)). Xg~(F)
respect
to
whenever that
~s~(F)
if there X )
if is ab-
is
such that
for
12
This
is
equivalent
and
{b
to
saying
. ~s~(F)
}~__ ~
such
lim [ITT~-~ll. = 0 , where y -~ 0 1 discontinuous if t h e r e is { Y n : n
is
Y -- i , . . . } C r
that
n
co
i
(1.3)
~
Now,
assume
=
¢
[ b n 1
is
~
y
on
C(F),~Ib
a Borel
measurable
I0,
and
on
ycF
A(F)
K~_V
C V
, open,
then
3
¢EA(r)
.
, and
V
is a n e i g h b o r h o o d
of
such that
~ = 0
and t h e r e
in
is a n e i g h b o r h o o d
W
on
of
- ~(y)
~V
y
such that
= ~
on
W
Notes §l.1
We refer
to
§1.2
We refer to Appendices
§1.3
[ 90, 53;
Chapter 22,
I, If,
We r e f e r to
[22,
r e g a r d to T h e o r e m for e x a m p l e ,
f'=6
Chapter
III;
o
-i
15.7;
43,
90, C h a p t e r s
Chapter 1.3
i ]
12;
and
57,
5, 7 ]
Chapter
8 cT~(r) Y
where
Chapters
f(y)=~
We r e f e r to
[ ii;
22,
Chapter
§ i.~
We refer
[ 22,
43,
85,
to
90 ]
12; .
98 ]
,¢>-¢(y))
With note that,
Y ' 1 iny e in
bounded variation. §1.4
• 1.7;
(0
show
this
with
a
Sets
E
is t o t a l l y
disconnected point
standard
there
and
E
since
is
Cantor
not set
discon-
would C
be
then
necessarily example
in
at conof a
minute.
Remark
i.
nected;
Generally,
for 2.
for
all
hood out
Recall
if
if it
3. only
if
Example symmetric {~k
and
of
that
only
example,
xeX
U
(Lebesgue)
x
a line
that for
such
a
T2
a
segment
T2
every that
in
0 E
2
topological neighborhood
U~
space
measure
X
N is
and
U
compact
sets is
are
space
X
is
N
of
x
there
is
open
then
it
and
is
disconnected
(e.g.[35]
).
It
is
to
xCr
is
totally
of
Cantor
that
discon-
O-dimensional is
if
a neighbor-
closed.
It
O-dimensional
totally
see
totally
connected.
is
easy
not
turns if
disconnected
if
and
and
{~. X = F
2.1
We
set;
: ~k e ( O ' ~ ) }
now we
define
shall be
a certain
frequently
given.
type
use
such
sets
Set
E1
EIHE l
~
iV
2
where
~l
_:
[o,2~
i
12
:-
] I
[2~I i(r)Co(r)
fact
that
a continuous
,
is dense
in
imbedding.
A(F)
CI(F)CA(F)
is B e r n s t e i n ' s
classical
re-
(e.g.[3]).
To show the
continuity
of the
imbedding
ci(r)
(2.9)
the
where
domain
and the range We next
observe
$n' + @ By the
standard
space C 1 (F)
that
vergence;
space
calculus
the
if and
topology
the u s u a l
is c o m p l e t e
in fact,
uniformly
has
{$n}
4'
given
topology
with
the
identity
by
I1¢11A+11¢'11 ~
in
exists
(e.g.§
map
in this
I I I IA and
1.3).
I 1411 A +tl4'll~
the
is Cauchy
Cn ÷ ~
result
consider
ci(r)
÷
has
first
topology
as well
con then
as pointwise.
4' = n
~hus The
II~-~'ll~ identity
+ ll%-~ll map
the
(2.9)
A ÷ o .
is o b v i o u s l y
open m a p p i n g
theorem
a continuous
there
is
K>0
bijeetion
so that
such that
for
all
cEcl(r)
I1~11 A
in p a r t i c u l a r , b.
Let
CEA(F)
+
I1~'11~
CI(F)~A(F)
and define
the
:Kll~llc~
;
is a c o n t i n u o u s
approximate
imbedding.
identity
~
:
r~ s
Clearly,
¢ ~ @ E
c
is
2w-periodic
s
since
j
g --Tf
=
2~
by
•
30 tg ,~(2~+'y-.1,)~ l "~- e
i'e
e¢~
¢(V)=
1 *(Y-X)*~(X) ) -¢
dx =
(t)dl
= 9 ,,~,%(2Tf+'y)
rW
Since
$¢*
¢(Y)
Considering
=
I
¢(Y)~¢ (Y-k)dl'
A(F)C_A'(F)
we h a v e
~e ~ C e C ~ ( F )
and t h u s
@EA(F),
for
F({a
~e*
CsA(r)
}) = ¢ , n
* @,~>
O
and
it is e a s y
thus,
-n
Yn
(n) i =
Further,
g
i ]__~
fw
to see
since
y)e-inYdyl
that
@
e ln'(~C~(r)
£
0
Ifl<E -G
+
)>0
on
is
a.e.
a consequence
of
K
(measurable
or
are
; this
f = 0
m(X
)>0
C + ~- - X+,
C
sets)
(or C
so
that
by
both).
X
such
of
C
that
C + ,C --
= 0 = m(X_-C_) some
= -i
on
C_
neighborhood C
,~
; further
= 0
on
disjoint
some
take
4+(0)
:
I
neighborhood
= 4+(1)
= 4_(0) =
.
f
--rO,ll-~
0 ~
Then
J
and
{tsGE:f(t)
R = 0 -
represent
on
and
~e C kk , y
we
s 5
since since o
I¢
j
supp
~,
~(t)
= 0
,9'
= h
some
(2.13)
CsC
fixed
and
h
-- @ - ¢ o S e H k
supp
~o
C (k,y),¢(t) --
when
ty hand
f
the
, and
,y
that
= 0
take
by side
fact
the of
0
s~C
in
definition (2.12)
,y k ck,y of
is
C
oj
Further,
C
such
as
@ =
where
c
a constant
of
distributionally,
(k,¥)
k HX, Y # A
any
for
l,{d
is
= d
have
n
= o{]~-JJ,lnl
÷ ~
l n l
, and,
as
we
saw,
f~L2(r)
to
unique
and n
}~LP(z) n
extends
= A(r)
d
Thus,
gives
A'(F)
n
--
distributions
C I
well-defined.
(2.15)
an
For
of
on
3$
By
the
Hausdorff-Young q 0 " i.e.
co
# 0
0
on
converges
P to
so t h a t , 0
on
since
P-E
n
1 o
o
-
r2~
2~
I
JO
m(P) x(y)dy
=
2~
q.e.d.
In 0
and
1916
Ranchman
Menchoff showed
showed in
1922
that that
there there
are are
perfect large
M sets
classes
of
of measure perfect
47
U-sets
(of
sets.
The
measure triadic
In which
we
result
3.2
this
refer
in
, F
is
erties
to
as
we
the
and
a U-set
space
of
we
I
thickens
result
closed
of
though
not
Rajchman's
U-sets
pA,eudo-functions;
in
we
the
work).
terms
of
mentioned
A'(E) o this
Pseudo-Measures
if
on
F is
on
{s:Isll}
refer
to
that
topology
on
plot
(a
characterize
and
on
. Note
induced
V
is
the
.
analytic
of ~
= O
I ~
chapter
§ 1.2
tributions
H
set
Thus
A hyperdistribution H + } where F is a n a l y t i c
finity,
the
Cantor
Hyperdistributions
+ {F
O-naturally).
[3] F
from
3 V C
~
. We
for
let
viewed
. Letting
, open,
~
be
as I~
and
F
of and
a leisurely
, when ~
a pair
analytic F
functions
, vanishing
the
space
explication the
unit
of of
circle
F ~
be
open
analytic
in
V
at
hyperdisthe
in (in
such
in-
propT
F)
, has we
say
that
and
< F+(s) if s~VN{s:Isll}
F
(3.1)
is
support
: I is
of
open,
~ V~B-
He~
to
be
H =
0 on
I}
well-defined.
+
Proposition
3.1
The
following
a.
Vi ~ " F
b.
~-supp
are
equivalent
, open,
H =
0
for
on
H = {F ,
F
}~2':
I
H = A
+ c.
Proof.
a ÷÷
b
and
F
and
c ÷
a
F
are
identically
are
trivial.
F-}
. The
0
+ To
show
a
÷ c.
Let
H =
{F +,
hypothesis
in a
says
that
F
and
48
-
+
are
F
F
to
same
entire
and
"F(~)
= O"
F
constant
entire
orem Thus
restrictions
F+
and
function
is
F-
are
--
B
F
and
B
vanishing
imply
F
and
, respectively,
identically
O
the
at
bounded "F(~)
of
=
so O"
that
by
implies
Liouville's F
~ 0
the-
.
.
q.e.d. +
Given
H
=
{F
, F-}ej)~'
and
set
co +
(3.2)
F
n
(s)
=
[
c
s
,
Isli
,
n o
-F(s)
=
-i [
n
o
-co
(3.2) -F R>r>O
makes
sense
analytic , and
from
for
the
Isl>l
Laurent we
s n
series
let
Cr,
theorem.
CR
be
To
see
concentric
this,
given
circles
of
radii
calculate co
-i
--
-F
n
(~)
~
[
as
[b
+
s
n
n
n
where
[
1 an
thus
a
part
of
n
=
0
(3.2)
for
all
where
n c
=
-
by
2~i
Cauchy's
= b n
F ({)
]CR
d~
~n+l
theorem
Because
of
and
(3.2)
we
we
have
the
second
write
n co
H~
(3.3)
~
c e
iny
n
for
Hc~/
lytically
; here
we
continued
have across
s
~ e F
iy
EF
, the
. Thus
if
Fourier
function
F + ( e iY )
F - ( e iY )
F
+
series
and of
F the
-
can
be
continuous
ana-
49
is
given
by
(3.3);
is
clear
by
the
usual
The
key
representation
Theorem
3.2
a.
the
fact
that
in this
calculation
of the
theorem
(3.4)
Ic
b° iny
that
Assume
(3.4)
n
we
get
Laurent
is
H~[c n einye ~
Given
case
a Fourier
series
series
coefficents,
-
. Then
Ve>0
3N
such
s>O
• Then
that
¥1nl>N
I < e
holds
for
all
3He 2
such
H~Cne
Proof.
a.
Given
s>O
and
consider
the
Zcnsn. IslN,l c
theorem
ICn II/n
have
lim
l~(l+e)n
of
E
follows on
(0,~)
positive),
Also,
b.
F
and
, analytic way,
with
radius
{c
n
}
only
(clearly
sup
(3.4).
Ic
II/n
for
the all
radius ~>0
,
of and
at
derivative
; this
with
infinity,
dealt
it
as
with
a function
in-
function
respect
l+e<e C
is
last
increasing
= i - hence
to
in
E is
the
of
~ = i/s
for
all
l~l0
ee = e
[c
n
s
n
analytic
satisfies for
Isl0
define
P (y) =
where
the
By T h e o r e m
series
on the
3.2 we have
right that
~e-@lnle inY
converges YHe~,
uniformly
¥~>0,
Hg#P
and thus exists
P cA(r) C A ' ( r ) .
, and
for
51
Hm[c
e inY n oo
i~P~
Looking
at t h i n g s
slightly
[Cn e-~Inl ein7
differently, -i [CnS
--
-F
(s)
=
if
H = {F +, F-}
, then
for
n
• Isl>l
,
-oo
we have
_F_(e~+iy)
noting we
that
have
e >i
Isl
=
and
ISl
so
= -i[ C n e - ~ I n l e inY
- le~+iYl>l
. Similarly,
for
-~+iy s = e
and
e
F
+ e-~+iy) (
= [c n
e-elnle iny
0
Since
c
,,inl ÷
= O(een),il
n
.
for all
, co
-~Inl 10
converges
uniformly
(and
F+(e-a+iY)
(3.5)
n
e
e
absolutely,
_ F-(e ~+iY)
~
,
then
in~
of
course)
~ ~)a(y)
= -co
is a c o n t i n u o u s ries
of
(3.5)
Proposition
Proof.
(3.6)
Let
function is the
3.3
on
Fourier
¥Tsi'(r),
T%[cne
F
iny
(in
series
¥¢~A(F),
, *(y)
= ~ane
-
fact of
c e n
an e l e m e n t F+(e -a+iY)
+
~>0
as a + 0
se-
52
Hence,
by
Lebesgue since ~Ic
dominated ~la
n
I< ~
convergence and
c
a (1-e-a[nl)l e ; hence, taking ao for which IIjK~ ~a]N
ITn(Y) I
J0
;
67
Now
let
Then
yeUl
there
~
is
be N
fixed such
and
given
g>O
.
that
O
(3.34)
! ITn(Y) I < C
sup n>N --
since
[ c e in 1k -- o ~nj~ E
rigorous
the
k
Y m aE
example
d o e s n 't i n t e r s e c t
intervals;
each
distinct
, and
elements
a contradiction.
hypothesis
geometrical
procedure
,
Y]'''''_
our
independent
neighborhoods were
hyperplane,
. By
each
-n
m
= O
the
SO
struct
=
n. # 0 . T a k i n g 3 ..... m} ~ k we h a v e
Ikq~ ik-1 (4,13).
-i
of t h e
that
crux
we
=
3
_~njYj
Yk>k -- o
one
one
n.
independent.
max{Injl:j=l
contradiction;
Remark
at
is
that
that
+ n y = O, m
to
Proceeding only
3
implies
m
J
con-
k dis-
blocks E 2k
in
dependent",
which and
i.e.,
hyperplanes. The
Proposition
following
4.4
well-known
Let
G~
result
F, m ( G ) > O
is
due
. Then
to
G-G
Steinhaus.
is
a neighborhood
of
O.
t
Set
Proof.
f(;~) =-
]XG(X)XG(k+y)dx J
Then ¢
f(X)
f
is
continuous
by
HSlder's
=
I
jGXG
(X+x)dv
inequality
and
the
fact
that
I I~ g-gl n a
as
a ~
O
, when
gcLl(F)
and
~
indicates a
Also,
if
f(1)>O
then
k~G-G
; this
is
clear,
for
if
translation by r I XG(I+~)dy>O
JG
÷ 0
i
a.
79
then Now,
f(O)
there
is
= m(G)>0
borhood
yeG ~ (X+G)
so t h a t ,
of
0
, and
and
since this
hence
f
is
does
l = y-z,
y,
continuous,
zeG
f>0
in
a neigh-
it.
q.e.d.
Proposition of
4.5
F . Then
Let
3
GI,... , G k
Yj.£Gj,
j=l,...,
be
k
non-empty
, such
disjoint
that
open
{Yl'''''
Yk }
subsets is
strong
independent.
Proof.
Take r
yl=~r, Now,
any
YiCGl
irrational
assume
that
which
and
such
is
of
that
{¥i'" "" 'Yj-I }
infinite
YIEGI
is
order;
in
fact,
just
take
y. sG. 1 1
and
.
strong
independent
where
jO
the ~ N>O
we
the
and
Yk.
~
J closed
Y and
as
Uk
and
I l~kI ll = 1 v. J
some
irrational
let
- 612)'
define
get
defined
is
is
I < £
~(E)
additive
y/w this
-iny
i ~ ~(6o+64+68
v3
elements
that by
property
E =
; mM~E
note
follows
Further
y
mYk.
and
(4.23)
we'd
classical
v I ~ ~(60+61+62-63),
theorem
thus,
open
N
form
dual
that
~I c I = 1 n 0
(4.23)
= C(F)
is
N
(4.231
with
a contradiction.
fact
such
is
limit
then
point
not
so t h a t
only
is
VmeZ,
additive.
Now,
by
J the is
weak dense
form in
F
With ization
of
tinct Without
Kronecker's and
elements
If
any
of
in P r o p .
J -
Nk-i 2
employed
in
§ 4.2,
{my:m=l,
2,...}
E = F
additive
E
k,
of
E
is
Nk
sets
we
on
4. 7 we
+ l,
additive
, and
. Also,
generality
measure As
to
theorem
get
the
following
slight
general-
4.7
4.8
Given
loss
thus
regard
Prop.
Proposition
Proof.
of
then
Yk
let
assume
E
; then
is n o n - H e l s o n .
{Yk'''''
NkY k} ~ E
are
dis-
M>O N
k
is
odd,
for,
if
not
we
place
our
{yk,...,(Nk-l)Yk} define
c.
j
-
{c.:j=l,..., j
~(~+i)
if
N
k
}
j = 1,...
such
'
that
Nk-i - - , 2
and
c. = 0 j
c.
j
-
for
4(~+i)
86
if
Nk-1 2
J -
Consequently
there
+ 2,...,
is
k
Nk
, again
o
as
in
Prop.
4.7,
for
which
MII~ k tl A, i li~ k El i o
o
where N
Uk
=
k
o
~ c.6. j=l J 3Yk
o
o q.e.d.
Example the
For
h.~
any
finite
sequence
Then
IIUnIll
there
is
= i
the
a subsequence
weak
~ i
that
~
then
~
if
topology.
F
=
{i,
n
y # 0
of
points
define
n
{i},
Example
h.h
it
Helson
is
open
as
there
are
many
U
Prop.
~.8
that
it
U
Further,
is
and
it
is
are
also
not
to
=
1 ~},
1
By
n ~(F)
the
Alaog!u
such ~ 0
and
and
clearly
theorem
that
F =
{0,
; in
~
m
~ n
fact,
I I~I I1 _< 1
that
because to
i,
~,...}
; consequently,
get
F3 =
whether
sets
and
= i
the
1 {~,
same
A 1 5' 6 } '
Helson
every
sets which aren't 1 {0, ~ : n = l , . . . } is
U
= ~F
}
then
again
proved
difficult
perfect
u({O})
can
1 {~,
F2 =
F
IlUl I1 = 1
'~>
~}
if
y
if
. Note
n
3'''''
we
F1 =
0
if we
Y =
I CkYk ' k=l
Yk
in
(4.24)
elements
n k0, apropos
is
our
relatively
equivalent
and
can be question (to
e) of
to
this
type
r/ss [0,
2w),
(r,s)=l,
approximation.
Proposition
5.1
a. for
Let
There
y/2w
are
be
irrational
infinitely
x
Proof. (where,
b.
¥e>0,3
a.
Let
we
- ~I
We
all
-~-) 2~
2w)
s2
,
many
rationals
i.e.
Iys(mod
Inv(moa
that
consider
operations
: OO
for
all
N>N
which
I r --27 j ( g 2 - g l )
and
that
real,
there
is
N
! < 6
such
"
that
O
i
~ j
i- -27 Thus
(5.6)
holds
ing
the
for
g
real
real
-
g
and
--
0
1 N ~g(ny) I < e N i
, and
complex
the
complex
cases
case
follows
by
consider-
separately.
q.e .do
Since linear
the
statement
independence
remarks
on
we
5.2)
shall
independence
make
before
only
follows
a number
giving
of
careful
with
some
hypothesis
of
supplementary
(to
statements
Kronecker's
of
§ 4)
theorem.
Remark if
i.
xeS
Let
SC
choose
E
and
n eZ
consider
such
that
SC
F
y ~ x+2wn
X
(5.8)
If
{w,
Xl,... , x
in
~
. Also,
in
E
then
independent
first
then,
by
part
of
(5.8)
hypothesis, Conversely,we
(5.9)
Let
the
E [0,
obvious
27)
way;
. Note
that
is,
that
X
m
}
{7+2Wko, X l + 2 W k l , . . .
The
in
is
each
if
is
{7,
r
is
strong
X l , . . . , Xm}
is
in
of
then
independent
strong
Xm}, as a s u b s e t
E
independent
F , is
strong
.
obvious. n.=O J
independent
, Xm+2Wkm}
{Xl,..., in
strong
and
For
the
this
second
does
part
let
In.x. = 2wn; J J
it.
have
Xl,...,
XmCE , yj~xj+2wn
x. J
~ [0,
2w)
in
~
. If
{y.} j
99
To
prove
which also
(5.9)
strong
independent
is
strong
independent.
let
nw+[njx.3
= 0
gives
~2n.x. = 0 in J O n = 0 . As a s p e c i a l
get
x I, . . . , x e [ O, m Also, we
is
have
dense
that
in
E
27 ) C with
if
SC
E
to
~
so
then
that
{7,
n.=O for J (5.9) we c o u l d
of
the
start.
the
relation
is u n b o u n d e d
between
then
{x:xS
Xl,...,
Xm}CE_
[2n.x.j0 = - 2 n 7
implying
case
from
regard
in
F
each
j
; thus
obviously
sets
in
in
E• we
take
E
and
F
is
dense
mod
2~}
that
{log
p:p
prime}
,
is
.
2.
One
a linearly
•
£
in
of
Bohr's
independent
key
observations
subset
of
E
; in
was fact,
is
if
m
In.log 1
p;
n.
we
have
by
the
apply
n
log
Hp. J = O and a fundamental theorem
Kronecker's
theorem
= o
J .
hence
Hp. J = I - this means a arithmetic. Bohr used this
of to
the
Riemann
that
each
n.=O 3 observation to
( function:
co
~(s)
3. elements
-- Z
1
1
n
We
know
of b o u n d e d
strong
independent.
is n o t
Kronecker.
and
- H(l+e s
¢6C(E)
had
from
Theorem
order
then
Thus For
the
s log
p+e-2S
log
p+...),
p prime
closed
EC
if
form
E
0
example,
4.1b
that
is n o t
or
7
if
Kronecker
belong
explicitly,
Czc#±l
; then
to
since E~
suppose for
[0, wsE
any
{m
,w) I = I c - c o s n
Further
note
pendent
then
n
w+~njyj
that
= 0,
if
EU{w} yjsE
n
O
or
or , then
o which
w
EU{o}
is
2wn
n.--O a
(since
it
is
not
2w)
then
E
el~sE~
F)
Z - -
,Ic+ll}
in
E
and
independent;
+~2n.y.
2n.=O) J
contains
> 0
--
are n o t
1 implies
m wl > m i n { I c - l l
F
(i.e.,
}C n
l%(w)-(m
.
p
= 0
hence
for
so t h a t
O 0 and
E
is
strong
example, Z2n.7. 3
n
o
~=0
0
= 0
indeif in
F
100
4. strong mable
As we
shall
independent
then
by
result
exponentials
gives
the
every
sufficient @
ing
that
limits
the
definition
on
% : E ÷
E
those
sets
is u n i f o r m l y
approximable
set
E
E
tells
in
and
the
fact
gives
the
necessary
are
every
us
that
is u n i f o r m l y
is f i n i t e ;
fact,
that
continuous
is n a t u r a l l y
on w h i c h by
theorem {z:IzI=l}
of e x p o n e n t i a l s
of K r o n e c k e r
following
if
condition
infinite
characterize
The
Kronecker's
if and o n l y
a discontinuous uniform
see,
motivated continuous
if
E
approxi-
Kronecker's
there
is a l w a y s
conditions, functions. by
is
not-
Thus,
seeking
to
¢ : E + {z:Izl=l}
exponentials.
results
are
four
} C--~
be
statements
of K r o n e c k e r ' s
theo-
rem.
Theorem
5.1
{el,...,
Let
Cn } C ~ _
{YI '''''
Yn
x~E Let
V{al'''''
an}C N_
V j = l .....
n
{Yl''''' and
any
any
Yn } ~ E
i be
strong
independent.
3 { m I .... , m n } C Z _
and
Then
3XEE
such
that
,
5.3
Let
{~'
e }g" ~ n --
(5.12)
YI' • "'' Yn } C-- E
5.4
and
Let
{w,
¥{~i ..... ~n} C:E_ Vj=l,..., n
and
be
strong
independent.
Then
for
we h a v e
sup m~Z
Finally,
(5.13)
for
Ixy.-a.-2wm. I < s O $ O
{el,...,
Theorem
i J
VE>0,
(5.11)
Theorem
Then
n iy.x n l~c.e 8 1 = ~ICj 1
sup
5.2
independent.
we h a v e
(5.lO)
Theorem
strong
this
n imy. I [ c.e Jl j=l 8
is
(5.2),
" ~ Yl' .. "' Yn } g-VE>0,
n = [Icjl i
3 {ml,...,
Im~j-~j-2wmjl
be m
n
< s
strong
independent.
}~
and
--
Z
m~Z
such
Then that
101
Remark
i.
We h a v e ,
as we
Kronecker's
theorem,
Theorem
and is
(5.9)
the
strong
the
hypothesis
independent
conclusion
Kronecker.
see
imy.
so t h a t
be w r i t t e n
Theorem {w,
ia.
5.2'
(resp.
3 x~E
Theorem
quivalent;
(resp., ~meZ)
give
Bohr's
for
by
close
that
only
Theorem
from
if
{w}UE~E
4.1a).
{Yl'''''
(5.8)
Further,
Yn }
is
i(my.-~.-2wm.)
if and
Theorem
>.2
5.4')
Let
=
le
e
only
a
if
le
e -ll
,
imy. i~. e-e eI
(resp.,Theorem
{YI'''''
independent. such
that
Then
5.4)
Vj=I,...,
< e (resp.,
proof
le
(via F e k e t e )
yn} CE _
V{~I''''' n
imy.
Jl
>.i
some
intimated now
÷
prove
is small.
can t h e r e f o r e
(resp., an}~ E--
and
,
i~.
J-e
e I < s)
of K r o n e c k e r ' s
theorem
,
the
to n for
for
this
x
b
Theorem
that
Theorem
5.1
- 5.4
are
somehow
5.2
if
By R e m a r k
~i=0
i we w a n t
to
. This
5.2
ixy. i~. e-e Jl
trigonometric
some
x and
gives
÷
e-
show
x
Ie
(5.10)
above it.
Theorem
(5.14)
but
the
i~.
e-e
We've let's
Theorem
that
if and
from
fact
. In fact,
of
5.1
2.
a.
holds
notation
e -zl
is s m a l l that
4.1a
a proof
that
e
strong
ixy.
§ 5.2 we
le
Theorem
be
Ie
In
note
given
as
Yl .... ' Yn })
Ya>O,
the
4.1a
i(my.-e.)
el =
Imy.-~.-2wm.l e o J to t h i s we see
Related
of T h e o r e m
just
already
in T h e o r e m
is p r e c i s e l y
this
J-e
le
earlier,
5.4,
(E b e i n g
(5.13)
To
noted
thus
(5.14)
Theorem
5.1
< ~,
j=l,...,
n
;
n-i~. iy.x 11+Ze Je e I is very polynomial 2 -ia. i y . x l+e Je J m u s t be v e r y c l o s e to 2 which
Let
gives
(5.11).
c.=r.e J
J
J
r .j->O
, and
let
E>O
102
By T h e o r e m j=l,...,
5.2'
n
(our
there
is
xeE
given
reals
such that
in this
case
le
are
ixy. -i~. J-e JIl
Z¢(n)e i n Y -
is of course
to K r o n e c k e r ' s
theorem
(sic)
fields.
theorem
(1926)
[ 57, PP.
everywhere.
Carleson
converges
a.e.
to
¢
and,
in fact,
theorem
series
: there
latter
for
ap-
sev-
we only men-
of Fourier
59-61]
This
(and Hunt)
for d i o p h a n t i n e
At p r e s e n t
of it in the t h e o r y
diverges
important
crucial
we are d i s c u s s i n g ,
independent
application
Kolmogoroff's
, then
we've
Kronecker's
proximation, other
for T h e o r e m
h.lb
5.
eral
0
is strong
Obviously,
in T h e o r e m
o 1 J
situation E
n
i = [Icjl
result (1966):
is
is to
@iLl(F)
perfectly if ¢~LP(F),
103 5.2
The Bohr P r o o f The n o t i o n
nique,
and w i t h
ditions;
of K r o n e c k e r ' s of Riesz
that
idea
product
plays
are a s s o c i a t e d
so, let us b e g i n w i t h A Riesz-product
Theorem
has
and R e l a t e d a crucial
several
Estimates
role
in Bohr's
natural
arithmetic
techcon-
some d e f i n i t i o n s .
the
form n
(5.15)
where cos>-i
Rn(X)
on t h e i r
particularly singular
properties
useful
and let
represent
set
have b e e n in [ 5 7 ;
and each
¢.sF. Since J e x t e n s i v e l y and
studied
i16,
Fourier-Sieltjes
[0, y. J
(where [0, 2 ~ ) C ~ )
finite
set of reals
Volume
I] . They
transforms
are
of c e r t a i n
measures.
{vj:j=l .... }C_
x.=y. J J
~
are given
to c o m p u t e
(continuous) Let
ery
H ..(l+c°s(xjx+@j)) j=l
{x.:j=l,..., n}~E is a given J we have R >0 . Riesz p r o d u c t s
reports
group
-
be the
w h e n we
.
{Xl,... , Xn}
2w)
We
say
accessible
points
of
consider
it as an e l e m e n t
that
is
E
the f o l l o w i n g
i
in~
conditions
if
E~_F of the
for
ev-
hold:
n
(5.16)
- S.Xj=0, ~ 1 J
where
e.eZ J
..lejl!N,
and
implies
s'=O'0 j = l , . . . ,
n
;
n
(5.17)
3~e'xj=x k, w h e r e 1
Remark
From
(5.9)
{YI'''''
Yn}
is s t r o n g
clearly,
if
E
is
Motivated diophantine
l [Icjl
J
sup IZc.e
b .
c.
ixx.
I c.e
sup x~ [ O , N ]
>
¥N
ixx.
1
JI
s,-u p "I I~ c.eJ xetO,NJ 1
n
>__~ ~.I c
jl
1
i¢. Proof.
Let
Also,
J
c .=r .e J J
, r.>O,a_ ~J~ [o, 2~)
, for
j=l,...,
n
.
define n ix.x ~ Zc.e J
P(x)
i
,
J
n
Rn(X)
,
--- I I ( l + c o s ( x x j + ¢ j ) ) 1
R
(x)
n,o
=
R
n
(x)-i
,
and
i(xx+¢) R
(5.23)
Note
that
if
n,j
.(x)
j=l,...,
~ 2R
n
n
J
(x)e
J
-i,
j=l,...,
n
.
then ixx.
(5.24)
Since
Rn(X)c.ej
YI''" " ' Yn term
in
is the
the
series
and
so
we
Ii
' we
series (5.19)
apply
J = !2 rj ( l + R n , j ( x ) )
see
(5.19) is
(5.16)
from is
constant
(5.16)
that
a(o,...,O
)
if
directly.
and
only
the ; in if
only fact,
constant a term
~ x +...+s x 1 1 n n
in =
0
106
Thus,
the
frequencies are
of
the
of
R
n,O
(x)
(when
written
as
a series,
of
course)
form n
~¢.x., s.=O, i J where We
now
From
at
least
one
give
the
frequencies
(5.19)
and
(5.24)
c
(5 • 25)
ix
2 - -m e
x
m R
(x)
rm
the
~( - ~k)~k
1 if
constant =
Sk=O
for
all
r
Therefore,
by
the
"-i"
(5.24),
term
m
a
m
is
the
a(
..
~i'
~exp .,e n ,
C ix X m m 2 -- e R (x) r n m (5.17) this latter "
of
by '
2c
where
e. is a l w a y s n o n - z e r o • J of R (x) , m > l n,m
, and
Ym
-+i
J
c [ 2-- m ~.=0,±i rm J
=
n
Consequently, n
J
k#m
Hence
the
in
the
m-th
constant
= i
of
R
(x)
term are
of
R
(el,...,~n)
of
where,again, Next
we
define
the
the
mean
, ej=O,
"-i"
value
is of
in
equality term
holds
the
±i,
form
the
except m-th
a function
is
is
0
n Xa.y.+y i J J m
; and
the
for
all
(0, .... 0 , - i , 0 , . . . , 0 ) ,
coordinate. F
: E +
~
on
[O,N]
~N 1
and We
we
estimate
MN(Rn,m)
1 F(t)dt
,
, m~l
have 1
(5.26)
rN I R 0 n,m
(t)dt
i =
N
CN I0
only
'
(x)
n,m n-tuples
when
coordinate.
n,m frequencies
occurs
constant
( 0 , . . . , 0 , - i , 0 , . . . ,0)
n +[¢,x~) m i ~
ix(x
~ b(¢ 1 . ¢n;m) exp ¢ . = 0 , -+I .... J
n it(Xm+~¢kXk)dt 1
to
be
107
where
the
(Sl,..., nate,
sum on the En)
right-hand
side
is not taken
~ (0,...,0,-i,0,...,0),
and where,
"-i"
over
in the m-th
coordi-
generally C - -
(5.27)
b(el,
this, Because
,en;m)
...
(e
from
(5.25).
m
of course,
of (5.17)
a
= 2 r m
follows
and since
we've
already
,...,e
1
dealt
n
)
with
the
constant
term
n
of
we have that n,m p e r f o r m i n g the i n t e g r a t i o n
Thus,
R
no f r e q u e n c y
x +[e.x. m I ~ J
of
R
n,m
is O.
in (5.26), n
iN(x +[~.x
)
m 1 J J
1 iN
(5.28)
R
0 n,m
(t)dt
i [b
= ~
e
(El,
-
.... en;m)
1
n
i(x +[~.x ) m 1 J Therefore,
because
(5.29)
of
J
(5.27),
IMN(Rn,m) i < 4 [la( --
. s I,
n . • ,e
and
4 (5.3o)
IMN(Rn,m ) I -< Nd n
where From
the
(el,...,en)
estimate
(5.20)
we
(5.31)
for all
,.. el
(el,...,e n (0,...,0,-I,0,...,0)
Thus,
. ..
I , '£n
compute
Is(
2 n-
el'
# (0,...,0,-i,0,...,0
)#
(~)2n-2(1)+
%la(
)I = 2n( "'en
... + ( k ) 2 n - k ( I ) 2 -
(
-i ) +
+.. .+1- 2i = 2n- i-2
m) 1 < 2 n+2 - 2 n,
n2 n-I
2
N ,
IM~(R
2nl ) +
108
and
(5.32)
IMN(R n
,m
2n+2_2 )i < - -Nd n
by (5.29) For
R
and (5.30),
a calculation
n,O
respectively.
similar
(5.33)
to that for
IM~(Rn,O)L
2
R
gives
n,m
2n+l-2
and 2n+I_2
(5.34)
IM~(R~,o)I i - - Nd n
From
(5.32),
(5.34)
and
(5.24) we have 2n+i_2
(5.35)
IMN(~
)l < i+
Nd
n
n
and
(5.36)
IMN(C.e j
ix.x i J R (x)) I > ~ r (i n j
2 n+2 2 ~d n
N
for
~=i,...,
n ,
since
i [ i N j0 2 r.dt J
i = 2 rJ
Therefore
(5.3~)
(I+
Now because
2 n+l N -2) sup fP(x) t h sup IP(x) I IMN(Rn)I n xe[O,N] xs[O,N]
of (5.24),
(5.32)
and
(5.36)
2n+2_2 ) Nd 2 IMN(Rn, j n
(5.38)
thus there
is
~.c~ J
such that
I _7 i J
~n
Now Nd
-(2n+2-2) n
Nd + ( 2 n + 2 - 2 ) n
and Nd - ( 2 n + 2 - 2 ) n
lim N ÷ ~
=
Nd
i
.
+(2n+2-2) n
Thus.
from
(5.41),
if
0<s
_ 7
sup xc[O,~)
For
s
i -- T4
we
choose
N
such 1
--
2
i J
that
N S
sup IP(x)l ~ s [ r x~[0,N] J
(5.42)
that
110
and
so we get
(5.42)
for 2n+l+2n+2_3
N > 2
therefore,
take
N > 3
d 2
n
n+2 d
n q.e.d.
Before is strong Proof•
giving
the proof
independent
if and only
(of T h e o r e m
FN(X)
~
2
(i- ~jT)
5.1)
that
if
N=I
the Fej6r
that is
kernel
{yl,••.,yn} ~
IN
for
+
N )(eiNX+e -iNx)
=
(ei2X
+e
-i2x)
+...+(i- N+l
x+2(l-
)cos
F
As
for
(where
x. a
~) and
for
2x+.. • + 2 ( ~
cos NX
= i+(I- ~)(e
ix
+e
-ix)
is a g e n e r a l i z a t i o n
N
given is
y. 0
given
¥j,j=l,..., but
of the
.
J
x
typical
n , with
considered i¢.
c.=r.e J J
= l+cos
corresponding
as an element
we define
factor
the
of the
generalized
product n
N
R (x) s n
to Lemma
n
N>I.
then
so that
Comparable
all
F
(in E)
N l_l__)(eiX -ix) Z(l- ni~)einxN+l = l+(1- N+I +e -N
FI(X)
such,
5.1 note
{YI' • "''¥n }
if
Consider
1+2(1- N T I ) C O S
Note
of T h e o r e m
n s (x.x+~.)
5.5.1 we w r i t e
I~jI~N
N
j=l R
N
n
(~i ..... ~n
O
j
as
)exp
i x ( c l X l + ' ' ' + E n nX )
in R
n
.
xj=yj group Riesz
111
Since
{x. : j = l , . . . , n} J esis
of
is
Theorem
strong
5.1]
e.=O in ( 5 . 4 3 ) . J Consequently if some E.#O J
we
independent have
that
[from n [c.x.=0 i J J
Thus
1 2T
IT e x p J-T
and
this
F
: E +
for
we
M ( R N) n
where of Again,
for
R
ix(E
converges T
the
-
x +...+e x )dx 1 1 n n
to
0
define
as
M(F)
=
and
the
only
hypothif
each
T([eox.a )
T([c.x.) J
equality
'
T ÷ 1 lim --~ T + ~
~
FT I F J-T
T 12T [ RN = a ( n n ~ I-T n v,...,v,
lim T + ~
second
if
and
, sin
(5.44)
(5.9)
follows
and
see
that
= 1
trivially
from
the
definition
N
n
P(x)
n ix.x ~o.e a i J
=
,
n
M(PR ~) = (1---~i ) jr.
(5.~5)
n
1 J
i(xx +¢ ) To
prove
(5.45)
note
that
if we
consider
m
re
m
then
m n
iX(Xm+[S .x. ) 1 J J
i(XXm+¢ m ) (5.46)
RN(x)r e n m
and
by
=r
~j
the
b
1~41<j (~m
m
independence
x +[£.x.=0 m
j#m
Whenever
i lim --~ T ÷ ~
(5.47)
as When
some
e.=0 J
in for
(5.44). all
j#m
a.#O, J
j
j#m
FT
t J-T
;m) e .....
exp
ix(x
en
if
and
only
j
,
n +Ze.x.)dx m 1 3 J
= 0
,
if
all
~.=0, O
112 rm
(5.48)
where Because
i¢
fT
lim ~ T + ~
j
b -T
the
of the
dx
(O,...,-l,O,...;m)
"-i"
is the
way we've
m-th
defined
R
=
r
m
m
e
a(
0,.
..
,-i,0,...)
slot. N
,
n
-i¢ (5.49)
a(o, . . .,-1,0, . . .
Combining
(5.46)-(5.49)
) = e
and
summing
(as we
noted
over
m ( l - l_l_)N+l
m
we
get
(5.45). N
But
now,
since
FN>O_
quently,
¥~>0,
M(PR N) < s u p n -that
such
o
I P ( x ) I M ( R N) n
M ( R N) n
= i
(5.50)
is t r u e
that
and
we h a v e
for
all
Rn_>O
, and,
conse-
YT>T -- o
so, b e c a u s e
of
IT N j-TRn
(5.45)
and the
fact
,
x£ESup IP(x) I ~
(5.50)
§ 1.5)
i ~T N i -< I--~ J-T1P R n I _< xe[-T,T]sup IP(x) I - ~
M(pRN)-en
Thus
~ T
in
N
n i (i- ~-~)j[=ir.j
and h e n c e
(5.10)
follows. q.e.d.
Remark
The
closed
sets
F
are
Helson.
the
new
In fact,
Fk
is
countable
closed
(there
a small
5.3
is
Infinite
II
in
k
Kronecker 4.2
n
:n=l,...},
translate
r
so t h a t
support
extra
i
- {0,
if we
sets
In E x a m p l e
k
only
problem
for
Fk by
by
Prop.
k>_2 ,
an i r r a t i o n a l 5.5b
discontinuous the
k=2
and the
we fact
measures,
Fk
see
that
that is H e l s o n
case).
Sets and Prop.
4.5 we
indicated
a natural
method
to
113
construct we'll
infinite
construct
extension proof
can be r e f i n e d
and
a perfect
of K r o n e c k e r ' s
of Prop.
Theorem
strong
5.5
Vs>0,
5.5c
independent Kronecker theorem.
and by u s i n g
set.
E . By using
First
In fact, general
this
we must make
in a m a n n e r
Riesz
procedure
one f u r t h e r
similar
products,
to the
Theorem
5.1
to state: Let
{YI'" "''Yn'n} ~ E _
3 N>O
such
that
sup mE[O,N]
and,
sets
as in T h e o r e m
4.1,
be s t r o n g
independent.
V~>O
Then
VCl,... ,e e~ n n imy. n l~c.e e I ~ (l-s)~Icj I ; i 3 I
Ve>O,
such
3 N>O
that
Val,...,anSE,
3
me[O,N]
for w h i c h
le
The basic
construction
L. C a r l e s o n
although
perfect
sets,
Wik
imy . is . J-e J I<e,
at the
and the
of the
time
j=l .....
following
he was
argument
only
n
.
example
interested
to c o n s t r u c t
is due
to
in c o n s t r u c t i n g
Kronecker
sets
is due
to Rudin. Example
5.1
As
in E x a m p l e
4.2 we define
E
- A
Ek
,
i 2
k
and
k
12j-l,
k C
12j
-
i~-l j
j=l ....
2k-1
,
where
{I~:j=l,..., 2 k } is a c o l l e c t i o n of disjoint intervals. We now J i n d i c a t e the i n d u c t i v e step we need to form Ek given E k-I so that
E
will be K r o n e c k e r . Given
I k-l,j j=l, ... , 2 k-l,
and let
Jk2j_l, jk-12j~-- I k-IJ.
be two
114
disjoint
open
intervals.
By Prop.
4.5
{w}~{y~:j=l,..., J is
strong
k
there
independent is
N k >0
in
such
. We
now
for
each
interval
k
with
and
for k y. J
center
use
Theorem
a k¢~ 2
1 < ~
and
with
~ ns[O'Nk]
2k
the
sup
2
take
following
I~'-'~
k
1 ~
I
O
l~(y)-e
sup
J
iny
3n
J
)l
for w h i c h
1 < 6 ,
~cE
k i@.
¢(~)
where
=
Xe ae
in.y J
XF
1
Consequently,
by T h e o r e m
2.7,
there
is
n
such
that
i~.^
le
S T . ( n . ) - T . ( n ) I ~ £/2k, J J J
j=l,...,
k
Therefore k
k i0.^
~tlTjlIA,-~ O
¢eC(E),
and
l¢I~l
psi(E)
, satisfy
111~Ill-Il Since
E
is K r o n e c k e r
there
:is
n
such that
-in7
sup l~(¥)-e
I < ~/2
i
{w, yl,...Vn } theorem,
122
Ilull 1 !
Given
e>O
IIU-~nll i +
we choose
Thus ' because
N
IIWnll 1 =
such that
llW-Unll 1 +
Vn>N,
IIU-UnlII -> I I P - P n I IA,
n
Ii I I l~I IA '-
I.nllA,I
IlUnlIA , ~ I[~IIA, when Combining
~/2
+
,
,
n>N
these
ly
I IP-~
llUnll A,
inequalities
11~11l! I[~I A' +e
gives
, and c o n s e q u e n t -
ll~ll I = II~IIA, q.e.d.
Remark
Wik I l l S ]
not K r o n e c k e r countable
given
(see E x a m p l e
strong
§ 4.4, we r e f e r Also,
has
Helson
sets
5.7,
latter
are U-sets.
is again proved.
sets
Kronecker sets
Further,
). Prop.
are H e l s o n , there sets
Wik set w h i c h
~.lO
tells
sets
(e.g.
non-Helson
of s t r o n g
§ 8);
spectral
it is not
U-sets
are t r i v i a l l y
of m e a s u r e
(1.7)
it is easy to
see that
from
is
us that
and as we m e n t i o n e d
are i n d e p e n d e n t
are
are U-sets
Since
of a p e r f e c t
and [ 5 8 ]
§ 6 to see that
from Theorem and t h e s e
>.2
independent to
lution
an e x a m p l e
known
in sets. resoif
O, P r o p . 5 . 7
if
E
is
^
Kronecker
and
Note
~E~c(E) that
then
in T h e o r e m E
lim(m n n
every
it is n a t u r a l
countable that
such
lim(m
is dense
{zE~:IzlS]1~II l}
in
4.1 we proved:
is s t r o n g
~l~l~l
As such
{p(n):neZ}
independent
on F, 3
{m } ~ Z n -,y) = ¢(y)
to say that
E
÷4
YF ~ E ,
such that
is u n i f o r m l y
finite, YyaF
independent
if for
closed n
FC E and V C a C ( F ) , I¢I~1, there is {m } ~ Z -n -,y) = ~(y) u n i f o r m l y on F . C l e a r l y , u n i f o r m l y inde-
n
pendent
sets
independent if
E
are s t r o n g
by the T i e t z e
is c o u n t a b l e
independent.
Thus,
it is n a t u r a l (or Helson)
independent;
then since
extension E
- noting
Rudin's
theorem.
is K r o n e c k e r
countable
to ask w h e t h e r
and K r o n e c k e r
sets
Further,
if and only
are u n i f o r m l y
it is o b v i o u s
if it is u n i f o r m l y
uniformly
independent
sets
every uniformly
independent
set is Wik
example
of a s t r o n g
that
independent
are Wik,
set w h i c h
123
is
not
then
Helson E LJ{O}
Example and
~.2
thus
shows
(e.g. is W i k
÷+
We
an
a Wik
that
§ 6).
give
set,
there
Finally, E
of
is n o t
positive
n
when
a countable
Kronecker
> 6
n
that
, s
E
is
countable
independent.
sequences
e
and
strong
example
which
are
is
observe
[84, {6
n
+ 0
n
strong
},
p. {~
n
independent
348] }
• To
such
set,
do t h i s
one
that
,
whenever
6
0
such
we
¢(~)df(y)
w(n,m)
considering
Next,
(6.1)
Since
now
,
is l i n e a r o f f of k a continuous function
R cos j=l
O < ak
and,
÷ [O,1]
f
Cantor-Lebesffue
= ~(-n)
induced
(e.g.
(although
the
m
(n)
Consider
[O,I]
. For
write
that
p
f
co
w(n,m)
measure
§ 2.1
[-~'~)
y~E~
calculation
^
Observe
of
distribution-
j
-= I J
a standard
u(n)
say
first
by
^
We
the
function
fk:
for
is
for
define
• and
k
defined
is
2k
[-w,~
the
~
notation
J
k
fk
7,
Cantor-Lebesgue
preserve
[0,
at
natural measure
probability on
each
that
, bk ÷ 0
, form
O0
before
the
Lemma,
(and s t a r t i n g
property
that
for
Then
--
n al...ak_l(bk-ak)
there
is
with
C
, independent
of
n
n
-
sufficiently
l2w, for --
~i=...=~0 m-1 = 0 , where
m=m n
Thus, by (6.9) and the Lemma, fl 2M O__O , ~=i,..., J Thus
~k
of
multiplicity.
2~-~< ~ -s 2 -(k!)
Also,
E
from k-i
(6.12)
(k!)~-C that
bk- ak >__(k! )-e
and
large,
131
al'''ak_l(bk-a
k)
k-1 n
(k!) ~
.~-2e 0
j=l and
(k!)~_2e
.~-2E O
> k-I
j=l because k-i H j=l
Hence,
we
Next,
for
have
(6.13).
any
n
, let
(6.14)
m
j
be
n
[ (k-i)!
=
defined
[ (m + l ) ! ]
~-~
, a > 0
.
by
< -2
O
for
p(S
r
)=I
each
r
there
, [IrXn(~) I n converges a.e. 1 is S C ~ w i t h the p r o p e r t i e s r --
that
and m n
¥~S
, lim
< i
IrXn(~) 1
;
r n
consequently,
(6.19)
¥~eSr,
lim n
.
A
Now,
p( ~ ~ S k) k=l
= 1
; and
from
(6.19),
lim
Ix (~)l
for gives
all lim
~e~S k=l
k
IX (~)I
and
= 0
< 1
n
n
This
IrXn(~) I _< i
for
for
-- k
all
k
almost
, and
every
~0(E~)
so
n n
q.e.d.
Remark
i.
In
Lemma
c we
have
actually
shown
that
lima
/m
exists,
limit.
See
m n
and,
modulo
also
[ 93,
2. tially
the
an
p.
explicit
537]
Salem
formula
or
two,
have
computed
the
•
has
conditions
given on
the
refinements ak
and
of bk
Theorem are
sharp
6.1
so
[ 43,
that p.
essen-
102 ] .
134
6.3
The
Existence
Let
E
of
be
Rudin
Sets
a perfect
symmetric
set
determined
by
{~k } , and, k
with
the
m(E~)0
notation
= 2~
of
"'~k
§ 2.!,
A
we
have
E = ~Ek k=l
T - translation
of
, Ek =
E
is
0 E~k O j=l
,
a sequence
and
{TkE k}
i'
where
kEk
k k k T.E. - { y a F : y = x j + k , 3 J Cantor-Lebesgue singular where
2 ~
k k
k k k J J
j=l
and
on
2 k}
kt-~ keEL| |E} • A T - translation of W , ~ the J m e a s u r e for E , is a s e q u e n c e of m e a s u r e s
and
Tk~ k }
- { T .k E .k: j = I , . . . , J J
k ~-'---~@j k ; h e r e @ keA(F) E. E. J 3 Ek k k p, p~j , and T.~. is the
is
equal
to
i
for
each
¢~C(F)
translation
k ~.
of
since
With pothesis
will
Proposition that
for
(6.21)
k k T ~
the be
.6...~2
any
~0 above
+>
and
I I~I Ii=i
notation we
converges
in the
< ck
J
J
k k T ~ S0
have
using
Theorem
. Then E
II
so
that
6.1,
Ill =l
the
•
hy-
there
is
{ek:ek>O},
Zek ~ lls k ( - ) ( ~ ) l l ~
I Is k Iloo -- Is k(O,...,O)(o~)[
and
(corresponding
that
2
(y1,...,yn)eH
Assume
lemma
¢o
i
is k(~'z . . . . . Yn)(~)i
all
) is
R=~r 2 m similar
HHI
2
for
and
33]
polynomial
a hypercube
i/2 k (i.e.
p.
Kahane's
trigonometric
length
(7.2)
7.1
of
yn ) -
S(O
....
,0) I
y}
V - {IEF
: X0
and
E
Helson
implies
F
Helson
have
the
and
7.~). a neighborhood
N
prop-
151
erty
that
]Xu-¢ ]
(7.13)
on
N
; this
is
permissible
>
since
we
are
dealing
with
×U
and
ug~ v#A Let
[@[~i
be
defined
by
JII~-xuIXNaIVI= JlI~-xul~x.d. , f
(7.1~)
which
we
can
do b y
the
Radon-Nikodym
theorem.
Define
f l~-xuI ¢-Xu
~
,
on
N
,
elsewhere
g = 0
g
is m e a s u r a b l e
with
respect
to
W
and
if
CW = ×U P
we
have
r
] (¢-XU)gd.
= 0 ;
1N
whereas
by
and
I (~-Xu)gd. IN
(T.15)
Since
(7.13)
N
contains giving
an
the
open
desired
(7.14)
= I I~-XuIdl. JN set
the
right
I > 61 dl.I IN hand
side
of
(7.15)
is
positive,
contradiction.
cl.e .d.
Theorem ed
that
vergent fact son
if
sets
A(E)
Taylor
that
7.6
her are
is
series theorem
Carleson
has
been
the
space
then is
E
generalized of is
by
restrictions U
in
the
a generalization
sets
( [ ll4]
M.
, Notes
Chauve to
wide
uses
the
§ 2).
E
[14] of
sense. Wik
; she
prov-
absolutely
con-
Of
the
course,
theorem
that
Hel-
152
Example
7.1
Mal!iavin
are
sets;
and
if
U and
only
these set
if
he
basic
a set
and
pp.
example
and
also
Theorem
B.22).
a proper
property
y
7.6
is
of
]
the K
subset,
a set
7.4
of
spectral
F u!ther
In t h i s
and
criteria
for
Edwards tain
sums
[83]
of
and
jections; convergence to
the
Proposition ¥¢eC(E),
convolutions.
begin
with
7.3
I¢I~i,
~
if
is
S
with every
resolution. the
is not paper
case;
that
Helson.
We
for
set,
details
take
y:n=l,...}~
The
P~K
K - P have
the as
Helson giving
in
functional
7.Z)
7.8)
terms
of
is the
Grothendieck-Dieudonn@ such
Sets
of u n i f o r m
(Theorem
conditions
pseudo-measures.
(Theorem
in t e r m s
second
true
for
first
and
naturally
suggests
is
analysis
due
limits due
to
to of
R.E. cer-
Rosenthal
existence theorem problems
of p r o on w e a k related
.
the
yeA(F)
know
Kronecker
supports
The
uses
Given
set
Thus,
is not
which
z {7n'
theorems
sufficient
§ 2
C
two
conditions
of
a perfect
prove
gives
approach We
we
of m e a s u r e s
such
Varopoulos'
Criteria
and
theorem
that
to
to
spectral
resolution
which
Helson.
this
a Helson
resolution.
strong
let
that
resolution
~ C + P
to be
gives
know
spectral
. Then
a set
[ 21]
of
interesting
showed
Analysis
section
of
be
resolution
Functional
we
is
reader
E
is
it
a set
Let
÷ y
n
sets
spectral
spectral
refer
perfect
that
strong
4668-4670
a set
that
definitions
of
resolution
[ 104,
[68]
Theorem
the
to be the
is
constructed
state (see
it
spectral
Varopoulos is,
from
observations
of
proved
following
E C
F
, for
easy
Assume
result.
~>0
which
and
sup
yeE
l*(Y)-~(~)]
< 1-6
and
O
