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German Pages 424 [426] Year 1990
Mathematica/ Research Asymptotics for Elliptic Mixed Boundary Problems
S. Rempel B.-W. Schulze Volume 50
AKADEMIE-VERLAG BERLIN
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S. Rempel • B.-W. Schulze
Asymptotics for Elliptic Mixed Boundary Problems
Mathematical Research
Mathematische Forschung
Wissenschaftliche Beiträge herausgegeben von der Akademie der Wissenschaften der DDR Karl-Weierstraß-Institut für Mathematik
Band 50 Asymptotics for Elliptic Mixed Boundary Problems by S. Rempel and B.-W. Schulze
Asymptotics for Elliptic M i x e d Boundary Problems Pseudo-Differential a n d Meli in O p e r a t o r s in Spaces with C o n o r m a l Singularity
by Stephan Rempel and Bert-Wolfgang Schulze
A k a d e m i e - V e r l a g Berlin 1 9 8 9
Autorem Dr. Stephan
Rempel
Prof, Dr. Bert-Wolf gang Schulze Karl-Weierstraß-lnstitut der Akademie
für
Mathematik
der Wissenschaften
der DDR,
Die Titel dieser Schriftenreihe toren
werden
ISBN
3-05-500676-3 0138-3019
Erschienen
im Akademie-Verlag
(c) Akademie-Verlag Lizenznummert
Berlin
der Au-
Berlin,Leipziger
202-100/410/89
Gesamtherstellung:
VEB Druckerei
Lektorj Dr. Reinhard
Republic "G. W.
Höppner
1065
Bestellnummeri
Str.3-4,Berlin,DDR-1086
1989
Printed in the German Democratic
05600
vom Originalmanuskript
reproduziert.
ISSN
LSV
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(2182/50)
Leibniz",Grätenhainichen,DDR-4450
Preface
This monograph
contains a pseudo-differential calculus of elliptic
boundary value problems with and without the transmission property, on manifolds with conical singularities and with edges. The basic idea is to study appropriate algebras of operators with symbolic structures which contain in particular the parametrices of boundary problems for differential
operators.
The analogous approach on closed compact
c"0
manifolds is standard and
leads to the well-known classical pseudo-differential operators (oj>DO's) and to the index The calculus of
theory. TjiDO's
has been developed in the past decades in many
directions, e.g. with more general symbol classes, non-standard conventions, continuity
operator
in distribution s p a c e s / F o u r i e r integral opera-
tors and so on. Another direction is the theory of pseudo-differuntia1 boundary value problems, in particular of mixed and transmission problems, and the pseudo-differential calculus on manifolds w i t h singularities. The corresponding operator and symbolic structures are of a high complexity and far from being in a final transparent state. There are also many interesting open problems in this area. The present exposition is an attempt of a systematic theory for the problems mentioned at the beginning in a unified way, which contains at the same time earlier
results.
The intuitive idea is to establish first a calculus in direction
trans-
versal to the singularities which contains the remaining variables a n d covariables as parameters and then to carry out the
i^DO
action in the
other directions. For boundary value problems this leads first to the boundary symbolic calculus along dary and then to a
1fDO
|R+
being
the normal to the boun-
calculus tangent to the boundary with
valued amplitude functions. In the case of edges the
IR+
operator-
calculus has
5
already boundary value problem-valued amplitude functions but then we apply again a
-yDO
calculus
along the edges.
This corresponds to the local model of an edge as manifold with boundary "J x
|R+x {compact
c"
{edge^ .
In this sense boundary value problems for
tyDO's
are a particular
case
of edge problems. The edge there is the boundary and the local model IR+x {boundary^
. In other words, also for edges in general we have to
expect extra boundary conditions along the edge which satisfy an analogue of the Shapiro-Lopatinskij condition. In parametrices we also get potentials which motivate
matrix valued operators in the sense of
Boutet de M o n v e l ' s algebra or Visik/Eskin"s w o r k . Another supporting pr±ncLple is the conormal asymptotics of solutions as a part of the elliptic regularity. It also determines the structure of the smoothing operators (here called Green operators in analogy to those in Boutet de Monvel's a l g e b r a ) . Our exposition just presents such an approach. This is of course a huge program which made it necessary to respect carefully the hierarchies of symbolic and operator levels. The lowest level is the
IR+
with scalar symbols, based on the Mellin formulation of
calculus
IjiDO's
on
The first two chapters are devoted to this theory. In Chapter 3 the theory of
IJIDO'S
(with and) without the transmission
IR + .
follows
property
with respect to the boundary. Chapter 4 contains first the cone
theory
as an operator — valued analogue of the material of the first two chapters and then the edge
yDO
calculus itself. The various steps
are motivated and further commented in special notes sections that also contain many references. Clearly our approach is embedded into the achievements of the
TfDO
calculus connected with the names of many
authors such as Kohn, Nirenberg, Maslov, Hormander, Visik, Egorov and many others. The idea of symbolic structures was already invented and widely used in the theory of singular integral operators. In particular the content of the Chapters 1,2 may be considered in this
tradition.
Concerning the literature,as far as it is not complete in our biblio-
6
graphy with respect to sources and methods of the analysis,we refer to further papers and textbooks such as A g m o n , Douglis, Nirenberg [A l], Visik, Eskin
[v l]...[v 5]
, [E z]
.Gochberg, Krupnik
[ K 5"] 1 Grubb [G ¿¡, Hormander [H 3 ] , [P 7j, Rempel, Schulze
[.7 l] , Subin
Lions, Magenes
[s 3] , Trêves
A c k n o w l e d g e m e n t : We are grateful to 3 . Leiterer
[G 3], Kondrat'ev
[L 4 ] ,
Plamenev3kij
[ï 2~] .
(Karl-Woierstraß-
Instiute of Mathematics Oerlin, and M . Lorenz (Technical University Karl-Marx-Stadt)
for a number of
hints and technical
improvements,
further to the Editor, in particular O r , Höppner from the A k a d e m i e Verlag, for his patient
cooperation.
7
Contents 1. 1.1. 1.2.
Operators on the half axle 11 The Mellin transform .......11 Spaces of functions with discrete conormal singularity.......16
1.2.1. 1.2.2. 1.3. 1.3.1. 1.3.2. 1.4. 1.4.1. 1.4.2. 1.5. 1.5.1.
The spaces and .16 Tensor products and Green operators.. .33 Mellin operators.... .........45 Definition and basic properties...... .46 Compositions and Fredholm property..... 56 Pseudo-differential operators.. .......61 Mellin expansion and conormal symbols .......61 The action in 68 r, 1 The algebrapC(!R ~ \0) 71 Compositions of Mellin and Green operatore with pseudodifferential operators. ...................71 1.5.2. Compositions of pseudo-differential operators................73 1.5.3. Ellipticity of operatore i n c C f R " " 1 ^ ) 78 1.6. Notes 84
2. 2.1. 2.1.1. 2.1.2. 2.1.3. 2.2. 2.2.1. 2.2.2. 2.2.3. 2.3. 2.3.1. 2.3.2. 2.3.3. 2.3.4. 2.3.5. 2.3.6. 2.4.
Continuous asvmptotics and higher order operators............89 Spaces of functions with continuous conormal singularity.....89 The spaces and 0^.(11?+) 89 Spaces of the type C~(Jl.$A). C*V2,i^*). 115 Other spacee with asymptotics... * 124 Operators with continuous singularity.. ............126 Ths action of opsrators on .........126 Spacss of the t y p e Z ^ i , and the algebra 147 The algebra^(iLdRd) and ellipticity 174 Boundary symbolic calculus... ..178 The Mellin transform of Sobolev spacee............. ...178 Spaces with asymptotics .191 Grsen operators 198 Mellin operatore ...................................208 Pseudo-differential operators of arbitrary orders 218 The algebras cC and 236 Notes 246
3. 3.1. 3.1.1. 3.1.2.
Boundary value problems.....................................252 Function spaces...... ..................252 The spaces (IR?) 253 Subspacss with asymptotics......... ....................262
9
3.2. 3.2.1. 3.2.2. 3.2.3. 3.2.4. 3.2.5. 3.3.
Boundary value problems without the transmission property Green operators without boundary symbols...... Green operators with boundary symbols Mellin operatore The class # ^ Ellipticity and Fredholm property..... Notee
4. 4.1. 4.1.1. 4.1.2.
Mixed boundary value problems on manifolds with edqee 320 Function spaces. . .......322 Function spaces on a cone 322 Function spaces on a wedgs .....328
4.2. 4.2.1. 4.2.2. 4.2.3. 4.2.4.
Operators on a cone......... Green operators..... Mellin operatore The algebra e£ on a cone..... The caee of a cone with boundary
4.2.5. 4.3. 4.3.1. 4.3.2. 4.3.3. 4.3.4. 4.3.5. 4.3.6.
Notee Operatore on a wedge.... ?2-Green operatore 92-Mellin operators The class d].C - 0 Ths class : djC T P Ellipticity and Fredholm property Notes
376 379 380 388 393 397 402 406
References.
407
Index
415
10
270 270 280 .....294 301 307 .....313
..331 332 337 .345 365
1.
Operators
on the half
axis
1.1. The Mellin transform In this section we remind of some definitions and identities on the Mellin transform. Since the material is classical, we only give the statements (for proofs cf. [ J !•])• Let IR+ « J t fe IR : t > o ] . The Mellin transform of u£CQ(IR + ) ia defined as
oo u(z) - Mu(z) - ^ u C t J t 2 " 1 ^ , 0
(1)
which is -considered for z £ C or likewise for Re z o 1/2* The Mellin transform (1) is an entire function in z £ C satisfying the estimates I u(z)l ' c n (l + | Z |)" , n
a'R8
for any m £ Z + with a constant c m > 0 and supp u - [ a ~ i ' a ] > a > 1. Proposition. The Mellin transform has an extension to an isomorphism M s L2(|R+)
L 2 (Re z - 1/2),
(2)
00
where |u(t)| 2 dt - jir
5 and
^ Ju(l/2+iy)| 2 dy
(3)
«o M" 1 f(t) -
\ t-i^^Jfil^+iyJdy
.
(4)
"to
For general u € L 2 Q R + ) the Mellin transform u(z) is only defined on Re z > 1/2. If u(z) has an extension to C, say as a meromorphic function, we also consider this extension as the Mellin transform of u. An example is the Euler T(Z)
-
T •o 5
function, tz"1e"tdt.
(5)
0 which is meromorphic with simple poles at z • - j, ] f Z + , oo We also have an extension of M from C0(IR+) to the space r* f
i* { u €• SS'OR + ): u - r + v for some v 6 "£'(|R)J,
11
r + being the restriction to IR+* Then for u » r + v t- < v , r + t z _ 1 >
Mu(z)
(6)
is defined and analytic for Re z > r for some r £ |R and independent of the choice of v with u - r + v . (6) will be denoted as the Mellin transform of u* Let
be the space of all functions f(z)
that
are defined
for Re z > r, for some r € IR, and are analytic there, satisfying an estimate of the form Sc(l+|z|)BaRez
|f(z)|
with constants c,a > 0 , ra 6- Z. If f^'f^
are
in
some half
Re z > const, f^ will be identified with fg* Then
plane
is a commutative
algebra with respect to the addition and multiplication of functions in Re z > const* On the other hand, r
+
i s
a commutative algebra
with the convolution * as product < u m v, «p>
1/2. 2
belongs to L (|Ry ) for all x 0 . Finally let us mention the following simple 8» Lemma« Let f(z) be a holomorphic function in the strip
< Re z ^ f g
and ^|f(x+iy)| 2 dy * a 2 Then for any
for
x < ^
2
.
£.>0 |f(z)|
=
9
113r
,
for
^
+£
< Re z
with arbitrary
8 . &
"t I V l'
t &
18
X Z j-0 k-0
* 0 and N -
(15)
*•}
_
u(t) - 2 . 2 . j-0 k-0
-
6
i .p^jk* 3
109
l0
9kt
°(t)
i1" ° < t ) }
N' » ^
C- L (|R+)
(16)
for all
V
s
Tfej-S.S']
"
and 1 fr Z + . If y
are fixed, we also write
•
Similarly as above w e have the Oo 4 . Proposition« C , is a Fr&chet space with the system of norms TI V fy(u)
»- ( I M * 2
|| t ^ ^ 1
•
8 - (S.S'.Y. 1) fr ¡R+ xlR + x R x Z The assumption Re p^
(17)
].
1/2 was made for convenience.
2
In this case we have
C L ( R + ) . A more general definition then
follows by posing oo
r
T if , T ° y
I
oo
•
J
ot.oi' with a non-vanishing function g
[ " g
1
(t) -
«j
satisfying
for1
2 . It is our next goal to characterize the in
iiL and C * r fit
in
terms of the Mellln transform and to introduce equivalent systems of norms* To this end w e first evaluate the Mellln transforms of certain particular
functions*
5. Lemma» Set ^P'k(t) p £
Re p
(iii).
i s meromorphic w i t h t h e
C o r o l l a r y 7 . For
l i f r ^ u ^ d t k 1» m^. Thus the map
N
' "
p
¿jk(u)c0
¿1 2 !
is a continuous projection where
aCJ • 1 -
< 1/2,
M^ i ^
fk J
' '
—^ ^
N-N(i.y).
with finite-dimensional rang»,
is the complementary projection. Since im /ti^ S i ^ ^ y
(29) is proved. For proving (30) it is sufficient to consider the case 1 • 1. We first prove that
id'u
for u
l | t
r
V
+ 1
dy . Per definltionem we know that
rf.ul
2
- It^Vtfu-
¿*u)| F
o
L2
for all 1 (r z + , i| • 0, S • 0. Moreover, ^ ' Thus we have
k
. -
P j
o
P
r
k
+
k
o
P
J'
k
-
1
iog k t
+
.
V "ZZ ^^3k* ^.k+i(u>)* 3 , u
N
J
where
8 J
Since
m
"ok"°
N
Then
"
+
Z
-j
-p 3
Z j-0 k-0
l0
9ktSl[tt)(tx
— £ j k ( u ) f c ( E is continuous, the mapping ify ? u — »
-
is continuous, too. Then the continuity of - T ^ " ^ 1 * 1 aC U + T V * 0 6 It remains to consider (31), which is a simple consequence of follows from T ^
1
^ ^ )
t1-(^t)
24
„fr o+lt
(t*u)
.
t
i - M
u >
$
0
J
Later on it will turn out that
ty^
Remember that the bijection u —
t
all
is a Green operator, cf. 1.2.2. ul u gives a definition of
$
with a topology following from the requirement that t*
^fty
for ! ^
—
is an isomorphism« The third statement of Lemma 10 shows that
there is no contradiction if Re p^ *
1/2, Re(Pj+)f) ^
1/2.
11» Remark» Aseume Sy.
j e z+
,
(32)
i.e» (P i .m i ) € ^ = > ( p 1 - J .n^) éf
for all i.J fe 2 + . Then,in the definiPj fk tion of the conormal asymptotics we may replace 16 J by ~ p i3 ' k
"P1 k -t (t) »- t J log t s r .
(33)
{ r + u , u e ^P(IR)]
(34)
12. Remark» Set tf(R+> with the Schwartz space f
0
-
^PÇR)( {(Pj'"•;)) : Pj — j . Wj - 0,
j e 2+ } .
(35)
Then
The conormal 'singularity' of the type
corresponds to the Taylor
expansion of a function which is C°° up to t » 0 , It is then convenient to talk about a Taylor asymptotics (of some order
if we have a
Taylor expansion up to j • Remember that the topology of
^
was derived from a countable system
of scalar products , sr.(u.v) " •
(u.v)
2 Z
L (1R+)
+ (t1-
à
1
*
P (37) u. t1"° ft1 /if v) 2 J Î L*(IR+);
(tj. 8, X) 6 « , cf. Proposition 7. In this way
^
is a countable
normed space with Hilbert norms* If
ïfk*'' is defined as the Hilbert space being the completion of
with respect to the scalar product
y
- lim «
tt^ , we have
tPC°':?
¥
1
.
(38)
25
where lim denotes the projective limit over
nit« .
Now we introduce another countable system of Hilbert norms in Let
^,
^
j f 2, be a sequence of real numbers with the property Re
S-j *
for
P|
=
may be i d e n t i f i e d
i'(of) t f
f t
for of
f o r which
which
order « f
is
Then
31
% For
a
1
u r U2+
.
T
S > 0 we set a
{(Pj^j^?
: Re
Pj< -S+1/2}.
18. Lemma. For any 1 t 2 + there oxists a
induces a bisection
1
^ S ) — f a Proof. Let f £
S ;> 0 such that
T h e n & f for suitable
form
(56)
• o
can be represented in the
^ =
Y
W ^ ) J
£0
jpT«(t)dt ^
c with continuous functions g.(t). Since for 6 > 0 v£>
r i» b: large enough — r :
2 L
:p(8) ^y(S)
(57)
a s
a
f),
cont
is
^
c o n t i n u o u s
nuous
• 0 ^ i 6 1, (57) can be extended to
linear functional. Denote that extension by
Furthermore,
'hus
(l-c^)f is automatically given on H>(f) 0
:= 0
defines an extension of f to
/Hj(tif) + (l-ii)f )
anc
'
'
>
> 's®^
aro
obviously
the identities on the corresponding spaces. This follows immediately by completion of
¡f^ and
) w i t h respect to Sobolev norms of order 1
and extension of the functlonals to the completions which coincide. 0 We have V
V
)
(cf. the proof of Lemma 10) and mappings
which are canonically induced by iT^
and Atj, respectively. In view of
Lemma 18 w e have a bijection (56). Thus the elements in may be denoted by the same letters.
32
and
From = f t ¿y , u t i j
< f , /IT U > 6
s
, we thus obtain the
19. Theorem» For any 1 ff
+
there exists a
S >0
such that for any
I^ we have a unique docoraposit docoraposition f = g + h 1
IM
m
with g f ^ ¿ i , h t
* Œ . m = ^
( m j + l ) , N = N(£.y).
j=0 1.2.2. Let y
Tensor products and Green operators be the set of all sequences {(p^.m^) 6- C x Re Pj
Similarly
»--so
as j
«o , Re Pj
: j t-
The Mellin image of 1/2 - S = -
^j
. Ai -P
* a-mCk)
consists of analytic functions in Re z
>
and
oc' (v) = {5l(-S k + iy) 1 v(-S k + iy)| 2 dy - J l O f ^ + i y ^ v ^ + i y ) 1 2 d y } 1 / 2 < k, 1 for vfciTj^,, k,lfc? + . Set
£jU
:»
Then
1/2 is a countable set of norms on
Jy
for k , l t 2 + .
Set
Vi(u>2>1/2-
«.(k)(U)»(X i=0 Then of ^
i3
again a Hilbert norm on J y . Let
with respect to
^k)*
Let
ify^ be the completion
be the Hilbert space of all ho-
lomorphicfunctions f(z) in the strip B k for which \|($ + iy) 3 f(J +iy)| 2 dy
sup "
8
< °°
k < W
for j = 0,1,,..,l(k). From the results of the previous section then easily follows the 1. Proposition, The map u
- M
u |B
+ ¿^u, u £ ^
* £ » £ k + 1/2,
has a unique extension to a topological isomorphism
and
T
= v
&{k) © *m(k) n
* - 2fT
l+z1^
1
'
tpl^*1^
K(z,w) is obviously square integrable. Thus Hilbert-Schmidt and Proposition 2 is proved.
is
•
As a corollary we thus obtain 3. Theorem» The space Proof.
is nuclear.
¿ y is the projective limit of Hilbert spaces
The nucle-
arity holde per definitionem if for any k there is some k' such that » position 2.
is Hilbert-Schmidt. This was just established in Pro0
Theorem 3 reminds
of results on the nuclearity of spaces"of analytic
functions. Let
and consider the spaces ¡Py and iP^
with the systems of
norms (31"^ )oi(.oi and (^ijJgeB' respectively. Here ar(u) 0.
gj
V(0.t)
assertion.
elementary
with ~
S) '
(13), tho
the
a,b&IR
1 W^
11
L*(R+
x |R + )
way
0 R + x IR + ) (25T)
-2
w
1
z
1 '
v(iv,z)
||
2
L
:jj| w
vV ((i vW , z )2 ) J] ' «
L
SrJ1
v(s.t)
< r i * r i >
2
L
v(W|Z)
( r i X r i )
L2(
+
(|R +
x |R+ )
r i
2
2
2
S
2
+ II Z 2 1
2
2
c{ I
z
I ^ 2 " ' l W t
v
(
2
S
)
s
'
t
)
x
r i > i
2
Il 2 « L (IR + x I R + )
J
] j
and » ì
(2JT)
«
v
-1
-
v(s,t) L
i/
1
„ V t '
(1R+ x |R + )
8
v ( w , t )
2
t
V(s.t) l/"(IR+ An a n a l o g o u s
estimate
( V -
for si-
4
SrJ'vts.t) L
44
v(s,t)
x 1R + )
(l« +
X|R+)
L2(|R+
x
|R+)]'
combined with the other estimates finally yields
I
s
«
=
cj t
~
l (t?+ x
|R+)
~
s2(1J
^
~
v(s.t) II "l/^
S
x |R+)
+ Bt2^ ||
The estimates in the proof of Proposition 10
( 2 5 )
^
t
v(s.t)|| "l^C^xrJ
may be modified by using
the inequality
xayb = cj
xsgn
1 a( | a| +£) + yt" b( |a| +
for all x,y€-|R + , a,b€-|R and arbitrary
t) j
£.>0 with a constant c = c(a,b,f)
> 0 . The proof oasily follows from the obvious case when a , b € I R + replacing x(y) by x
—1
(y
—1
by
).
Then (25) can be replaced by estimates where on the right, for instance, we have an exponent of s close to
~ r if - b
~ "r instead of 2(^-6). This has to
be compensated by enlarging the other e x p o n e n t s . In other words,the s (or t strip) needed for estimating the mixed terms in (25) may be close to the original one. The assertion of Proposition 13 is well-known in the special case ^ s for
«= y Q . Then it follows immediately that Proposition 13 is valid Y . 0|
containing only a finite number of points. Using the notion
of infinite sums of topological vector spaces (cf. 2.1.5.) one could derive another proof of Proposition io 1.3. Mellin
from, this .
operators
Now we introduce operators of Mellin type which give a first
expansion
of the algebra of Green operators discussed in 1.2.2. At a first glance the Mellin operators are similar to
Tj.D0's
with Fourier transform
re-
placed by the Mellin transform. Note, however, that they are smoothing outside the origin and are localized modulo Green operators in an arbitrary small neighbourhood of
0. Moreover, no Mellin symbols with
explicit t-dependence w i l l occur.
45
1,3.1» D e f i n i t i o n In for
this f
and b a s i c
s e c t i o n we s h a l l
,0| t y
so-called O °P
where f t
introduce
, which are
The s i m p l e s t
M
properties
closely
Mellin [f]o
operator
: ^
and o p M [ f J
'
of o p e r a t o r s
connected with
~
has
in
, ^
the M e l l i n
the
form (1)
with a cut-off
is- the M e l l i n
)
convolution.
,
m e a n s t h e m u l t i p l i c a t i o n r
a class
function
on I R + ,
convolution
co
opM[f]u(t)
o 5 f(t/t')u(f)df/f
, u£-L2(K+)
.
(2)
0 B e l o w we s h a l l
prove
that
the choice of
ti
does not a f f e c t
modulo Green o p e r a t o r s . More g e n e r a l l y ,
we s h a l l
the
and c o n v e r g i n g
form t ^ " ^ l i o p M [ f j t"'
^
O.
J "0 necessarily
First in
opM[fj] Ojt
3
in C
oo
tion with
is
for
any f ( r f
mappings For
and continuous
and f — >
46
: ^
f
case of
by t h e
f j that
of
sums are
not
function
O
the m u l t i p l i c a t i o n
then tho o p e r a t o r
occurring
by a
func-
, w i t h max(,lepj
, Mf
: Gy
M^ i n d u c e s
*
+ r;eq|J< 1/2,
o n o )
—
M^ o f
multiplication
operators *•
we g e t M
symbols
deal with operators
singularity.
~
f t
with Mellin
on t h e m u l t i p l i c a t i o n
1 , Lemma. L e t
Mf
, ]f>0,
a simple special
conormal
by f d e f i n e s
fc
operator
3
, .
we c o n c e n t r a t e
(1). This
, j
the
o
continuous continuous
t>
Jy^
and f - » M f
induces
operators M
f
mappings
^
y
'
continuous
Pr^of:
Let
?
(t)
for
all 1 f
v
i
t
a
f
•
"
. oj = {
(
{
«
O
(t).
Then
" i
,1
obtain z j=0
^
• •^)]
.
x
+
2
logJt
S = 0 we )
, m j )] .
P j
—z
^ Z "i to
= { (
(with
o b v i o u s m e a n i n g of
q..k
subscripts)
¿t
V ,
k=0
=
4
u - ^ T j=0
k=0 p . ,k
^
N
tX "
£
op (if
TJ4f
® J *
Vy. >
)
with
Proof. Per definitionem we have ( t J - ^ Q o p M ( A ) 0
for
\
Then the sequence of conormal
J
symbols
from M + tif.
G r e e n o p e r a t o r s and M e l l i n o p e r a t o r s Yi
»•»0
tf-i «-o (U-60)
operator
arbitrary.
o p e r a t or Ml + A
t
shows t h a t
(cf.
Hence
same c o n c l u s i o n a p p l i e s
a given
uniquely
«s« J "" to + t
J
a compact
than
. > 0, t h e J
^ • For
j **
t
e
a sum o f
norm l e s s
= 0 but ^
(U-K)t
is
J
j ""
t
Lemma 7 ) it
to
is
tj t
J"" iT-i J
and
compact. I f "C -j t J +
=
J
+«LG t h e p r i n c i p a l
determined according
to
an
Proposition
Mellin
10.
Consider
now 3-1 -
. ^ T « * « »
h ^ ) , « ) . * '
k=0 /fti^ b e i n g d e f i n e d
by t h e
finite-dimensional orthonormal with operator we h a v e
last
equality.
space M..
respect
' 1(
J_
v
to the L
)"
be a b a s i s
(for
0R + )
6l3 with finite-dimonsional « i «--Oi, = t
Let
the notation
scalar
range
product.
cf.
For
"¿ijU
yields
being uniquely t
1
0,
instead
then
the
we
and
(AH +4l) =
.
(Atv).
of is
the
sub-
on Re z = 1 / 2 .
G , j t 2 + , are subalgebras of
, the argument principle (cf. (Xl], p. 90)
gives
5. Proposition. Let ot, «.' have the same principal conormal symbol h Q
and itf 1 +
+ OL^Q. a.' fe 1 + ind
+ ° t 6 0
f o r t
for
t > 0 op ( i ; J ) ( S ) u ( t )
- prJjj \ ( t - s ) j " V
* Now we i n s e r t
0
the e
^t-s)u(s)ds.
expansion
-S(t-.,
£
=
^
( t
.
3 ) k
+
V j ( t i l ) i
k-Q where R^ j ( t , s ) ds • - t r
_2
has a z e r o of o r d e r N+l a t
s = t.
Then w i t h r = t / s ,
dr, oo
t ^ (t-s)
;i
" (t-s) u(s)ds 1
k
0
» ^ 1
(t-t/r)k+j"1tr"2u(t/r)dr oo
= tk+J 5
( e - D ^ - V ^ ^ u t t / s ) ! *
1 u e- CqOR + )«
Thus
$
(t-s)k+j-1u(s)ds
0
[ /«kj(8)U(t/8)
I
s
0 f
/ " k j ^
= tk+j
( a - D ^ - V i ^ »
I 0
f o r s > 1. f o r s 6 1.
and we may w r i t e
65
^ (t-Bj^-MsJds
- tk+J
op M (m k )u "kj'
0
(10)
with mkJ(z)
= M/ikj(z)
- S
s ^ ^ ^ ^ s - D ^ j ' ^ s .
1 A classical
integral
formula
„..(*)«
r ( i - z ) r(1+iop+(l+
k —
for
» € C, Re « > 0 .
with
T(i-Z) r>+k)
Hi-2)
=
lc! R l - z + t f + k ) T ( « )
K
,s)
_ )(S)U>
The e x p a n s i o n of P r o p o s i t i o n 4 remains v a l i d k
( t - s ) ( t — s g ( t
i n ÏR+ x IR+ up t o t h e bound-
TO
0
+
\
/
k
( 1 1 )
Rl-z+tf+k)
Set 5°(a)(z)
;- a* g + ( z )
+
a^ g ' ( z ) .
(12) 1
9+(z) 1 à l.
Below we a l s o
G~^(a)
a
I(^)g"(z>}
flu-*)"
B !
^ Î C ^ !
8
t h e c o n o r m a l symbol of a or o p ^ ( a ) ,
where t h e dependence on
S
(13)
of o r d e r - 1 ,
lé
action,
i n t h e e x p a n s i o n of P r o p o s i t i o n 3
out.
5» Theorem. L e t a t S ^ ° ^ ( | R n \ 0 ) N e 2+ there
,
»
Now we d e r i v e t h e M e l l i n e x p a n s i o n of t h e p s e u d o - d i f f e r e n t i a l
i s cancollod
1
write
«"m 1 and c a l l
+
and
i s a k=k(N) , k ( N ) —*• oo
où be a c u t - o f f
function.
a s N —• oo , such
For
every
that
N Oop ( a ) ( £ ) o -
66
+
j-0
''Pg^N^^U')
(14)
with
some k e r n e l b ( a )
Proof.
Let
-
b (a)(t.s.4')
Oj^ be a n o t h e r
Lemma 1 a n d P r o p o s i t i o n
cut-off
f
c V ' ^ O ,
(
N
x
^
o opM(Aj(^.S)g+
- IC^T
+ A~(^,8)g-)
)
o (1-J)(£)d
C^op
mod o p g ( Inserting
the d e c o m p o s i t i o n
fo
N
»op ( a ) ( £ ) o
-
r
N
X
Z°
j-0
k=0
0 P
of
Proposition
A
m(
Î^"
S )
9+
4 we o b t a i n modulo
opQ(
+
N +
b
°PG< N.S>
« V ^ ^ P M ^ ^
(15)
k»0 N ^Tu>opH(A*(£\X)g+
+
+ A~(^,S)g-)
01opG(b).
j-0 The s e c o n d a n d t h e t h i r d °Pr(
®
+ OopM(g~)t
* . J
term on t h e
right
of
(15) are
o^ = OtJopM(g
opM(hI
0
n
Q
n ¿P
o p
obvious M
( X
),
'o
^ ^ ) .
tJ+l 3 ( l - it^ ) . We c a n a p p l y
the decomposition
are of
69
cO op (a)Q, from 1«4»1, Theorem 5, and obtain l ^ P * op ( a ) C 3 ( l - oT^) *
N ¿_
1
* ( 1 - )
f 1 « o p M ( h 1 ( a ) ) t o ( l - if ) + opG b N (a)
1=0
with b N (a)
® *
rO
rO
and suitably generalized Mellin symbols hj^a),
V (1- 0«
and every f C-Qpfi
The vector
is bounded
for
|lm z|>£
for a n y £ >
space is an a l g e b r a with {o\
sided ideal. Denote by CSfft Q T / l ) f in
g
real
as a two-
the vector space of
w i t h coefficients in W f t Q t H
polynomials
and by ( K ^ © ^ )
the sub-
space of h o m o g e n e o u s polynomials of order k. Remember that for op (a)) t
t
M o r e o v e r , for m jt oi M (lR n _ 1 \ 0) , 5- (MV) t W U J l ] , J
(a)
.
• w. 6 ^ (|R n _ 1 \ 0), ol = op^(a) + M
The conormal symbol of order - j of
+
is defined by 6-^(0i) = 6 ^ ( o p
(a)) +
which is an element in
[ a
the subspace of sequences ( > ( h ^ k ^ 2" s j . If
to
(«).
•J e Y
by
of
p.
the d i s c r e t e
as the smallest are
k-0
1
belongs
carried
le
M('fl)
V-ii! N = N(-£),
h)(P>-
in
a s
^ ^ 0 define for
(-4dw
an e l e m e n t
£2
For
(-D
given
j
for
conormal which
constants
«-P.
aw
J
Let
•{ w €• (D
:
w •
p.. ,
j
j
(4)
and r(v) Y The
!=
3T,. y
1/2 - -J }
.
function
belongs to
iS4(C)
for
F(t,w)
:» t ~ w e i ( t )
any f i x e d
t £ IR+. For
4^u(t) and u (:
90
n { Re w i
- u(t)
i s equivalent
- ^
)
F
(5) = 0 we o b v i o u s l y
have
>(t)
to the existence
of some
£
(.
(r($ ) y )
of
the
form
(3)
such
= t ^ ^ u
V
for a l l
U
Define
the
-
that
of
F » ( t )
U2(Rt)
€
(6)
function = ^ t
z - 1
o solution
which i s a fundamental is
1
3
r
Cj.^.l) to/ .
(z,w)
4>(z,w)
- < ^
a moromorphic
F(t,w)dt
(7)
— o.
of
function with
a simplo
polo
at
z=',v.
Instead
( 6 ) we may w r i t e
for
2 (X € o< , H q b e i n g
all
form f ( z )
=
^(z)
+
Ti_,)?
t
•i defined v2(z),
as
the
(8)
s p a c e of a l l
2 L (IR
v ^ fe
IL 2
+)
, supp V j
functions
of
the
bounded,
v2
£
2 Remember 2
L (|Re
that
z = 1/2^).
an e x t e n s i o n tion.
the M e l l i n
to
It
transform
may h a p p e n ,
some d o m a i n
This w i l l
also
u
for
of
every u £ L
instance
D. C (E a s a s i n g l e
be d e n o t e d
(|R + ) b e l o n g s
when u t ¿^y valued
by u a n d c a l l e d
, that
to u
holomurphic
the M e l l i n
has
func-
transform,
again. Now we e x t e n d called
the concept
continuous
of
the d i s c r e t e
asymptotics
a s s o c i a t e d w i t h more g e n e r a l
and a n a l y t i c f u n c t i o n a I s c a r r i e d set
A C
being
t,
A
the union of
disjoint Re w
and a
S
°
by t h e c o m p a c t
- U
' ^
(15)
also h a s an a n a l y t i c e x t e n s i o n to Re z > 1/2 - (S^t-f). S i n c e both £ , a r e c a r r i e d by the compact
set
z >
(15) is e n t i r e » From t h i s w e shall c o n c l u d e
1/2 -
(S+£)j
that
the
function
= £ g
Let Fo(t,w) = t"w £(t) being the c h a r a c t e r i s t i c
function of GO
(16)
(0,1) a n d Z
t ~1Fo(t.w)dt
< p o ( z , w) =
=
.
(17)
o Then •\|)(z,w) =
4>(z,w) -
(z , w )
is e n t i r e s e p a r a t e l y in z a n d w . T h e n the f u n c t i o n > ( z ) < ^ , 4 > > ( 2 ) d«- , 8 denotes the measure on ^ U = 3 induced by the metric of , which differs
with respect to the Cauchy kernel cf>Q by an entire
function. For any U ^ U j
where dff
( A^j) . equiva-
(20)
\
95
cfrj(•) i s a norr.i on $ ' ( Ag^ . since c p ^ ( =
0 implies
= 0
for a l l z t U. Then ' vanishes f o r a l l h °
n
h
h(z)
> " ITI
(22)
dz
s i (|*
sup
|(w.z)|
for a l l z t L5, D = 'BU. Then
B c
=
^ u ( t ) 2 \*
B
su W
PA
I4>(w'z)l2
d 0, B = ^ U. The n u c l s a r i t y of
jC ( Ajjj) f o l l o w s i n the same way as f o r standard spaces of holomorphic f u n c t i o n s . I n f a c t , according to (22) each f u n c t i o n a l £ sented by the holomorphic f u n c t i o n Let U
. B = 9 U , ¿fe ^
96
z
>( )
can be repre-
i n the e x t e r i o r of A
.0
' =
SU P l < < t ,4> > ( z ) l Zf B
•
(24)
6. Lemma« The topologies on !
norms
and
I^B
Proof. The topology of
! B
are
"
St'( Ajgj) defined by
to that defined by {Yq^I
( A^^) defined by the systems of semi-
{tyy}
®quival8nt» is stronger or equal
• On the other hand it is obvious that the
topology is stronger or equal to the {^¡3} topology. Thus the
desired equivalence follows from Lemma 5*
0
Now we show that the convergence of analytic functionals implies the convergence of their potentials
,]> in the space of rapidly decreas-
ing functions on the lines r 7, Lemma. Let
> ^
.
in
{RO
z
iSi" ( A ^ y
-
e
3
and
.
(25)
P fi A ^ o
Then
in L 2 (x Tp ) ' for all 1 f Z + . Proof; For fixed
^
we find some U 4 Qlj. with Re z / ^
for all z t U .
Then ( f +iy)|2
d
y
Oo
00
^ I ( ^ + i y ) 1 $( X n ( w ) - X(w))( e + i y . » >
-
-to
B -A(w)|2|dw|
= *• 0 as n
d w | 2 dy
» £» .
f tiy)1!2
p + iy.w)| 2 |dw| dy
0
Our next aim is to construct a semi-norm system on 2
under which it
becomes a Fr6chet space. It turns out that the L (|;+)-nortns of tho expressions
(13) are not sufficient
the operators
for a topology on
such that
are continuous. Je need an extra term for tho func-
97
tionals. So let us define on 7L,(u,v) := (u.v)
a system of scalar product
+
2
+ (t-S+V(u-s(u).F>;.
t"S+1l»1(v-
s
Here
(*>|,S,1,B) , where
(v).F>))
^S
"»| t
, S e d , 1 ۥ
and 3 = 1 U for U
The corresponding index set will be denoted by l/2 X . (u,u) 6
T.(u)
L/(ir+)
.
. Set
.
0
Let us define a further system of scalar products on
by the ex-
pressions aj„(u,v)
:=
7
(u.v)
„ L
+
1 (•z1~ u,
z1^)
„
L V . )
(27) •(B)
and associated norms / V
u
)
!=
/
(23)
S e B, where S is the set of all tuples B • (S.p.l.B), J t d ,
p
- 8 : 8«- d ] \J (Z+ \ 0) , 1 (r 2 + , B as a b o v e . Instead of (27) and respectively, we also can consider the system of scalar /j R (u,v) 7
+ (zXu, z 1 " ) „
:= (u,v) „
*
L
2
+ (u.v)
LZ(Tf)
^ )
i
i
products (29)
?
L
(28),
(3)
yp
and the associated norms yu^(u) = (^jg(u.u))'
.
Another convenient semi-norm system is 'yu14R (u)
:= max 1| y sup eiR I u(1/2+iy)| ,
(30)
sup | (p + i y ) 1 u(p + iy)) , s u p | u ( z ) | ] x x J y (: IR z t B B e B. equipped with the system of norms ( 3 T v ) v tf v . i s a /\ o 5 I nuclear Fr&chet space. The topology is equivalent to that defined by
8 . Theorem.
i
the system ( ^ ( ^ g f c B * Other equivalent systems are ( ^ ^ I g f
98
ar|
d
(/Vets* Proof. The simple arguments that
is Fréchet are left to the reader.
Let us check the equivalence of ( jf^. ) and «te have to show that
(^
• (^
))
*
(y^).
( b ^ . C/J B )) is continuous with
continuous inverse, which means that (i)
to any 6 f B there are finitely many /JB(u) = c
"¡f^tf
, k = 1, ... ,kg, with
sup
(31)
with some constant c = c(B , ^ , . . . ) , l kB (ii) to any
t ^
there are finitely many B-,
3, 1 = 1,...,1 oc
—
Jf^(u) S c
sup
with some constant c = c(^ , B
L
*
(r
with
/ " ^ ( u ) , U f. ^ 1 #
...). 0/
(32)
First remark that
L
V2>
and that we may restrict ourselves to those equals one of the
for which
, j ۥ 2 . We have -|z1(u(z) - < >
^U(z)||
(u).4>Xz))|
2
(u).ct»>(z)| L
(rV2-S+
and (31) is a consequence of Lemma 5 and Lemma 7 . Conversely, , .i(S(„
-
w
„
^
^
®o , cf. also Section 2 . 1 . 3 .
In order to prove the equivalence with (yUg) first observe that norms
as
on the functions u (r b^y are finite and induce
which is stronger or equal to that defined by the ^ g * 2
vergence of u in L ( B ) implies the convergence of
the
a topology
Indeed, the con( A j ),
^ j ( u ) in
which follows from | I = I — — 1 1 ^S 2ir i ' 2 cB
\ u(z) h(z) dz ^
sup
| h(z)| | J | u ( z ) | 2 d / j * 2 .
z
Thus
^^
B
is Frfechet with respect to (yUg) and hence both
topologies
coincide. The proof of the equivalence of (y'-'gJgtg
t0
t 1e
'
other systems
follows
in a similar way as that of Lemma 6 and 1.2.1, Lemma 15. 0 It is easily seen that the particular properties w i t h respect to
A
choice of d with the mentioned
does not affect the topology and that a
countable subset of numbers
= 0 with
fj — >
as j — » o o
Similarly, in ( ^ g ) we may replacc the sequonco of tho numoors another one, say ( P^
= (3, k t-^,
9 . Remark. Let A t A
. ^t^ ^^
—*•
+oo
, Aty) = A
by
is
a
as k — _ + oo . >
cf
and tho topology of
1.2.1. coincides with that of ^
*
^
(4)-
. In particular
no immediate characterization of the Mellin
rhan
^
defined in duct ion is closod
Let us point out that the semi-norm systems (yUg) , image
in^^.
or (yu^) give • Out tho above
calculations easily lead to a simple necessary and sufficient tion for u t
^
whore
0 A
closed subspace of
suffices.
condi-
H ^ . Oo
Let A = I be a closed set. Thon a function ^ excision if 0 = ^
100
C (£) is called an A
= 1 and ^ = 0 in some open neighbourhood of A .
10. Proposition. The functions Tj t
are characterized by the proper-
ties (i)
u
(ii)
¿4(C
s
A ) .
oo
\|( ^ + i Y )
f + iy)u( (> +iy)l 2 dy
^
*• ^
z e r o . Then i t
the
• As
suffices
to
d e f i n e d by t h e norms ( 3 8 ) we h a v e
top,.[f]u||^(A) w i t h some c > 0 . T h i s e s t i m a t e
= C
is
M #
obvious
k ( A )
with
. c = sup { | f ( z ) | : Z Bkk V ckk ] I t a l s o i m p l i e s t h e a s s e r t e d c o n t i n u i t y of o p M f . J . 0 oo .le a l s o have an a n a l o g u e o f t h e s p a c e s o f t h e t y p e C , ,cf. T'f
Section
1.2.1,
A'
set
here
of a l l
i n the s e t t i n g closed subsets {z
To any
A*
A'
numbers w i t h
of
analytic
functionals.
¿j
the
/\' C £ w i t h
s 1-z
t
A' j
t
A
t h e r e e x i s t s a system d'
¿^ = 0 ,
Denote by
< ^j + 1'
•
= ( { ' ^
~ ° °
a s
f
of
?
^
non-negative
. d ' r> A " =
Set
19. D e f i n i t i o n . non-neqative
Let
reals.
C°°(IR ) s u c h t h a t
for
112
=
A t
A ,
By C*?
^ ( u
| Re z Z 1/2 + A"
^ A'
every
ar>d
I'}
d, d '
o A'
.
be a s s o c i a t e d
systems
. . (IR ) we d e n o t e t h e s u b s p a c e of a l l
A • A
a '(6V
£V t*
/y
+
S td,~
such
,F>
S' 6 d'
there
exist
elements
that
-
0, s-
T
the f i n i t e
0
qf : £ L
f
is called continuous at
and each closed neighbourhood U of
is a closed set l 0 ,
{ K^.UjJt
we have for every j
f K _ u(y.t) t C*°(int Kj , jfi 1 '*) ) J J being the operator of restriction to int l
L 2 (/R + ).
L 2 (IR + ) - L 2 (IR + X IR ) be a given function and denote
by opG(«v) : L 2 ( R + ) the associated linear continuous op_(w) u(t) - \
¿+
*
L 2 (|R + )
operator
w(t,s) u(s) ds » (w(t,s), Ou (s ) ) -,
L
2 u
L (IR+). Obviously, o p Q ( w ) is a Hilbert-Schmidt operator. Denote by
opQ(L2(R+)
L 2 (|R + )) the space of all those operators and by o p G ( ! T )
the subspace of operators with kernels in T C
L2(R+)„- 3 $ 1 ) . Then (1 + o p g ( b ) ( y ) - 1 + opG(w)(y) for some w t C
Q
)
^
Q
C) It Q S V ^ 1 ) .
Proof: First observe that b(y.t.s)
fr
c ^ X i . i i 2 ® ^ ^ ^„(g^ai?1)
c f . 2 . 1 . 5 . Lemma 3 . In particular b £ C°(Q ) (x^. has a representation b(y.t.s) where c.^ C- C°°(.Q)» f^
oo ^ c i (y) f A ( t ) g i ( s ) , i-0 an d the series converges in the
tensor product topology. Write M " M (y.t.s) = ^ c i (y) f 1 ( t ) g ± (s) i-0 and t^(y.t.s) - b(y.t.s) - b M (y,t.s).
130
r
Then IIfa'(y, . , . ) U
0 as H —»00 uniformly with all deriva-
*o 0 such that MV ° y
(33)
j-0 f
converges in addition *MK
°r
^ V" = ^
a l l
A*-A
w i t h h(A) f A
and that in
*• AM^
(34)
J-0 converges in
( ,
^
^
) for all 77 €- A
with h * ( 7 T ) f A .
If
is
defined in an analogous manner by another choice of c^ and constants c., "¡J^ , then / M - M b Proof; First
is a Green o p e r a t o r .
remember
the representations
» lim
(A).AtA, fixed
in Section 2.1.1., where the norm of ^ ^ ( A ) - k < : R e z < ^ + k j .
refers to a strip S ^ -
Then we have to prove that M V c o n v e r g e s as ope-
rator MV
140
:^Ck(A)
*
3Ck(h(A)>
for
e v e r y k a n d t h e same f o r
MKm
+
W
1
the a d j o i n t ,
uniformly
N
as a f i n i t e
-
anS^,
D
types
k for in
show t h a t
since
^
all
i
is
„ IB
a finite
-
II z
1
-
k}
lines
sum o f
3
, "
n
I *
parallel
( z ) - M [ t
for
l(
z
-* C f
w
j
does not •
'¡f •
e n o u g h we
have
affect
the
and hence i t
singu-
suffices
operators
of
the
(A))»
form
;
(35)
/
of
finite
length, P
finitely
many
lines
axis
M_1{ hjiz+^J
Jf^, c = c^ , h •
c-1f c 1 " "
h(w+p
N + 1,
expressions
to the imaginary
M( U ( c 3 t ) t h^.
j
u] ]
.
Then
»c' ^sw~1+lf6i(s)u(|)
c
(t)
c ^ f f s ^ y ^ s j u i f )
| £ ] d »
,
¿w -
^
J
r i -
and N l a r g e
Thus,it
LZ(B)
^«(Cjt)
abbreviation
nj(z)
zero«
t h e embedding ^ P ^ i A ) ^ ^ ^ ( h
M _ 1 - [ h ( w + ^ )M( i O ( c s ) s u ) ( w ) } c
.
2
smooth c u r v e
M( O ( c s ) e ^ u ) ( w ) -
.
AVij
LZ(D 2 )l 2
J
B being a piecewise
for
N + 1 . Thus
n (z)|
B
Set
-
c o n v e r g e s a s a sum o f
r
n j
fixed
may be c o m p o s e d w i t h
r 1
or h a l f
2 !
j-N+1 o p e r a t o r s has o r d e r
For k
| Re z > j
AM^)
then i t
|
"
>
-(j-Vj ) < 5 -
to
MC(1)
MKy
j-0 zero order
sum o f
to deal with
Qo
^
1
larity
Write
) , MV(o)
suffices
for A t A .
c
"
*
^
j
|
St-w
i
h(w+|)
c1_m
)u(|)
dw j d t
vievi of the concrete definition of the scales ^^(A)^
$k(/\*A.°)
io" N = N(k ) sufficiently large wo get that both : ^k(A) — *
#k(A+A°)
and op G (b N ) : ^ k ( / \ ) — ^
^ k ( A + A°)
are con; iiiucus. Thus «op
(a)U
t
k
(
A
+A°)
ii continuous. Mow we have op-j, (a)
a
^op^ia)^
+ 'oa op
+
(1-W) op^(a)to
( e ) ( l - c o ) + (1-co) o p ^ ( a ) ( l - i ^ ) .
The continuity of ( l - w ) op
—>
+/
i? obvious as well ar thai of bouor^e of
Theorem :\ qnd the continuity of
ifL i A o • Further it /\
let
ci' be another cut-off function with o = co'co. Then (1-co) op^(a)ai = (1- W
) op^(a)o
+ (oi - CO' ) o p ^ ( a ) w .
For ( —
cû" ; op^(a)co
op^(a)co
we may apply 1.4.1. Lemma l,wnich shows that (1- to') op^(a)co
:
>
/\°
we argue a s in the beginning,whereas for (1- cO* J
continuous, t o o . The continuity of (43) may be
proved by obvious estimates of the involved semi-norms. 0 Note that
A°
B
A ( Y 0 ) . cf. 1.2.1. (36), 2 . 1 . 1 . (4), and that w e also
have a continuous operator
2 3 . Proposition. Let aj. é o p G C P r
j t 2 + , a (r S ^ ° ^ ( l R n \ 0 ) . Then, for every fixed o p ^ a M ^ g .
6 6
, T~J T
T, A t A
° P
G
( %
A
£
° ®
r
» P, T - j A =A,
f 0 (44)
^ > '
opG(fr(x)r^A+Ao) .
(45)
Proof : We show (44), then (4b) follows by duality. In view of Proposition 2 and Theorem 8 it suffices to know that °p^(a) $
*
«fop^a)* t
S £ (
l 2
o r
+
) - A
¿£(L 2 (IR + ),
o )
)
(46)
/ .
(47)
(46) is obvious because of Cj^t ¿£(L 2 (IR + ), ifp ) and Proposition 2 2 . (47) is obvious , too, since op^(a)*f
S£(L 2 (IR + ), L 2 ( R + ) ) and d ^ f
¿£(L 2 (|R + ).
).0 Note that we have even op^(a)cj. € o p G ( and similarly for
Oj,op^(a)*
Let MK tie as in Theorem 16 and a t (38) by
TkZ^) U ij ( ^Z 1 J+k-1 of
C^ia)
for
s j tz"l J
«s V 1 . Assume
that V1(rZd.
The
proparties
llm z.\ — » show that then f x ( z ) f ty?) j. W i t h
''l'^l'lt 2 ' Then we have the
146
0 ) . Replacing m^ in formula
—k ffM (a) we get.a function f^(z) which is holomorphic outside
constan,:s
following
as
above, we can pass to some operator
(39).
24. Theorem. Under the
described
op^(a) w i t h some G r e e n o p e r a t o r op^(a)
as the l e f t
Proof: Applying
c o n d i t i o n s we h a v e
- /W + h
o and, hence, in the Intersection. Since
9
X l ^ ' V c t j=o
for all N £ N —»oo
g.
2
for all j t 2 + . we have
^
$
&
^
)
• This follows, since the scalar product in
is induced by the diagonal of
H
) © ( -i&H^ )0
J *
and the only point is to ensure the convergence for
in ( £ )@
152
)• Then, for an orthogonal base (9j)j
we have convergence oo > (h.g,,). 5«o
( h , 9
respectively.
^Ih^-)' (5"
anc
' t ' 1 i 8 induces at the same time the above
)-scalar product.
0
X
A s an example let A
2
.A
A
€ A
compatibility condition that Fr&chot
(which doe9 not necessarily A
+A
2fe
A
satisfy the
)• Then we have the sum of
space3 :PAi*
C
1
^
A -
A
1
+ A
2
,
2
L (|R + ).
This notation will be justified when we show that the space not depend on the decomposition of A (cf. Proposition 4). O n the ^
does
into the sum of elements in
spaces w e have a n additional
from the representation as projective limit of Hilbert
,x
^
A
structure
spaces
j
Then
Since the embeddings 0
!
j
^J-l'
w h i c h are induced
1
"
1,Z
'
the inclusion ^fj C L 2 (|R + ), satisfy
by
el|
.
e
2
|
we get e
j
+
e
j
s
+
*i
^ j
~ -
ttj-1
+
for all J * Z
and
The same is true of arbitrary finite sums
P
y
We shall need also A
infinite sums of of compact sets
j
i-1 . • One reason is that each A ^ A
is an infinite sum
A1
Aj•
Consider a n arbitrary sequence ( A ^ ) ^ ^ ^ sup | Re z : z t A * } Then w e can represent each j there exists i Q
*• - ««
^ 1. as ¡P x. « lim A A •*— » i Q ( j ) such that °
• A* t A
satisfying
a s i — * «> . % i n .J c»
such a w a y that for i . # for all i > i 0 * k-1
J
153
In fact,
t h e norm d e f i n i n g
for
f i x e d s t r i p c ( j ) < Re zz < | for large i .
fixed j
t a k e s c a r e o n l y about a
t o w h i c h no s i n g u l a r i t i e s a r e
contributed
Therefore,
Z *} - Z a}
i-1
i=l
and we s e t
oo
Note t h a t
^
check t h a t
i-1 for
Definition
2).
(
I ^ •
i»l ^
^ i s a nuclear oo ^
A
A "
i-1
Ai
Z
•
i-1
/x
FrSchet
space, a g a i n . I t
«L Aj_ c o m p a c t , ^
$ A.
J\
i-1
E v e r y A & A ( c f . t h e d e f i n i t i o n of A i n 2 . 1 . 3 . ) o» ~ ^ » A j • where A j € A compact and
i s easy
= ¿R
A
(cf.
to 2.1.1.
can be r e p r e s e n t e d
as
J-l sup ^ Re z
: z t A ^
—
-
oo
as j —>
oo
.
&•£^ •
Then we s e t
J-l
4 . P r o p o s i t i o n . The F r & c h e t s p a c e Ji does not depend on t h e c h o i c e of oo ^ the decomposition ^ » ^ A j w i t h t h e above p r o p e r t i e s , i . e . i f A " J"
1
\
i s a n o t h e r such d e c o m p o s i t i o n , t h e n £ j=l
k-1
and t h e t o p o l o g i e s a r e e q u i v a l e n t . rn P r o o f : Denote by A ^ a n o t h e r c o v e r i n g of A common r e f i n e m e n t
of
Aj
and
A£,
i.e.
by compact s e t s w h i c h i s a oo ^ ^ ^ = A ^ compact and 1=1
f o r each j
there
isanl(j)
isanl'(k)
such t h a t
a s 1 —>oo
and i f y
obtain continuous
154
such t h a t
a"* A j ^ . ^ j C. C+ rx , lf-L(j). The main
£(u) £
( A j). which is
possible according to the following 5. Lemma. Let K.K^.K^ C C be compact, simply connected sets. K =
i in
A
t o show t h i s we may r e s t r i c t
contrast
ourselves
the
the
the s i n g u l a r i t y
of
conditions
quantities
functionals
about
no a n a l o g u e o f
c o n n e c t e d components
the
singularity
analytic
the s i t u a t i o n
are
that
convex.
sequence
a
the sequence of
which g e n e r a l i z e s
1
reader. if
in
functions general,
left
U are
function
associated
A
is
^f-iS^i'(A^)
coefficients
-spaces,
quantities«
only with
the
More
such
preci-
bounded
t o t h e unbounded o n e s . to
in
without
In
order
bounded
components. 9.
Proposition.
dense
in ^
Proof: Let
Let
tffe C 0 ( R + ) ,
= 1 near
bounded c o m p o n e n t s . Then
l,and
a,,
each u
t ^ c t ' ) ! !
^ • 27T
set
«
^
? c ( z )
(«fcUf(Z)
be w i t h o u t
t*
we
have
\
«fc(z-V»)u(w)dw n - i j
ri
T
compact this
is part
compact
of
occurring
a s t r i p 77
part
it
In
cp(t
),
< jy i t
with
0 < c »
?(f)
i p c ( z - w ) u ( w ) d w (:
r
t h e semi-norms of
Re z
coincides
=
^ t , ^ . !
^ 1
a contour
[u(K»J - U(z)] dw
r
| ] .
admits a decomposition u
where u M f
I
/
+
= ^
, vfc 7
^
, and
hence
} ) t
for all k t-Z + and any
/
tV*
L 2 (IR + )
f, t- 0, The decomposition of u follows oy arguments
of solving a Cousin problem, similarly as in che proof oT Lemma 5. Then v^(t) = where
£
f M'(eii)'
of u . In contrast
^
to the
unique, since in general
160
co(t)
+
r y O
,
represents an asymptotic
theory here the choice of ¿^ ft
quantity
is not
Now we are in a position to extend the calculus of 2.1.4« to the spaces ^
,A
» It is clear that the abstract description of Green o p e r a -
tors a p p l i e s , we denote by
the class of all op^ib) L
\ \ 2
acting on L ( R + ) or
2
N
M
i
l2(r
+
}
®x A
]
.
The equality -
^
®
r
established in 1.2.2. Proposition 13 reflects a special property of the iPp
spaces. The proof is based on the fact that tor each fixed weight is only a finite-dimensional modification of
spaces, A ۥ A
, we have
ifQ. For the
/ © r . nore precisely tho proper
inclusion
«V
*
- V
r V
r
A
r
Assume that
^ , (xL ^ „ = ^ (x) „ as sets tor A r J "A1 ^ A^ A A ^^ the topologies have to coincide and each norm on
$ 1 ® A In other words,for given piece-wise smooth curves Pj
j , f"^ .
Fig. 3
„ Ij
,,
_ 'if1' 2
) such that \ )
(r I 5 G
C C \
Iu(zi)v(z2)p
0Utsi
/ ( C j )
side
\ C
K
1
( l + f t l
-
1
of
give3 2
Z
the
}
1
2
•
inequality
the (
1 +
^
X
in
desired
I^|)
question
contradiction I d z J I
2 I < Ì
we g e t
the
esti-
\ — > oa
for
dz2|
Ti
v
L
^
M
*
(
i
.
i
)
!
2
)
^
!
K
I
~2
^
J
v
^
M
l
^
5"
|dw2| *
x
2
J
ft
-
t
f
M
C
M
^
I
w
J
I
^
2
10.
Définit ion.
ing
properties
(i)
Zc
(ii)
| z & Z
(iii)
for
is
:
i
any
obvious
Définit ion. 2 7T
9
is
of
all
closed
d Z ,
Z
1 x
- Z
Denote
Proposition
1 Oli)
all
Z tZ.
12.
Proposition.
are
equivalent.
proof of
arbitrary
is
(Z)
Qy
piecewise
smooth
curve.
Z f Z
can Z
by
^
be w r i t t e n ,
tha
X
ZCC
)
2
!
with
!
^
K
i
the
follow-
i
=
Ç2(rlR defined
in
the
of
In
spaces.
For In
the
nuclear
=
each
definition
Frêchet
tyf)
Z (rZ
a
+ Cjff}
is
2.4.1.
2
for
Z
correct.
since
U-,
tha
Qtil^)
= O f ) ^ independent
and of
In
.
for
space
wo h a v e
particular
is
space,
= lim
associated
in
1.2.
space
'.Vrita
2.1.3.was
i
=
the
of
1.2.
inductive with
the
view
each
limit Z f Z .
topologies
choice
of
the
Z.
based
on
Proposition Z ^ Z ,
a
that
as
form
Z
shows
is
Fréchet
decomposition
all
points
• Z2.
1
for
2 + Z* = Z.
12 b e l o w
nuclear
a
set
compact
of
every
Proposition
proof
sat
is
the
that
1 Z ,
The
tho
Re z =
y ,
11.
over
¡
= Z
Z
are
by Z
Denote
Definition It
•
?
i
tha 6 are
decomposition repeated with
= l,....Pi
Z
: =
i=l
principle. obvious Z
1
we
The
arguments
modifications. have
of
tho
For
163
z -
Qtflz±
.
i-1 Now consider Mellin operators with symbols in omit the assumption that Z some
fcC.
Re
Z
d
2 e Z. First we i"* |.
but only suppose that
f) Z • (3 for
• 0 . In a second step the latter condition will also
be dropped* The second step is based on the first one by applying the decomposition principle in the sense of Definition 11
and Proposition
12. Let h ( r Q Z
t- Z.
Pj 0
Z - 0, Re fl - 0 . Fix some
¿T-*
( A +
z
}
A^A.
Let Z 4 Z be arbitrary and h (r ^ ^ 0 + Z1'1 .
h±fl
r j O T
4
z 1 - 0 - j». r
"
Z1'1 f
"here Z x
2
H T " S i z1'1 - 9
Z
.
5
i hen «"If-, Vi lfi tot J op h (T J h.)t J ci = O t
S0 ° o p M ( T °h -1 op (i ii
t according to the translation ro
Let hj * hj
o)t
S,
l0
+
' fj. , ;t c2> mod j*i
principle.
+ h^ ^ be trie corresponding decomposition of h^. Then
Q
¿ q
h
j,o
c~>
q
(v,
- \ h , « V" > k,o
j=l
k=l
p
h, ^ - V " k,l >
h. „ o,l
k«l
ana Doth sides ot the latter equation are holomorpnic near Tnus ^-Mi-
op M (T S o f
cOop'^W^iO
and
A/vf
and
is the formal L 2 adjoint, then ) - T~*
«""'V)*".
Now let us calculate compositions* First assume h P j fl Z »
^
n
fl W • fi and consider M. - ci o p ^ h ) o
ot 6-
Re U = 0 . Set for 3
X't
t
tOopH(n)0.
X ۥ (E, t > 0
»|z f t ¡ § - £
0 sufficiently s m a l l . Then Z = Z sition argument yields h » h
Thus W - iO o p ^ - ^ T - S i j
. h 2 ) i 0 mod ^ . Q
.
T h i s p r o p o s i t i o n shows t h a t t h e c o m p o s i t i o n l a w f o r c o n o r m a l s y m b o l s from 1 . 3 . 2 . r e m a i n s v a l i d i n t h e p r e s e n t more g e n e r a l
168
case.
The f i n a l sists
of
c l a s s of M e l l i n o p e r a t o r s w i t h conormal symbols in infinite
—•+«>
for j
sums o f M e l l i n o p e r a t o r s o f •
l e m s we o n l y n e e d assume t h a t
(cf. OC^ •
t h e numbers
opj^ , a r e r e a l and
] (• 2 + ,
In the applications
t o mixed
prob-
F o r t h e same r e a s o n s a s i n 1 . 3 . 1 .
we
in the d e f i n i t i o n
of
satisfy
, j
A s shown i n t h e p r o o f
of
-
tf^
> oo
Proposition
g i v s n Z-' t- Z ,
j (• 2 + ,
as j —
f
o
r
1 4 we may r e s t r i c t
o f Z G- Z i n t o a sum o f
decompositions
con-
c o n o r m a l o r d e r « j , R e of^
j f ^ j , which are i n v o l v e d
—+
Tf^
arbitrary
j,
1.3.1.).
Qff}2
two s u b s s t 3
where Z °
each i ourselves
: Z » Z°
satisfies
.
+ zi
to
For
i ) Z° = 0 ,
we
con-
s' s i d e r an a r b i t r a r y j tf ^ l l l j - 1
rea
j
s e q u e n c e h^ (- ( f { ) j .
-"- n o n - n e g a t i v e "
Y j . i — •
Choose two sequences {
^
numbers s u c h t h a t J - Tfj i °
V i . i — " *
•«o , i a
3
a s
•
1
1.2,
0,1.
-y. F o r g i v e n d e c o m p o s i t i o n s Z ^ » 2? P o t
j
,J
- ZJ
« fl we
1 1
obtai
* Z^'1,
0PM(T*3.°
O P M ^ ' defines a continuous
j-
operators singularity
>
J.°
j ( 1
1
)t
Yi
i
f
T " * ' ( A + (Z-*
4 »oo J ^opj^hjjco
for
j —
,
, 0
)
• ^ •
i « 0,1,
(z
3 , 1
),*
only a f i n i t e
i n t h e sequence c o n t r i b u t e t o the 1 1 — t y p e i n e a c h f i x e d s t r i p j • c < (!o z < j . i h e
( CO o p ^ O V j j a ) *
define
H
0 z ^ a y , + h . « » h . .and a.i J'
T
1 h.
operator
Vp A Since
ft
,i
continuous
-
op
+ co t
opM(r
M
(/j'° J'
1
h
J > 0
h
j ( 1
)
*
0«
A
A
number
• of
resulting adjoints
tJ t
e
+ J '
1
^
operators
169
tf Since
^
—
-P
> oo
as j —-> oe , i = 0,1 , the resulting singularity in
1
1
each strip j - c < R 0 z < j i a tors ( 60 o p ^ ( h j ) c à ) *
affected only by a finite number of opera-
in the sequence« The following result can be
proved in the same way as 1.3.1. Proposition 15. 19. Proposition. Let h..é ," P -12 0 J Ofift H . Z t Z"" rary sequence. If op'^Cn^) is defined with
° 9> 3 *
an
+
o as above, opj^
A
arbitOP^'
one can choose constants c^ > 0 such that
M < -
£0(c^t) o p ^ t h j )
«(c^t)
J»o converges in
, $
,
,
,
n
) for all & i à
t
and rn converges in
(J
*
= ^ ^(c^Mopj^ih..)) 3=o f (z
}
for all A t A . Another choice of 20. Definition. Denote by tha
„
§Q A
j
¿C- 2 (1R + ))
GÙ(c..t)
form AN, +
M
+
tà G
t
( ij.o)
+
(z
}
< SJfl)i
and c^ preserves
"e
, where
s
Pace ç
)
M V modulo ^ q «
operators in an
° AW is a Meilin opera-
tor of a form which occurs in Proposition 17. The function S ¡ ^ ( W * ép(z)
s- h j (z)
is called conormal symbol of order - j . Note that the sequence of conormal symbols is uniquely determined by the operation and does not depend on
In
fact, the conclusions
of 1.3.1. Theorem 13 can be applied with obvious modifications* A s in 1.3.1. Corollary 16 we have the exact sequence
170
where
denotes the i n d u c t i v e
- P .
limit
over a l l t y f ) 2 o ,
Z°tz,
["*, f ) Z °
'
2
I n t h e same way a s 1 . 3 . 2 . 2 and P r o p o s i t i o n
P r o p o s i t i o n 3 we g e t
Proposition
16
2 1 . Theorem. % M
from 2 . 2 . 1 .
*
algebra,
i s a two-sided i d e a l
in
a n d
k+l-j Now we d e f i n e an a l g e b r a the parameter Q
(R ) d
^(R^)
i| 6- IR6* ( c f .
we d e n o t e t h e s e t
of
families
of o p e r a t o r s d e p e n d i n g
the analogous d e f i n i t i o n s of a l l
families opQ(b)(i|)
b ( t . s . - y ) (r C ° ° ( I R d . ^
(• IR C| , I *n | h/2 X u(Xt).
Choose a f u n c t i o n
-
» c o n s t . , where t h e c o n s t a n t
£ €- c " ^ ^ ) ,
may depend on
£ ? 0, f
/•(t) ^ and
-1
^opG(b)(^)
1
?
< I t
for
t >
,
for
t > 1
2
,
set
C j > 0 some c o n s t a n t D e n o t e by Cjj^. . . .
d e p e n d i n g on j
t h e s p a c e of homogeneous p o l y n o m i a l s o f ) with
coefficients
ded i n t h e f o l l o w i n g
way.
22. Proposition.
h^ 6 QV}
sequence,
(2+,
Let
in
T f l ^ . Then P r o p o s i t i o n
, Z^ t Z ,
j
P ^ 0 Z ° = fS, and d e f i n e o p ^ ( h ^ ) ( i j
be a n
order k
in
19 may be e x t e n -
arbitrary
) a s a b o v e . Then
there
2 are constants
c^ •> 0 s u c h
that
eo
171
))
converges in (ZJ,0)W
^(Z
3 , 1
)^
for
a 1 1
A
J
*^ '
X
^ u n i f o r m l y in '»|é-KCClR d . and 00
J
"°
^
for
converges in
+
^
a 1 1
ù 0 , w i t h the Hilbert
s X structures induced by 3[ ' (|R+) and
H
s
(|R+), respectively.
c < d < «> : = t3-1[0.d] + H8 [ c ,
s.^R«
endowed with the norm of the sum.
In view of
178
the set
,
space
*8'*[c.d] =
Hs[c.d] =
*9'*[0.d]nH8[c..]
we get an equivalent definition for another choice of c,d, in other words
is independent of c,d. Remark that C ^ (1R+) is dense for a l l s.tfirlR. Moreover, < p & s
in
(|R+ )cj£ s
(|R+ ) for every
ij)tc" ( R + ) . This follows easily from the corresponding for
property
3
2C '*(IR + ). 5f?s'^[0.d]
Since
a Hilbert
, Hs[c,«o"]are Hilbert spaces, we also can
introduce
space structure in the sum.
It w i l l be fixed then once and for all. So J D O action on IR. For S = 1 we simply w r i t e Remember
op(l+).
that
o p d + S ) ( S ) : h£(R+)
H^"Re8(R+)
for a l l rtIR, s f t, S 6 IR , and o p ( l ~ s ) = o p ( l ® ) - 1 . H e r e H£(IR + ) = { u f e H r ( l R )
: supp u £ R + } .
179
A s u s u a l l y L 2 (|R + ) a n d H°(IR + ) w i l l
: L 2 (IR + ) — ^
op(l®)(g) The notation o p ^
Moreover, r e c a l l
= r+op e+,
r+
the
the o p e r a t o r of e x t e n s i o n
by
zero.
fixed p é ID a n d
stants c ^ , c 2 > 0 such
for
(1)
function
4.4).
For e v e r y
Re p P
cjimzl
e
i.e.
the f o l l o w i n g a s y m p t o t i c b e h a v i o u r of the V
1 , Section
2. Lemma.
tolR+,
+
identified,
h;3(R+).
w i l l be u s e d as u s u a l l y o p ^
restriction operator
(cf.T
be c a n o n i c a l l y
cf R+l
there are
con-
that
, n, < \ J Ç ^ £ l \
c , w h e r e c is so l a r g e that t h e r e a r e
p o l e s of T ( z + p )
in
S j S Re z < b 2 ,
no
|lm z | 2 c. CO
D e f i n e the b i n o m i a l Then we have
the
coefficients
the
ot-k.
, but
dense
is
then i t
obvious, follows
since in
in
Thus u>jtX o p M ( T - A h ) = ca{tX
t"X
-
opM(h)}q>
opM(T"Xh1)t-X-
opM(h1)]cJ
-185
c a n be c a l c u l a t e d 5.
by t h e same a r g u m e n t s a s
P r o p o s i t i o n . caop°(l°| ) ( S ) c ^ I 1
continuous
Proof;
i n the o p e r a t o r
on t h e
converges Let opJ(l;)(S)
The
in
9
for
in general.
. Since
for
=0.
converges C * (IR + )
is
From
Û
' * " r(lR+ ))
for a l l
s.^eiR.-^f
+ (l-c^)op
+ 2+.
Then
(1* ) (S ) ( l - i ^ )
op ( i * - ) ( 8 ) e c°°(ir + xir + ) of o p ^ ( l " ) ( S )
in classes with weights
t
: #
S , Î
(R
+
)
Ûf~
is
unique
(cf. S e c t i o n 2 . 3 . 3
induces a continuous
modulo
below).
operator
r
+
N e x t we want t o e s t a b l i s h H S ( I R + ) = r + H s ( I R ) , and supp u bounded, i s
184
the a s s e r t i o n
£ . Moreover, the d e f i n i t i o n
S^Re
' " r ( I R + ))
f u n c t i o n s , cd^tù = id^.U^ti^ = l ù ^ .
-
s.yeiR,
u(zK
r
3 obviously
which
op*(l")(S)
(i)
s _ r
: -C3op* 0 with constants c, a depending on u.
This is an immediate generalization of 1.1. Theorem 5. It that the limit of the integrals in (ii)
for i - » 0 is also
A n a n a l o g o u s characterization can be given for =
with bounded support, y i f , ^ ( v i n T i 2 ~ of
(i), that
u
poles, and in (ii)
finite.
ue$s,3(lR+)
+ ^
"here we assume,
(IR+)
instead
3
is meromorphic in Re z > ^ - s =
follows
with the corresponding
Note that for s < 0 the latter
restrictions are not relevant and for s > 0 , only a finite number of poles has to be counted. Let s e IR and %(s) Denote by g
: = max [ j ۥ 2 +
: j -c |s| - | ]• .
8 f 0, the linear span of the derivatives of orders
M,(s) of the Dirac-measure at the origin
linear span of the functions 8. Theorem.
H S (IR + ) =
Let
{t-'io(t)
and
0 j 8 , s 2 0, the
: j = 0,...,
M.(s)] .
aelR, then J^S,S(IR+)
for s > O,
t^- 3 , 8 (IR + ) + S 5 8
for s i
3 £ S ' S ( P + ) + iT® ,8,3. *
)
O, s f | mod
for 3 > 0, s * |
mod 2
for s i 0.
The proof w i l l be given in several steps. First show the 9. Proposition, ll/e have for ^H®(|R + )
2
following.
a > 0 S
(IR + ).
with equivalence of the topologies, U a cut-off
function.
185
Proof : First w e show that there is a continuous 3
ciH®(IR+
S
' (IR + ). In view of the isomorphism
S
u e H Q ( l R + ) there is a unique v f L
2
embedding (1) for every
—g (IR+) with u = op(l + )v. Let supp u
be bounded , tC>u=u , and choose a sequence { v j } 2
Vj — • v
—
in L. (1R+). Then u^. = o p ( l +
tion 3 we know that car+oP(i;s)
Vj
(IR+ ) with
8
8
) v^ —*• u in H Q (l£ + ). From
Proposi-
= « o p ° ( i ; s ) vj
for all j and that the right-hand side converges in
8
limit u'. Thus u ' = r + u and hence C 0 H 8 ( R + ) |
for a l l e fetR.
Ct0^8,8(R+)
()R + ) to some
In particular for s i 0 w e get riop^i;8)
v = w °p°(i;a) v
(6)
for all ve-L 2 (IR + ). Now let u . . £ H 8 ( R + ) , u^ —*• u in H 8 (IR + ). Then = op(l8) u j - » v
Vj
in L 2 (IR + ) and
From (6) applied to Vj
it
Oop°(i;8)
Vj
u • in
' S
follows u'=u, u^ —»• u in
S
(R+).
(/R + ).
For the reverse direction we apply Proposition 5 and obtain the continuity
tOcOi
3
où. For
QR + ) w e have
cdu =. cd r + o p ( l ~ 8 ) o p ( l 8 ) e+c»u = ti> r + o p ( l ~ 8 ) e + +
(1-ttj) r + o p ( l 8 ) e+6)u
W r + o p ( l ~ 8 ) e+(Jj o p ( l 8 ) e+£^u
By Proposition 5
it
follows
ci r + o p ( l ~ 8 ) e * ^
op(l8) e+«u
= Or+op(i;S) e+«t op8(l8)«u Now choose a sequence 8
ft '
8
of
. functions
(IR+ ). Then f
186
.
J
: a
opjt1')«»
,Qvj — •
u,
u(
in
L2(iR+).
Thus
u':*
ci r + o p ( i ; 8 )
e+fj
u 1 t H® ( K + ) .
Moreover, uj
: - U>r*
converges 0,
(7)
H®(R+)
=• X
3
'
®(IR+)
for
80,
Proposition. 3
Proof:
(ir+)
Let
us
We h a v e
for
s>0,
first
that
Qu =
ti> = tOcOi* Then,in
op^(l~8) i^op
^
Moreover,
(IR+)©rS],
u t H (IR+),
c^u = u .
: L2(IR+) — * H S ( I R + )
s
(l~ )v.
Let
the
Remark
Propositions =
10 a n d
that
t O o p ° ( l ~ ) c ~ 0
in
c ^ o p ^ l ^ 8 ) ( 1 - i) cOj^v .
c O o p G ( b ) cO.v
s
inclusion.
cut-off
13 we
+
of
vf-L2(IR+)
we f i n d a
(IR+) w i t h v = l i m v^
u o p ° ( l ~ s ) c^v..
14 shows
Then, i n v i r t u e
be a n o t h e r oe
Choose a sequence Vj t CQ
v i e w of
j.
S
inclusion
s Let
0> o p ^ ( l ~ s ) U ^ j for a l l
1 a ^ mod 2 4>H (IR + ) =
s *
show t h e c o n t i n u o u s
1 s £ ^ mod 2 .
isomorphism
continuous
+
c - i H S ( I R + ) C_» ( ¿ { t f S ' s>0,
to a
(IR+). }
= {(
>tJ:
Re
r(S)^
= { ( P j . - ; , ) ^ :
Re
= {(P
R«
P j
l
..
(
3
i
+
the
operations
by
KS)>
Obviously, v
z < §
P j
- & ] .
< J - S 3
.
P ^ f - S ] . Pj =
+
f o r
e a c h
a n d
v
For \ t
w o
|(Pj • >
+
4(1R+)' w
•
where ={(0u + (l-CO)v
: u(^(t!t),vtHS(K+)J
.
Then # f 8 C R + ) = ¿¿t{r)y J ^ f V
:
+
-
CR+) •
^("V
¿(F(y)y). +
=
(10)
- ¿ ( r i ^ y )•
It is clear that
^ / ( « V TP
T-^
(5)
'
X f- IR. Thus,these spaces could be transformed
to some fixed weight.
For notational convenience we also write
Remark that spaces
can be written as a projective limit of Hilbert j
The choice of such a scale is not
and follows from corresponding
scales for
and
references below the scalar products and norms belonging will be denoted by
194
canonical For
to
(IR+ ) ^^ ^
(...)
s
and
I.I
,
(7)
respectively. The notation tf^ will also be used for the 3C - spaces,
The description in the Mellin image will always be given for
(Ju,
whereas the influence of M(l-c«i)u will be neglected at all. This is i necessary here, since M(l- c«^)u is holomorphic only in Rs z ^ 2 1 (e.g. when u ( L ) but Mt^u is of interest in Re z < ^ • where may be negative, and then we would have an overlapping
strip.
Let us also introduce the following small modification of our spaces (5)
that only contain an asymptotic information in the open half 1 space Re z > ^ . First observe that
for 8 > s', ^tt'
with continuous embedding.
Then we can define the projective limit tf-*-0**
: = 11.
)•
¥'< vf 11 0
Note that
= { Urn One may ask whether the spaces
ft8'*"!
+
with discrete singularity typos are
invariant under certain natural operations such as multiplication by functions in
or coordinate difisomorphisms. In this connection
it is natural to introduce the condition that ao j=0
T
c v
.
Observe that the Taylor singularity
(o)
=
|(-j.c)j j t-2
is
°f that
type. 3. Proposition. The operator of multiplication by induces a continuous operator
(=
fo
195
aj = ^
and t h e same w i t h o u t
^ . More g e n e r a l l y , f o r
i f fc
j=o
*
JT^/CCjRe z < o ]
and
( 2 2 ) and 1 . 2 . 3 . Proof:
For
we have an a n a l o g o u s
Lemma
have
and
if:
= H*
for
— s > -
Theorem 8 (remember
Moreover, result
tj> : ^
follows
applies
for
case a r e
u
left
is
by t a k i n g
to the
: IR + —•>• R +
constant
(cf.1.2.2.
g (t)
equals
obvious,
t h e sum,
cp(
that
t h e case w i t h o u t
Now l e t
if
= H9 for
o 2.3.1.
with
1).
e f t ^ ( I R + ) we f i r s t
=
result
in
particular
Moreover, l e t
that
induces a
to(0)
ot(r) = r
difisomorphism
= 0 ) and
for
let
r > c
with
some
c > 0.
Proposition.
L e t «x> ba a s m e n t i o n e d ,
then
n,
induces
continuous
operators otf
oo at = 1
T"-'v
•
8
s
• if £
U3*
> yi y •
R
ar| d
t h e same w i t h o u t
^ . Moreover, u*"
operator
*
">t Proof.
Let
represented %(r)A
follows
t
=
—
.
(10)
o t ( r ) and X ( - C . T h e n t h e s i n g u l a r
= ( I ! 1 j=0
c
isarbitrarily
from t h e T a y l o r
= a^
^
i n new c o o r d i n a t e s
U > « r ) )
where N £
196
(9)
'
j=0
induces a continuous
W(r)
ML*.
—
•
+ a2r2 +
J
t*
ui { t )
by
rX+J
+ r
N +
L(r)) (-Mr)
1
given,(^(r)
= ci(%(r))
e x p a n s i o n of «0 a t
+ a ^ r "
function
- 1
+
a
N
(r)
r N
r = 0
,
,
(11) cfNfcc"(IR+).
This
is
= a r(l 1 where a 1 f 0 , a ^ C W
-
.
+
(IR + )
J
X
(r)
é- C (1R+ ) .
( i XX
+
( l
! a r ax
singular
of
. . .
+
of
, x.*'g^~ 9 (r)
= r^~s + o ( r ^ " 9 )
î?o0R+)
g
shows t h a t proved.
r-s
also J i 3 ' ^
(r)r
N
) ,
respect
=
of
to
logarithmic
\
yields
terms.
the
Then
(10)
{ u fc ¿f(IR) : supp u c iR+
f u n c t i o n s under
sflR. for
N
r V
(11) w i t h
2 . 3 . 1 . Theorem 8 and t h e i n v a r i a n c e for a l l
g_
b
of
the s i n g u l a r
*" : ^ ¿ S ' S
B
+
functions with
from t h e i n v a r i a n c e
and t h e b e h a v i o u r
rN)
• bx r
Differentiation
t r a n s f o r m a t i o n of follows
r
r +...+ *£L
and
r * 1
= aJ b N
a1
u* . I n view
the Sobolev
As proved
of
s p a c e s we g e t
above
r n e a r 0 . Then t h e
isomorphism
„
8
is
invariant
under
. Taking the sum,(9)
is
0
5. D e f i n i t i o n . for which
A
c
D e n o t e by
{Re
z < |
, ) f t IR,
-tf] . S e t
the set
A =
Then we h a v e t h e n o t i o n of s p a c e s
^
W X
with
of a l l
elements
^ t
Z
A (if)continuous
asymptotics,
namely ^(IR+) A 6 A (if) • and i t
: = tX
iTlA(|R+)
. The r i g h t - h a n d s i d e
c a n be p r o v e d a g a i n t h a t
This leads
to the
it
is
is
then
well-defined
independent
of
X
.
spaces
and "A " + ' A t A
. I n
spaces of
the
c a s e of
o" + '
^
continuous s i n g u l a r i t y
t y p e s we a l s o
admit
sort
197
0 so s m a l l
that
z
p^ 4
{l
-Pjli£j
well
defined
for
define
=
\ ^jk^
0 i k S m. ,
l S j i l
by V
"
:
= 2¥T I
hjk(z)Mu(z)dz. J
Then
is
on 2.
200
obviously or
Example.
as
on e v e r y Let
y
=
desired. space ¡ ^
Note where Q
t h a t 4- i s f J ^ 1
_1.
. Then
also
4-jo
u
= (jt) d " ( ^ I t - o
is a trace operator of positive type on
• J=°
^
¡P. (IR ) in the sense of To +
boundary symbols in Boutet de Monvel's algebra. Thus the above 4extends the notion of such trace operators for the general conormal asymptot ics. 3. Definition.
An operator
£•({)-«(, q(Q. P) is called a Green operator
of discrete singularity type if and ft in
for
"£(»() ® ^
ojQ has a kernel in ^
certain
t y
©T J
Denote by
O^ g (Q.P) the class of all Green operators with given 0=(X,0|), (
U^.^OjVary with
)
iVe also write
C L g ( X . V = ct G ((X.O), (j.O)) . It can easily be verified that this definition is correct, i.e. independent of the representation of oj_ as a matrix
(3).
It is obvious that ^t(l)
implies
-¿g(Q,0).
oj2
fc(l')
'and
^
the
-¿G(o_,P) same
without
C1)-
All essential results hold both for left Green and the proper Green operators. So,from time to time we give the formulations only for one case, where the other one is then left to the reader. It is convenient also to use Green operators that have finite smoothness both with respect to the interior and conormal orders. To thi9 end we first observe that every ej£(1)-«¿q(Q> p ) induces continuous operators $
+ ify _^3-()f-\)
ft** for all k
^
IR+ , j ( 2 + , where
+
k,A+k-0
( 4 )
+k
(IR+).
(5)
tJ| depends on ^ .
Denote by
201
(l)-^G(Q.P)(~k) the set all
of a l l
3t2+
as i n
(1)
(6)
for which
(4),
(5) are continuous
(l)-^G(Q,P)(-k>
(7)
n (1)-^ (0,P)(-k) k tz+ ^
(3)
for
.
Then (l)-^G(Q.P)(~k_1)
C
and (1)-^
°
(0,P)
=
Moreover, € (l)-^G(Q.Q)("k) implies d,
G
g2
&
( 1 )
( 0 , P ) d e n o t e s
which &
-^G
, oj 2 £ ( l ) - ^
( Q , P ) (
"
k )
the subclass
has a k e r n e l i n
G
(o,P)("
k )
' of a l l
oj. 6 ( 1
¿(op©
+
( 0 , P ) '
G
'
f o r
for /l0li
SOma
TP
and
^ G (0,P)
HS-^"X)+I w h e r e the inductive
(1)-jLG(Q,P)(-k)(«0).
= 11m
limit
is taken over a l l
«Of
and in the
same w a y (1)-«(, G (Q.P) =
lim_(l)-^G(O,P)(«0).
Now we can proceed in a similar w a y for the class w i t h o u t we have to introduce the subspace -
£
:
f
o
10 ) ¿G(Q,P)
= lim
and so on. For the are left to the
¿„(Q,P)(-k).
"^.-classes we can do the same. The obvious details
reader.
2.3.4. M e l l l n operators Let us now extend the calculus of Mellin oparators of Section 1.3 with respect to arbitrary Remember that ^
conormal
orders,
denotes the set of all countable subsets £ of 1. ¡f - k i X ,S i $,
ca1t~tM'kopJi(h)6a2 - % 6
210
h
^^
t-r+kopJ(h) «2
«¿Gii-r'i)(-k)
+
«¿ r is-r-» , ) C " k )
Then
t^i • i=»1.2.
for arbitrary cut-off functions
rso
fO
The flat term vanishes w h e n 4. Definition. A n
operator (2)
is said to have a (left-) Mellin expansion near t=0 with the conormal symbols e^-^et) if for certain
tf
= a J (r Qtfl^. , J
t R ,£ -j5 ^
f _u (O^Ot- t r g
< $ , j t 2 + , and every N £ Z +
tfj •? H taopM(aj)
arbitrary cut-off
(3)
functions.
We talk about a Mellin expansion if (3) holds without Note that the definition implies 5. Remark. symbols
"¡f0= ^
and hence
(1) on the
aQ t
right.
•
Let ft, have a left-Mellin expansion. Then the conormal (OT,) aro uniquely determined, j 6 2 + , They are also unique
for j=0,...,N-l
if the expansion only holds with fixed N. This is a
consequence of 1.3.1. Theorem 11. 6. Proposition. Let OLbe an operator satisfying 00 induces continuous
operators
01 : # J ( R + > — for every s t IR,
Definition 4. Then
a ^ O V
11p (y) with sorae Ojt y
(4) depending on ^ and SI.
If 6i is an operator satisfying Definition 4 we can define an extension to
rijfj'p
for arbitrary 'pt'p
by octfy , Then ot defines continuous
operators
and also continuous operators in the sense of
(4).
211
7. Definition« and denote
Let
by o i
tf
M + G
s p a c e of
all (5)
T
which
a-l^f
L
Z 1 f N o p j , ' (a ) 1 C 5 2 t 4 , ( Q , P ) ( - k > J j ==o0 "
for c e r t a i n If
, oj (•? (£-|. ^ -~ j J i£ U j a£ If 'ft •. iO ^^ -. OO gg aa rr bb ii tt rr aa rr yy ccuutt--ooffff
"
OL s a t i s f i e s
class
(6) w i t h (
(l)-lM+G(Q,P) -
i_l^G(U,P)("k) -^¿h+g(Q.P)(_I
"0
Ve
( Q
'
P ) (
"
k )
'
'.Ve have by definition
w h e r e the elements If w e replace o^ by
act on
by OlJTy .
the assertion of Theorem 10 remains v a l i d .
Moreover, w e have an immediate analogue of Proposition 11, A s for operators with discrete asymptotics for every
. P) (""k)
we can recover the conormal symbols, and then r j
1
(8)
is exact. For
216
JQm+q
we
have an immediate analogue of Theorem 9. The precise
formulation
is
obvious
and
left
In
( Q . P ) we h a v e a n a t u r a l
defined
by a s i m i l a r
Now l e t
u s make two
both 15.
for
procedure remarks
the d i s c r e t e
Remark.
only
X
exception
that
provided
fits
a discrete
R e m a r k . The c a l c u l u s
can
be g e n e r a l i z e d
to
respectively. by t h e
flat
section
subspaces
Note
of
the
specific 2],[l
also
transform
this
y
versions
every
that
the
sequence
conormal
in
of
the d i s c r e t e
every
^
of
Green o p e r a t o r s could but
We s h a l l
in
and
then has
to
between
our a p p l i c a t i o n s
deal
every J
1 + G (¡f-^-5")
spaces
distinguish
an
aQ.
and
M+G(if-f =
k+p=j
Repeating the conclusions in the proof of 1.4,1. Proposition 3 we get (with the notations introduced in the beginning of 2.3.3.) 1. proposition. Kor each N £ Z + , N>|t+1 and such that for each
S>0
there exists
^
N
X , 0 < X < N - p - 1 , X 4 ^ mod 2,
where P Q ( X ) = ( X . r ( \ ) ^ ) , such that for all u ۥ C Q
(R + )
N-l «¿op (a)u = ^ { A ^ ( S ) o p M ( g + ) + A - ( S ) o p M ( g - ) ] o p J=0
218
(l^-^S.xJJu+^ (2)
ju.
Proof«
Set
V s ^
= 5>oitt
V s
** •
( T )
where N-1 aN/S(t)
= a(-c) - ^ { A ] ( S ) 6
+
(X)
+ A-(8)e-(T)}
l^C«.*).
j=0 Since
|aN
we have
-1 + op^(0 ) = opM(g~)
I n v i e w of with
c
s
k e r n e l 6)b N j ( t - s ) .
(2)
Then,for
bN
6 H^P""1^).
g
f o l l o w s , where X under
g
is
the
operator
consideration
00 = |Jb K
i
cl u 1
P
0
( X )
N i
|
o
^P
0
(X)
L
Tho mapping p r o p e r t y
for
$
follows
cj N g h a s
b^ j ( s - t ) o i a s k e r n e l .
Note t h a t
t h e mapping p r o p e r t i e s
3N.S
j(t-s)u(s)ds
6
2. Definition.
The
t h e same w a y ,
since
0 of
* * 1
f o r
in
$ imply
mod
* * *
0
that N-r-1'
function
: = { a y i z ^ l
+
«¡g-(z+r)j
^ ¿ ¡ f J — j .
(3)
H I t 2+1 is
called
conormal order
t h e c o n o r m a l symbol of
, where
2.3.4. Definition
( 1+j » 0 ) } j ^ In 6 "
case 1
(a)
J«. 6 2 + 1
1).
>L,
to
the
= { (l-j-|«,0) ,(l+j ,0)j
ot>f
+
J
F o r -M-^ Z + we h a v e
,
X ot, f= { ( l - j - p . O ) ,
. a^ = a^
fe
belonging
(*•-!•
Note that (cf.
atSc^(|R)
for
1 = 0,1,...,L-1,
• where = { (1+j ,0) ] + can be r e p l a c e d by
^2
+ since
for
we h a v e 1 < L . I f , in p.. 1
i 8
addition, 8
Poly~
219
nomial then. If p. t 2 M.-1
ffj^ (a)
and
a^ ^ a^
for some
1, the conormal symbol z = 1,2,..., 1-J4.
has poles of second order at the points
Our next objective is to derive the Mellin expansion for higher order IpPO's on IR+. First we consider the case when the weight y
of the
desired domain of definition satisfies ^
>
max ( - f.p).
(4)
Then we know from 2.2.1. that there are continuous extensions of
op for all
— •
ae-r-t-r
s£IR. The Mellin operators
. We get from
.
) . is the Mellin
(2) a finite sum of terms of
the form A~(8)Skeao(Y1(g±)tlt+J+k'r
opM(Ak>._
k=0
'
For given
1t2+
all terms with
term with conormal order pendent of letting
j+k = 1
. >
contribute to the Mellin
-(tf-p+l). Since the left-hand side is inde-
S j we may simplify the calculation of the Mellin
8 — 0 ,
i.e. we take into account
symbols
only the absolute terms of
the polynomials in ^ . We have
AÎ and only
k=0
< > ° = aÎ
occurs
, i.e. j=l. In view of
« f ^ r ^ ô op^gV*1-!*) =
T
r - v
we get ( ° P ^ ( a ) H 2 ) = l a Î 9 + ( z T ) • a^g-(z T )J
^ ( a
It remains to find the singularity type of the Green
) (z).
remainder
terms.
Clearly tJ-rf
(tg)
k
oP;
(
hkiJ
¿ r f - s . ^ - r " ' * - ^ )
k=N and ùop^g1) e
for each
^opM(g
X S f -f+j+N, i
Jt^TJ" k=N
and
\ 4 -g mod 2,
r!
(tS)kopJ(hkfj
therefore
¿CK. 8 , t f . DC^-iJ^). '
0
setting
221
N-l j=0
k=N
w e gat
g1 t
Consider
. ^"(x')
now
N-l
N^l
j=0
k=0 N-l
- cit-r y ^ o p j t a Mr t a ) ) « * 1=0
,
where by d e f i n i t i o n of
a l l M e l l i n s y m b o l s of order >
v a n i s h . C o m m u t i n g on the right
+
op M (g"~) and
+
^ w e get in v i e w
of 1 . 3 . 1 . P r o p o s i t i o n 8 G r e e n o p e r a t o r s w i t h image in The a r i s i n g M e l l i n o p e r a t o r s of c o n o r m a l order of o r d e r
$ p - N h a v e image in
jw. - N
(j + k—
)^
> p-N d i s a p p e a r and
in the second a r g u m e n t . For
t _ X
N o t e tha't for
X'2 0,
5u( j ) = 0, j = 1,2,... ,
°PM(hk,j-r)^
terms
g N £ w e proved that it is a g a i n
the other c o n t r i b u t i o n s w e use that for u £ C ^ (IR+) such that
those
.
F i n a l l y , we e s t i m a t e the s i n g u l a r i t y type of the G r e e n r e m a i n d e r
V
For
f j mod Z a n d
+
= °PM(T"Xhk,j-r)
t C^" (IR+),
0 t h e r e a r e no z e r o s of
(j>(z) at
zf|R+.
Set V ^ )
= Z
°X
k=0
Ijr} i B^cJt.JuteJds.
c
Then
U>u(z) -
for a r b i t r a r y
222
(9) m
»-i
4j^u(z) v a n i s h e s at j = 1 , 2 , . . . , [ ^ X J and u feC* ( R + )
(8)
*
implies
where
II
oj.^, is a Green operator of the form
f
g"u(t) A
k const. and set for N fc 2 + N-l
,.
b[N)(t,s) = ^
b(t.O) O ( s )
k=0 and
b | N ) ( t , s ) = b(t,s) - b [ N ^ ( t , s ) . Then
opG(b£N))
is
finite-dimen-
sional and °PG(b- N - ^ .
N o t e that similar a r g u m e n t s w e r e u s e d a l r e a d y in the proof of Theorem It will be proved below that an a r b i t r a r y
^DO
on IR+ a d m i t s a n
sion to spaces with n e g a t i v e w e i g h t s after m o d i f i c a t i o n by a dimensional
3.
exten-
finite-
operator.
6 . T h e o r e m . Let
K frS^iR)
a
- i < \ if
opG(b^«> = KR'^XI: M * [ F Í L [H RES R L A Z) = R(»T • k=l
k= 1
k=l
j=l
z=j
This proves (15). In the same way (16) and
(17) are proved. Then the
mapping properties of the Green remainder operators of the Mellin expansion are proved by the same arguments as in the proof of Theorem 3. 0 7. Remark. The modification of the pseudo-differential action by a finitedimensional operator necessary also for
for obtaining an extension to negative weights is
\|/DO's
with the transmission property. In this
special case it is well-known that without modification we cannot exs 1 * pect a continuous action even on H (IR+), s < However, op^(l_) defines a continuous action op ( £ ) for all For given
s H S (IR + )
H 8 _ i t (IR + )
s €IR. |*.£IR
we call a weight
^
admissible
(with respect to
)
if £ - J«, f | mod 2 + and In particular, for dition and for
1 1 max(^, ( S ^ (IRxR ) ] . +
h
—
afcS^(R+xR)
is equivalent
to
a(t,t) e S^ 1 (R + x|R)nc < "(R + xR) and the symbol estimates hold uniformly in t near t=0. to
8 . Definition.
Let a(t
e-S^flR^xR) and
a(t ,t)
be j=0
the Taylor expansion for « { . " W i
: =
t — > 0 , a^^(x) = ^1(02— J-Vrat3 XyM" j + k=l
k
(>
[ i l
)(
z
'
(O.tjts',, c
Then
>
is called the conormal symbol of a belonging to the conortnal order
The sequence
where
j*. ) = j ( - j - ^ . O ) , (l+j,0)j ] (-2
normal symbol of
•
is
c a l l e d
the
complete
a t S^ 1 (|R + xR).
Consider the decomposition N-l t J a t j J(Tr) + a N ( t , t ) .
a(t,t) j=0 Then
229
b N (t.-C) = t"
N
I*
aN(t,t)
tS^d^xR).
Now we can apply Theorems3,4 and 6 to o p ^ ( a N ) . For each S
S
s tIR
0
¿¿CX '°.0< -r' ).
op ( a ^ J ) , Y
it
remains to consider
op^(b^) has a continuous extension i n
therefore :3 const., 1 1 , $ ^ mod Z . For N sufficiently large there exists c-fil g(t,s) =
gk(t)s k=0
g^ (r
T p-+
[-^-"i}^
depending on
a - ^ - , j +l < N
op^(a) - o p Q ( g ) extends to an operator in ¿ Q < (-ft
| mod 2
and in
¿(]
?)-g + (z + f«+Y>)g + (z+n+\>) = g + (z+(i+^) ^ g + ( z + N>) + g"(z + V)^ - g + ( z + | u W ) g ~ ( z + V ) - ( g + ) 2 ( z + p+^)" = g+ (z+f*+i?)-(g + ) 2 (z+p+i>)-g + (z+p+v>)g - (z+\?)
trfà.
In the same way we obtain g~(z+^+^)g~(z + -i) = (g~) 2 (z+(m+V) mod 1Ï?
\'
This yields
j+k=l
j + k=l mod Qfft^ . Thus the desired identity follows from(19). It
remains
discuss the case of t-depending symbols. It obviously suffices to consider symbols of the form
Since the
composition is associative, we may restrict ourselves to
the cases j,k = 0,1, where
j=l is trivial, if we have the result for
j=0, k=0;l. fkl Moreover, for k=l we may assume considered, it
b
' = 1. Since
remains a ( t ,t) = a(t), b(t,t) = t.
By definition we have
and a #
234
t = t a + D^a,
0
for
1
for
Now
k=l,
j=k=0 was already
s | ^ J ( t a ) ( z ) = 0-[;-j+ 1 ( a ) ( z )
and or^(Dxa)(z)=
{(Dta);gt(z+r)+ ( V ) - g - ( z + r ) ]
From a ( t ) - o ^ a j (it)r~ J it follows
f
ffcffl^ ))
( D T a ) j = (^-j + i ) ^
^
Thus
We have to show
^
j+k=l
i.e. C ^ - J ( t a ) ( z ) + (Tf;~ j (D x a)(z) =
such
take
that
.
enlarging
the domain of
definition
0P (a)
i
1 j ^ mod 2 ,
1 T f - p - ^ í j mod 2 ) w h e r e
of a ( n o n - c a n o n i c a l ) In
thelattercase,
obtained
projection
we g e t ,
by r e s t r i c t i o n
d o not a f f e c t
of
Let
a
course,
a realization
from s u i t a b l e
K fcS'clj3t
is
defined
by means
*
3
-T> T 2 < 4 " >
x'
th
lR n
fjn_ ^ =
fl
C n
K "i ho norm i n
R
Lemma 1 t r e a t s
c o o r d i n a t e which w i l l Later
in a special
later
on we s h a l l o f t e n
be t h e n o r m a l d i r e c t i o n
use
normed s p a c e
CK
of
continuously
(in
general
«¿'-depending
norm
the
functions not
II v i Clearly, general
all not
the
I M
2
s
H
We s h a l l
cut-off
norms
use,
for for
point
(distributions)
of v i e w .
on IR +
norm p r e s e r v i n g ) .
v||
different
Given
where
< f > )
2 s
H
F
'
u
,Rn-l
large
in
function
( L '
)
S
2
. Thai the
particular,
cO we h a v e
the
spaces
CKs,lf(R+)
s
¿U'
HS(R)(£)
^
^'-depending
result
254
proof
a
but of
a
0 < s ' * (IR
= d o *
8
( R
2
. _ H®(R+K£>
=11
*
V)e
+
"V)9|F(e+(i-ti)v(T)|
= the
acts
•
+
).
For an
)
+
of
Lemma 1 ) .
Therefore
(i-i^M
2
tx
arbitrary
( l - t i ) H ® {¡fT^)
n o r m s we g e t
lld-^MI
(cf,
ot^
are equivalent,
tt v | ~ 11 C0v|[ + || ( 1 - i i ) vll __ 0< e q u (IR R +s ), i . e . t h e r e iHs® (aR + )c o n s t a n t