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Lecture Notes in Mathematics A collection of informal reports and seminars Edited by A. Dold, Heidelberg and B. Eckmann, Zurich
331 Summer School on Topological Vector Spaces
Edited by Lucien Waelbroeck Universite Libre de Bruxelles, Bruxelles/Belgique
Springer-Verlag Berlin· Heidelberg' NewYork 1973
AMS Subject Classifications (1970): 46-02, 46 A xx
ISBN 3-540-06367-6 Springer-Verlag Berlin' Heidelberg· New York ISBN 0-387-06367-6 Springer-Verlag New York· Heidelberg· 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 1973. Library of Congress Catalog Card Number 73-83244. Printed in Germany. Offsetdruck: Julius Beltz, Hernsbach/Bergstr.
PREFACE This volume contains lecture notes for five of the six series of lectures at the Summer School on Topological Vector Spaces, held at the Universite Libre de Bruxelles in September 1972, and a summary of the four invited Seminar talks. The missing series of lectures is that of L.TZAFRIRI, on Special Banach Spaces.
A separate issue, probably in this Lecture
Notes series, co-authored by L.TZAFRIRI and J.LINDENSTRAUSS, will be an expanded summar} of TZAFRIRI's talks. Let all those who helped make this Summer School a success find here an expression of my gratitude, contributors, participants. the secretaries of my Mathematics Department, and foremost the NATO Science Committee who run a very effective Summer School program and financed this specific meeting.
Lucien WAELBPOECK
TABLE OF CONTENTS
Lucien WAELBROECK
"Topological vector spaces"
"locally convex spaces" Henri HOGBE-NLEND Joseph WLOKA
"Gelfand triplets and spectral theory"
Henri BUCHWALTER Ernst BINI Marc DE WILDE
"Techniques de bornologie en des espaces vectoriels topologiques"
"Fonctions continues et mesures sur un espace compl etement ier"
"Convergence structures on S(X)" "Various types of barrelledness and increasing sequences of balanced and convex sets in locall} convex spaces"
.
1
41
84
163
183 203
211
David J.H.GARLING : "Lattice bounding mappings"
218
Philippe TURPIN: "Linear operators between Orlicl spaces"
222
CONTRIBUTORS Lucien WAELBROECK.
Universite Libre de Bruxelles
1050 Bruxelles, Belgique. John HORVATH.
University of Maryland
College Park, Maryland 20742. U.S.A. Henri HOGBE-NLEND.
Universite de Bordeaux
33405 Talence, France. Joseph WLOKA.
Universitat Kiel
23 Kiel, Deutschland. Henri BUCHWALTER.
Universite de Lyon I
69621 Villeurbanne, France. Ernst BINZ.
Universitat Mannheim
68 Mannheim, Germany. Marc DE WILDE.
Universite de Liege
4000 Liege, Belgique. David G.H.GARLING.
Cambridge University
Cambridge CB3 9DA, England. Philippe TURPIN.
Universite de Paris-Sud
Centre d'Orsay. 91405 Orsay, France.
- 1 -
TOFOLOGICAL VECTOR SFACES I . WAELB ROECK 1. Generalities
A topological vector space
1.1.
(E, 'b)
is a k-vector space, with a topol09J tions continuous.
on a topological field
k
making the algebraic opera-
What I intend to saJ applies to real and to com-
plex vector spaces.
But I have acquired poor habits, and will only
consider in these notes complex spaces, henceforth
k
=t
with its
usual t.opol cqy . We wish the addition map cation
. : t
x
E
+ :
E
x
E
E to be continuous.
is a topological group.
The topol09J
V of neighbourhoods of the origin.
0 And
E and scalar multipliA topological vector space is determined bJ the filter
v
is the filter of neigh-
bourhoods of the origin for a vector space topologJ when a.
V U EV ] V E \/: U :J V + V
b.
The filter
c.
The el ements of If
J
has a balanced basis are absorbing.
A proof of the fact that the filters with properties a, b. c are exactlJ
the neighbourhood filters for vector space topologies is con-
tained in all standard texts on topological vector spaces (cf. e.g. [71, paragraph 15 or [19 J chapter I, paragraph 1).
The definition of
a balanced set and of an absorbing set must be given however. ACE lsi an
1. £
is balanced when
sa E A follows from
On the other hand, ACE
> 0 can be found such that
is absorbing when for every se E A follows from
observe that the set of absorbing subsets of balanced basis.
a E A, sEt,
E
lsi
O}
is the
basis of the neighbourhood filter for a local1} convex topology weaker than the given one.
The locally convex (semi-normed) space ob-
tained in this way is called
EV; the elementary properties of locally convex spaces are obtained by exhausting in some way or; by means of these semi-normed topologies. When
V is balanced. absorbing. but not convex. {sV
is not in general a neighbourhood basis.
I lsi>
O}
To obtain a neighbourhood
basis. we have to start out from a balanced neighbourhood
V. in a
topological vector space. and define
Vk inductively in such a way is a balanced. absorbing neighbourhood for all k. and
that
Vk Vk_1 :? Vk + Vk' We can define an "elementary neighbourhood ahain" as a sequence (VI' V2' ... ) with each Vk balanced, absorbing, and quite a bit of the baby Vk :? Vk+ 1 + Vk+ 1' The reader will
work that can be done in the locally convex case through the consideration of the space
EV' will be repeated here, but replacing absolutely convex absorbing V by elementary neighbourhood chains. Norms, semi-norms, and systems of norms and semi-norms define
1.3.
locally convex topologies.
To obtain general vector space topologies.
we need more general objects. ft,n
If
3-semi-norm is a mapping
a.
'..' (x + y) .;;;; v(x) + ') (j)
b.
vOx) .;;;; \' (x)
c.
V(AX) v
These are the i-norms and l-semi-norms.
for
for all
,
v
for
x,
scalar,
x
and
: E
such tn at
F+
y E E;
1>..\ .;;;; 1
x scalar.
does not vanish off the origin. then
and A v
x
E
E;
O.
is an ;1-norm.
It is clear that an 1-norm, an 1-semi-norm, or a system of 3-norms and !-semi-norms will define a vector space topology in
waj
- 3 -
quite analogous to the locally convex case.
If
v
is an g-semi-norm
and
then
VI" ... , Vk, ... is an "elementary neighbourhood system". Conversely, everJ vector space topology can be defined by a sys-
tem of :I-norms or 1-semi -norms.
What we need to to is associate an
1-semi -norm to each of the elementary neighbourhood chains. Let thus let
VI"
s,O",s",1
k, q
integers);
be an elementarJ neighbourhood chain; be a dyadic rational (i.e. a number 2 -k q with express
s
in the dJadic scale s
where the
kp
=
2
-k
p
are integers, different from each other, and let
Ws = E when s ;;;. l. A little thought will show that W c W s ' , and s' when s s that Ws + W C W . A hint maJ be useful to help the reader s2 - sl+ s2 1 to think. Complete this definition, putting
"
The ordering of dJadic rationals is, of course, the phic ordering of their sJstems of digits in the dJadic scale. assume that S
I
for
s < s'.
This implies that the first
coincide, but that for some s'
is
j ,
the digit for
This gives us a term
Vj
of s
is
We sand
0, that
in the expression of
and no such term in the expression of
Ws I, At most the furtherdigits
for
s
s'
unitJ.
Ws' would all vanish, while those for
This would give us something like
expression of Vj
l.
W s.
Vj+ 1 + Vj+ 1
would all be equal to
Vj+ 1 + ... + Vk in the But an inductive application of the relation
shows that V. ::> V. 1 + •.. + Vk J J+
- 4 -
W + W C W i 5 not very dif51 52 - 51+5 2 What one really must do is carrJ out the addition s1 + 52
The idea of the proof that ferent.
in the dyadic scale. look out for what happens at each carrj over. and. when considering the 5ets
Ws
remember that
V. + V.J c V.J- l' J
We then define
It is clear that
v
is an ]-semi-norm whose kernel is exactlJ the
intersection of the neighbourhoods bj the sequence of sets
Vk
Vk. Also. filter generated is the same as that generated bJ the
sets {x
We
I
v(x)
e;}
have shown that vectorwpologies could be generated bJ J-norms
and 1-semi-norms. The reciprocitj between absolutelJ convex absorbing sets and usual norms and semi-norms is alreadj not perfect in the locallj convex case.
It is even worse here.
But it is good enough if we are
concerned with neighbourhood filters. rather than individual neighbourhoods. The fact that a Hausdorff vector space topologj is metrizable if and onlJ if the origin has a fundamental sequence of neighbourhoods is clear. (and well known).
A metrizable vector space topologj can
also be defined bj a single }-norm. 1.4.
A subset
uniformlJ for that an
E
B of a topological vector space is bounded if s
scalar. s
> 0 can be
origin in such a waJ that 5ubsets of E.
O. and
x
ranging over
B.
to everj neighbourhood sB C U when
!sl
E.
sx
This means U of the
The set of bounded
E is clearlj a vector space boundedness (bornologj) on
It i5 the von Neumann boundedness of
E.
Another bounded structure can be defined canonicallj on a topo-
0
- 5 -
logical vector space. the additive boundedness.
B is additivelj
bounded iff one can associate a positive integer bourhood
k
to everj neigh-
U of the origin in such a waj that BCU+ ... +U
(k
terms)
Additivelj bounded subsets of locallj convex spaces are bounded. in general. U + ... + U is much larger than
But
kU. we must expect the
additive boundedness to be much grosser than the usual. von Neumann boundedness. We shall see that a set
B is additivelj bounded iff everj
continuous 3-semi-norm is bounded on
B.
It is clear that continuous
3-semi-norms are bounded on all additivelj bounded sets. assume that
B is not additivelj bounded. let
of the origin such that Let
v
OJ 1
U be a neighbourhood
U + •.. + U for anj number
be an 3-semi-norm such that
v(x) > 1 for
k of
x, U.
0 and
a real number
M exist such that
p{Mt)
(I +
for all
- 9 -
If the condition is satisfied, the ball of radius the ball of radius
(1
absorbs
E).a, hence all balls of finite radius, and
+
better, the ball of radius radius.
a
a
is absorbed by all balls of non zero
As a matter of fact, if
f o ( I f I) dm we see that
" (1 + c ) a
f o ( I f II M) dm
" a
and this proves the result. This sufficient condition cannot be necessary in all cases. If
m is a finite measure, Lo
depends only on the behaviour of
in the neighbourhood of infinitj.
For
Lp
p
to be locallj bounded.
it is therefore sufficient that 1i min f t-- P(M t ) I p( t) > 1 fol" some
M E IR+.
Similarly, when we consider behaviour of
p
as
t
0, hence
.I'.
p
will be locally bounded if
p(Mt)/p(t) > 1
lim 2.5.
lp' the space depends only on the
On the other hand, assume that
that
m is not purelj atomic and
lim inf t __ p(Mt)/p(t) = 1 for all Lp (n,a.. m) is not 1oca 11j bounded. Since
1i m inf p(Mt)/p(t)
find a sequence M.
We choose
tn s
>
00
0
'=
1
such that
and let
an
M.
for all
We shall see that it is possible to
M,
p(Mtn)/p(t n) 2r/p(tn)·
1
for all
We also choose
n
En c 0
with
mEn = an' such a set exists if n is large enough. We next define a function f n = t n on En' f n = 0 off En' The function f n belongs to the closed ba 11 of radius 2e::. This sequence is however not absorbed bj the ba11 of radius
E.
and
Jus t
- 10 -
cons i der
since
p(tn)mE n
= 2£
and
p(tn)/p(tn/M)
1.
This proof can be adapted in cases where
m is pure1j atomic,
and has atoms of sufficient1j large measure, saj the atom of order Also, if p(Mt)/p(t) 1 as t has a measure larger than a- k for all
k 00
M, it is not difficult to change the above proof and show
that
Lp is not 10ca11j bounded as soon as ri1j small measure.
m has atoms of arbitra-
I have not carried out the computations, but I am convinced that a 10ca11j bounded would be
Lp
could be constructed, where the measure space
IN, the atom
k
having the measure
11k!.
and where
lim inf t 100 p(Mt)/p(t) = 1 for all M. If I maj state a stronger conjecture: I am convinced that somebodj has a1readj carried out these computations. 2.6.
Assume now that
that
n
o
1
lim lp(l)
k
is 10ca11j bounded iff some
k
(a)
exists with
p(kt)/p(t) > 1
lim
(b)
lp(lR) is 10ca11j bounded iff conditions (a) and (b) both hold. 2.8.
We must fina11j speak of the additive boundedness of the Or1icz
spaces.
We shall see that this is equivalent to the metric bounded-
ness in the three standard cases. i.e. when n = I. rl = F • or
n =
each of theses spaces being equiped with the standard measure.
When.
rl
=
}l •
we shall assume that
p(t)
co
as
t
"".
This does not af-
fect the topo10gj or the additive boundedness. but it does affect the metric boundedness. A set is metrica11j bounded in a metric space if it has finite diameter.
We consider on an Or1icz space the distance associated to
the :Inorm vp(f) = J p(lfl)dm It is clear that an additive1j bounded set is metrica11j bounded.
- 12 -
Assume conversely that where
is a diffuse measure space.
Q
where
k>Mh can split and
f
vp(f i)
M E lR+
= f1 + = M/k
0
Let
o
k
and
E
}l •
v (f) < M when f E B. We o + f k where the f i "sit" on disjoint sets This shows that B C :r1k U. i f U is the open is such that
i . e.
is additively bounded.
B
lp. assume that
metrically bounded in
L (Q)
is metrically bounded in
B
pet)
as
00
t
00.
Let
B be
lp. B is contained in a ball of radius
with center at the origin.
We can split each
a E B as
a
M
= a1
+ a2
aI' a 2 have disjoint supports, where the absolute values of the components of a 1 are larger than n if pen) = E/2, while the absolute values of the components of a 2 are at most n. The set of
where
al
under consideration is bounded in
supported by a set with
k
loo' and each of its elements is
elements. where
k > 2M/e:.
It is not dif-
ficult to show that such a set of elements is additively bounded in ,(
p
. We must still show that
a2
ranges over an additively bounded
Of course. v p(a 2) < M, the components of a 2 are less than n with pen) £/2. We can split each a 2 under consideration as a2 = bo + b I + ... + br where the bk "sit" set. when
a
ranges over
B.
on disjoint sets. and where
£/2 < v p (b.) < 1
These inequalities imply that
r
under considertation belongs to £
E,
= 1•...• r.
when
M/2£ < k, hence each of the U when
U is a ball of radius
and center at the origin. We observe that the additive and the metric boundedness of
do not coincide any more when of
a2
lp
p
is a bounded function.
is metrically bounded as soon as an integer
such that each
b E B sits on a set with
k
k
elements.
E
lp
A subset exists The metric
boundedness is not separated. but the additive boundedness is separated.
B
- 13 3. Variants on the notion of an Orlicz space
3.1.
The Orlicz spaces are the first examples of non locallj convex
spaces that one encounters.
It is well known, but it must however
be said explicitlj, that the space of measurable functions on a finite measure space, with convergence in measure, is a special Orlicz space.
Just take, for
t
E
IR+, t
p(t}
l+t
More general spaces of Orlicz tjpe would be obtained in the fol-
(n,o., m)
lowing waj.
p: II
be a mappi ng that
p(x, t}
each
x.
would be a measure space, but now IR+
x
-+
IR+ ' whi ch woul d be measurable, and such
is subadditive in
The space
L
p
would
p
(lI, 0., m)
t
and tends to zero as
t
-+
for
0
would be the space of functions
f
such that v o (f)
= f o I x , I f I} dm
) 6l E which approximate u uI'd form 1jon the i r dom a ins. Tietze's theorem allows us to extend
• 30 -
elements of
C(X i) A E to
C(X) A E.
vi' and call these extensions again Let let
We consider such extensions of vi.
U be an open balanced neighbourhood of the origin in
V be open. balanced. such that
above gives us functions when
x E Xi.
then
Ai
¢
V + V.
The construction
vi E C(X) i E such that
u(x)· vi(x) E V
Let
is open. Ai
a function
U
E.
Xi.
Urisohn's theorem shows the existence of
with compact support in
A2. The function v
AI' such that
- ¢
has com·
pact support in
=¢
u(x) - v(x) E U for all
vI
(1 . ¢)v 2 x E X. +
belongs to
C(X) A E. and
The above remarks do not tend to make the existence of a compact set which does not have the densitj propertj un1ike1j. show that such a space 8.2.
Thej on1j
X is difficult to construct.
The density problem is related to the approximate extension pro·
b1em. or when Let
E is a metrizab1e space. to the extension problem.
Y be compact. let
X he a closed subset of
E be a topological vector space.
(X, Y, E)
tension property if restriction maps C(X. E). (X. Y, E)
Also. (X. V)
r(Y, E)
Y, and let
has the approximate exon a dense suhset of
has the approximate extension property if
has the approximate extension propertj for all
has the approximate extension if tension propertj for all (X, I. E) C(I. E)
onto
couples
XC I
(X. Y, E)
E.
And
E
has the approximate ex-
X C Y.
has the extension propertj if restriction maps C(X. E).
The definition of the extension propertj for
of compact spaces and for topological vector spaces
E is clear and will be left to the reader. (X. I. E)
has the approximate extension propertj if
(X, E)
has
- 31 -
the densitj propertj.
Converselj. if
(i. E)
extension propertj. and if (X. E)
has the rlensitj propertj. then
(X. E)
u E C(X. E).
has the densitj propertj. and that
We can find
v.
Then
u
XCi.
v E C(X) i E approximating
is
u.
w E C(i) A E exten-
Tietze's theorem proves the existence of some ding
has the approximate
has the densitj propertj.
Assume that Let
(X. i. E)
extendable. and
(X. i. E)
has
the approximate extension propertj.
(X. I. E)
Converselj. assume that sion propertj and that u E C(X. E).
has the densitj propertj.
v E C(i. E)
We can find
which extends
w E C(I) A E which approximates
telj. then tion of
(I. E)
has the approximate
w to
X belongs to
C(X) A E and
v
on
.
let
u
I.
approximaThe restric-
approximates
u.
This result relates the approximate extension problem verj directly to the density problem. probability measures on
We let
0
is said to be: absorbing if for
1/)
A locally of
which satisfy:
and
W:> V,
then
"'1 E
10 ,
(2) every VE 10 is absorbing, (3) any finite intersection of sets belonging to 10
contains a
balanced, convex set belonging to 10 (4) i f V E 10
A > 0,
and
AV E 10 .
then
A vector space equipped with a locally convex structure is called a locally convex space.
Any V E 10 contains the origin
10 belongs to 10
section of sets belonging to
A -J 0, then
E and
F
(by 3 and 1); i f V E 10 and
be two locally convex spaces whose structures are
defined by the collections 10
and 110,
respectively.
is a morphism of locally convex spaces if f: E
belongs to f E
(by 3); any finite inter-
AV E 10 (by 3, 4 and 1). Let
morphisms
0
;c (E,F),
F
form a vector space
(E,E); if
A linear map
(VI) E 10 for all
;;c, (E,F).
f: E-+F
VI E tv).
The
The identity map
are three locally convex spaces, and
E,F,G
g E. X. (F,G),
f
-1
gaf E :t (E,G): the locally convex spaces form
then
a category. Let ""t:
1.3. (x,y)
x + y
from
E
>< E
be a topology on into
E
and
E
( A, x )
such that the maps
.!I x from
are continuous and assume that
0
which consists of convex sets.
Then the collection 10
of
0
IK x E
into
E
has a fundamental system of neighborhoods
satisfies conditions (1) - (4).
of all neighborhoods
Conversely, if a locally convex
- 42 structure is defined by a collection
x + V,
then the sets
will be the collection of all neighborhoods of the point which the maps
x
where
for a topology for
are continuous and each point
possesses a fundamental system of convex neighborhoods. the oontinuous linear :maps.
Themorphisms are then
This method of introducing locally convex spaces
(i.e., locally convex topological vector spaces) avoids introducing preliminary topological concepts [75].
1.4.
Let 1!J.-
the vector space and
be a collection of absorbing, balanced, convex subsets of
E.
10
Then the collection
of all sets
contains a finite intersection of sets belonging to
V
A W, A> 0,
convex structure on tions
, or equivalently
satisfies (1) - (4) and so defines a locally
WE!{f,
E,
0
V which contain a finite intersection of sets of
the collection of all sets the form
A>
where
V,
said to be generated my
Two different collec-
can generate the same locally convex structure.
all balanced, convex subsets belonging to
The collection of
generate the locally convex
structure defined by 1) .
A seminorm on
E
is a map
positive real numbers which satisfies
IAI
p(x )
for all
x,y E E,
/\ Ell 0,
of
1
J
balanced, convex the closed se.mi pE
generate
Conversely, every locally convex structure
can be so generated since the gauge ("Minkowski functional") inf { /\
+ p( /\ x )
The closed semiball {x \ p(x )
balls (or eqUivalently the open semiballs) pertaining to the a locally convex structure on
IR
Pv(x)
xE /\ V} of an absorbing, balanced, convex set
is a
V
seminorm.
1.6. space.
Example.
Let
A Nachbin family
continuous functions on
X if
be a completely regular (Hausdorff) topological
on
X
is a collection of positive, upper semi
X such that for
v
l,v 2
E":
11
and
:A> 0
(X) ) v(x), x EX. Denote by l(x),AV2 vector space of all continuous functions f on X such that
VE?f with max(Av
for all
v E lJ.
sup Iv(x)f(x)\
xEX
The family of seminorms
(p) given by v VE 1f
defines a locally convex structure on
r
there exists
Z! (X)
vf
is bounded
P (f) v
e 1t" (X).
the
- 43 Particular cases:
a) if
is the collection of characteristic
functions of compact subsets of X,
t: 11 (X)
then
r::
is the space
(X)
of
all continuous functions. and the locally convex structure is that of "uniform convergence on compact sets"; b) i f ?r
..8
space
t: 7F (X)
is the set of all positive constants, then
is the
of' bounded continuous functions with the locally convex struc
(X)
ture of uniform convergence on X;
'if
c) if
is the set of all positi ve , bounded, upper semicontinuous
e >
functions which vanish at infinity (1. e . , given set
such that
KC X
Iv(x)I
C
if
x¢ K), then
there exists a compact
0
e2J(X)
is J:3(X)
with
the strict topology of R.C. Buck and van Rooij; d) if X is locally compact and (icompact and
e 7J(X)
of all positive. continuous functions, then
Lr
is the collection
is the space
of
J'{(X)
continuous functions with compact support, and its locally convex structure corresponds to the usual "inductive l:Lmit" topology (cf. 1.9).
t: '2J (X) and their vectorvalued analogues consult
For properties of
the works of K.D. Bierstedt, W.H. Summers and the references quoted there.
1.7. space tures
Let 11) 1 and 1IJ 2 be two collections of subsets of the vector
E satisfying (1) (4) of 1.1 and defining the locally convex struc-
oe 1
and
'7::2 ,
coarser than L 1)
ee2 )
1.8.
respectively.
11)1 ::) 1f}2'
if
than L
is
(or
"'C'2
is
IE: (E, 'r'l)
is a morphism. Let
be a family of locally convex spaces; suppose that the
locally convex structure f...
"t'l
2 1. e., if the identity map
.or:
of E...
V... '
is given by
be a linear map from a fixed vector space
E
and for each
into E...
of all sets (or of the balanced, convex ones) of the form generates the coarsest locally convex structure on
The collection f;l(V... ),
subspace of
E
and
convex structure on
j:
a) Let E L c..;. E
be a locally convex space;
the canonical injection.
L with respect to
j
V... E hO '
E for which all the
are :morphisms, called the initial structure with respect to the Particular cases:
let
t:
f...
f.... L a linear
The initial locally
is the induced structure.
be a family of locally convex spaces, E = ITE ... ... the product th the'" projection. The initial of the vector spaces E... and b) Let
E.
locally convex structure on structure.
E with respect to the
pr...
is the product
- 44 1.9.
Let
be as in 1.8 and for each t.. let
(Et.). (ce:), (10.. )
a linear :map from
E..
into a vector space
ing, balanced, convex subsets
V of E
E.
f:l(V) E 19..
E
subspace of E
'f
and
ElL.
vector space
for all
for which all the
are 'morphisms, called the final structure with respect to the a) Let E
be
The collection of all absorb-
such that
generates the finest locally convex structure on Particular cases:
f..
be a locally convex space;
the canonical surjection from
E
I-
fl-
f .. L a linear
onto the quotient
l'
The final locally convex structure with respect to
is the quotient structure. b) Let E.
be a family of locally convex spaces,
ternal) direct sum of the vector spaces final locally convex structure on
EI-
and
j..
E
=
UE .. I
the (ex-
the t..-th injection.
E with respect to the
jl-
The
is the locally
convex direct sum structure. 1.10.
Let E
the collection 1f)
of subsets.
'>. > 0
there exists subsets of
be a locally convex space whose structure is given by
E
(L) if
A set
ACE
A C A V.
such that
is bounded i f for every VE
The collection $
and AE
B C A, cover
d(;
B E Jr ,
then E,
(iii) any finite union of sets belonging to balanced, convex set belonging to
If
Ae
»
/\ > 0,
and
is contained in a
, /. A c:,r;
then
E is a vector space and
.
a collection of subsets of
satisfies (t ) - (Lv ) , we say that equipped
of all bounded
satisfies the following conditions: AE
(ii) the sets
(Lv ) i f
is a convex bornology on
E,
which
E
and
a convex bornology is called a convex bornological space.
refer to [29J
1IJ
E
He
and to the lectures of Hogbe-Nlend in the present volume for
the theory of these spaces and its application to locally convex spaces [29, Chap. VII and IX]. 2.
Duality 2.1.
A continuous linear form
continuous linear map from E lK
Izi
f
on the locally convex space
into lK,
1. e.,
a morphism
f: E
E is a It o,
for
0
y EM.
g(x)
I-
O.
p(x)
for
x E E and
g(y)
=
fey)
= E. Y = M.
and satisfies
g(x)
From g(A x ) follows that
p( A x ) g(/\ x)
g(rx)
and 0
x E E.
for
p(x)
integers. we have
g
y EM.
= g
(mx ) = mg(
E
x)
for r.
for every positive rational Le .• g(l\x)
pC-Ax).
Finally if
which is additive on
ng ( ; x)
Since
A> O. /\-+ 0
as
f
of
rg(x)
=
g(-i\x)
for all positive real
-pC >'(-x)).
and consequently
< O.
g(;\x)
=
it
l\g(x)
g( I\x) = g(-i\(-x))
then
;'g(x).
=
2.8.
JR. such that
g: E
for
f(y);;;; p(y)
U = E and condition (a) of 2.5 is satis-
Clearly
fied. so that there exists an extension
-Ag(-x)
= O. and such that
p(O)
Equip E with the strongest order and apply Aumann's theorem
(2.6) with X
>0
M a SUbspace of E.
JR. be linear and
f: M
Let
Then there exists a linear form
Proof.
m.n
E.
be a finite. subadditive function on
p( A x) for
Theorem.
A generalization of a well-known consequence of the Hahn-Banach
theorem is due to Konig. (2.8.1)
Theorem [40J.
subset of E and additive and
p
Let
a finite sublinear function on E.
p(ftx) = Ap(X)
is
z E A such that
on
E with e(x)
E be a real vector space,
for
p(z - i(x+y)) p(x)
for
O. O.
A a non-empty
i.e..
Assume that for
p
is sub-
x.yEA
there
Then there exists a linear form
xE E and such that
t
inf p (x ) = inf ((x).
»:.A
XEA
Fuchssteiner [26J shows that a generalization of (2.8.1) to semigroups follows from 2.4. (2.8.2) space
E and
there is
Corollary p
[40J.
Let
B be a non-empty subset of a real vector
a finite sublinear function on E.
z E B such that
pf z - (x+y)) ;a O.
If
Assume that for
p(x )
0
for all
x.yE B x E B.
- 49 -
t
then there exists a linear form
t (x )
such that
for all
0
Indeed. the set
p(x)
for
x E E and
x E B.
i
A '"
condition of (2.8.1).
on E with I(x) x E B.
n
1
integer} satisfies the
From these two results Kbnd.g [40J obtains simple
proofs in a number of situations. in same of which the minimax theorem was used earlier. as for instance the separation of convex sets. the existence of a Jensen measure. the fact that the Silov boundary is the closure of the Choquet boundary. the Hoffman-Wermer lemma. the Glicksberg and the KonigSeever generalizations of the F. and M. Riesz theorem and their equivalenoe due to Rainwater. and results of GrUnbaum J Kirszbraun and Minty on quadratio forms.
2.9.
Another oonsequenoe of (2.8.2) is the following maximal theorem: Theorem [41].
(2.9.1)
Let V be a real vector space and
(v)
empty oolleotion of sublinear functions on V such that
if (v)
0 ; we get (1) by renorming H+ • A vector f E H generates an antilinear functional 1 on H+ as o follows leu)
=
If(u)
= (f,u)o = (f,iu)o '
this functional is continuous since by (1) Ilf(u)!
=
I(f,iu)ol < [[flf 0 '1liull 0 Hk and satisfying the equation (Au,v)l (u,A*v)k' u E Hk, v E HI' For u E H_ l, u E Hk we have
spaces;
[u,Au]o
(9)
(rlu,Au)l A+ =
(A*Ilu,u)k
=
I k A *11 1
and we immediately see that II A+ 1/
=
[Ik1A* IIA*II
lU'u]o
= IIAII.
=
[A+u,uJ o' where
.. 166 -
:r
We know that maps H_ isometrically into H+; we now show that this operator may be factored into two operators, the first of which maps H
-
isometrically into H , and the second H 0
0
'I
into H+,
The operator I acts continuously from Ho to H+, Since H+ this operator may be as acting in Ho'
Ho
I)
J
We introduce the notation "I operator
I
=
iI for the latter operator, The
is obviously continuous, nonnegative
{(2)
(ilf,f)o
= (If,If)+ :::: 0 ) , and invertible on R(I) {If = 0
I1IJ 0 = (If,u)+ (f,iu) ) iu dense in H f = 0 ; i is invertible) , We will show ",0 -1 0 A. ... that R(I) = .:D(I ) is dense in Ho: i f h.LR(I), then 0 = (h,If)o = = (Ih,If)+ = (ilh,f) for any f E H , therefore ilh = 0, and hence 1 h = 0, It is clear is is selfadjoint!) and
=
1-
(I
positive in Ho' Theorem 1,
Consider the operator I) =
in the space Ho' It is a positive selfadjoint operator for which I
I
»(I)) = H+, R(I)) = Ho' This operator acts isometrically from H+ to Ho: (u,v)+
(I)u,I)v)o'
=
u,v E H+ •
Consider I) as an operator acting from Ho to Hand form the closure by continuity; denote this operator by ]) , ]) acts isometrically from all of Ho to all
H : moreover (10)
(f,g)o
()f,l>g)_,
=
])
0
f,g
E
Ho ' and
I)
The relation (11)
(f,I)u)o
=
' f
holds, from which it appears adjoints of each other ( ]) = I) )'
Ho' u I) and E
»
E
H+ J are
- 167 -
I- 1 •
Equation (10) gives a factorization of that
I
(12) Here
From this it follows
= D- 1 ])-1 or, if we introduce the operator J = D- 1 T:=Jo;;
'7
denotes ,])-1; thus (12) gives a factorization of
I
into
isometric operators ., and J. If we replace f by } a and u by Jf in (11), we obtain
(7 a , f) o
=
(a,Jf)o' a
E
H_, f
Ho ' Le • ., = J+.
E
We list the basic properties of the isometric operators:
(r a ,
(Jf,Jg)
(l a, (13) ,
(a,
( Du , Dv ) 0 = }
= J+,
.J> =
(u , v ) + ' D+ :
The inclusion i: H±
=
(,) f, J) g) _
(') a, f)
0
(f,g),
=
=
(1 (f, g ) 0
;
= (a, Jf), (J) f , u ) 0 = (r , Du)
Ho is H.S.,iff
J is
H.S.
(J
=
0
iJ, i =
•
jJ- 1=
3D),' equivalently; iff i': Ho H is H.S. We now show how to construct a rigging given an operator T.(H.S. = Hilbert-Schmidt operator.) Let T be a closed operator in a Hilbert space Ho' having a dense domain (T) and such that
=
(14 )
IlTullo::: [v
ll
uED(T).
Obviously D(T) is a pre-Hilbert space with respect to the scalar product ( 15)
(u,v)+ = (Tu,TV)o )
and we can take the completion of this space as a positive space H+ and then construct a corresponding negative space H • Consider the operator D with respect to the sequence H+
H C> H ; o equations (u,v)+ = (Du,Dv)o and (15) show that D and T are metri-
cally equal (if T is, in addition, positive, then obviously D = T). 1 On R(T), T- exists and is continuous; it is metrically equal to
. -1 " = J. Thus II.D
From this and the assertion above
it follows that the inclusand only if T- 1 is H.S. Notice that in
ion H+ ---> Ho is place of (14) it is possible to use the estimate IITull U E
D(T)
> eIIull
0-0
with C > 0, or what is equivalent, that the equation
,
- 168 -
T*x = f is solvable for any . f E H0 and x depends continuously on f. Example. We consider for simplicity G = R Let s,t E R and n n. W(x,t) = (-1) where (a,b); we put
n
.
n
slgn(xl' .... x) TT n j=1
is the characterizatic Du
u
1 x 1 · ··ax n
(t J.) , function of the intervall
, D+ = (_1)nD.
It is easy to verify that for f E Lioc (R ) and u(x) E we have n Dx fW(XoJ)f(J)df = f(x), = u(I)) (16)
n
n
n
c,,(x,J)(Du) (!)d!
u( x ) •
Let us define T: (Tu)(x) = q(x)(D+uXx),
u
E
'>
D(T) =
where q(x) = (1 + Ix11)1+i ... (1 + Ixnl)1+{ , O. Using the second of the formulas (16) we find that the left inverse -1 . T is anmtegral operator (Tand
1f)(x)
f f
are bounded operators on H. The function (6) is called a nonnegative operator-valued measure, if it takes the value zero on the empty set, if the operators
e (A)
are nonnegative and if they
- 169 -
satisfy the requirement of weak countable additivity: for disjoint the equation ( 17)
holds in the sense of weak convergence. Suppose that the measure for bounded
g
(A)
=
Ii:
tr
(0
(f)))
0, il existe une pcu Cf = (Cfi) telle que
IhUH
pour toute
(3.3.2) COROLLAIRE. La topologie de Moo(T) et la ¢topologie coincident sur les bornes communs et sur Ie cone positif. En particulier elles \ ont les memes parties compactes. Or la
¢topologie est une topologie initiale d'espaces
sorte que les proprietes speciales des espaces
1
de
(I) se transportent
aux espaces Moo(T). Ainsi (3.3.3) THEOREME. Toute suite de Cauchy faible dans Moo(T) est conver!gente dans Moo(T). En particulier Moo(T) est faiblement semicomplet. (3.3.4) THEOREME. Pour toute partie s on t equivalentes : / a) A est relativement compacte ;
les assertions suivantes
- 198 -
b) A est relativement faiblement compacte ; c) A est b or-nee et, pour toute pcu f = ('f'i)' les familIes decrit A. = sont equisommables lorsque En suivant Haydon [H 1], et par un assez joli lemme technique, on en tire : (3.3.5) COROLLAIRE.- L'enveloppe solide IAI d'une partie relativement Icompacte A de Moo(T) est encore relativement compacte. 3.4 Questions d'ordre. La situation de l'espace MOO(T) a l'interieur de l'espace M(ST) des mesures de Radon sur ST est remarquable vis-a-vis des proprietes d'ordre. On sait deja que M(BT) est un espace de Riesz completement reticule. Or pour toute et toute pcu f = on a = alors que l'egalite a lieu pour toute (T) puisque Moo(T). Mais [R31 : 00
(3.4.1) THEOREME.- Pour qu'une mesure i I faut et il suffit que l'on ait pcu f = sur T.
I
soit element de Moo(T), = pour toute
Fixons HEClf, Het., et E >0 ; on sait deja qu t i L existe une p cu
=
et une famille de points de T telles que Qf-L:f(ti)CfilkE pour toute r s n. Donc en fixant telle que et en choisissant la partie finie J de I pour que L I u I E , on a ifJ l pour toute f E. H L
ilaJ
f (t . ) u (CD. ) l
'l
I(
E
Or L
ifJ donc
cp.) =
L
L
i J
l
to.)
i£J \
l
l
l
= pour toute fEH,
ce qui exprime encore que :
-
Et i II H' 2 E
et montre que est limite uniforme sur H de mesures discretes est donc continue sur H et Moo(T).
elle
- 199 -
D'ou l'on tire:
(3.4.2) COROLLA1RE.- Moo(T) est une bande dans l'espace completement re-
I
M( 8T) .
11 est facile de voir que Moo(T) est solide dans M(8T). Pour le reste, il suffit de voir que toute mesure positive u e. M(8T), borne s upe r-Leu r-e d'une famille filtrante croissante de mesures positives Moo(T), est element de Moo(T). Or pour chaque pcu = on a : = Sup u (1) = Sup Sup
L: (cp.) = Sup J iEJ Il J ou J decrit l'ensemble des parties finies de I.
L:
l
=
l
On peut terminer en caracterisant la bande etrangere a Moo(T) dans M(8T). Pour cela associons a chaque mesure positive M(8T) et a chaque pcu
= la mesure = L: On a et, de plus, la famille est filtrante decroissante, car si 1)J = (1)Jk) est une autre pcu, la famille = (tfi1)Jk) est aussi une pcu et u'f'l',I, = . Par ailleurs 'f' si ve. M (T) alors v'f = v, de sorte que lIon a pour toute ve.M (T) telle que . 11 suit de la que la mesure A = Inf majore toute 'f v EM oo( T ) telle que En f'a i. t : 00
00
(3.4.3) THEOREME.- La mesure A Ila composante de
= 1nf
est element de Moo(T) et c'est
'f
00
sur la bande M (T).
=
Posons pour simplifier
L:
iEJ
l
pour toute partie finie J de I.
11 suffit de prouver que l'expression L
L
= Inf Inf
J
= Inf
1)J
mais
1)J
=
=
=
est nulle. Or
J
=
J A(l), d'ou
1)J
J = O.
0.4.4) COROLLA1RE.- Une mesure
est etrangere a la bande Mco(T) s i et seulement s I il existe, pour tout 00, une pcu 'f = ('fi) sur T
l
telle que
On remarquera qu'on generalise ici au cas de Moo(T) 4n critere classique de Tamano [Tl selon lequel un c ar-ac t er-e u e. 8T est e x t e r-Leur' a 8T (ou etranger a Moo(T)) si et seulement s'il existe une pcu telle que
=
0 pour tout i.
- 200 BIBLIOGRAPHIE (B 1)
N. BOURBAKI, Integration, chap. IX, 1969, Paris.
(B 2)
H. BUCHWALTER, Topologies et compactologies, Publ. Dep. Math. Lyon, 6-2, 1969, p. 1-74.
(B
3)
(B 4)
H. BUCHWALTER, Parties bornees d'un espace topologique completement regulier, Seminaire Choquet, ge annee, 1969-70, n014, 15 p. H. BUCHWALTER, Sur le theoreme de Nachbin-Shirota, J. Math. pures et appl.,
a
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Voir aussi : Comptes rendus, t. 273, serie A, 1971, p. 145-147. Comptes rendus, t. 273, serie A, 1971, p. 228-231. (B
5)
H. BUCHWALTER, Espaces ultrabornologiques et b-reflexivite, Publ. Dep. Math. Lyon, 8-1, 1971, p. 91-106.
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3)
J. BERRUYER-B. IVOL, Espaces de mesures et compactologies, Prepublications St-Etienne, 1972. A paraitre aux Publ. Dep. Math. Lyon,
(BN)
H. BUCHWALTER-K. NOUREDDINE, Topologies localement convexes sur les espaces de fonctions continues, Comptes rendus, 274, serie A, 1972, p. 1931.
(BP
1)
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(BP
2)
(BS)
H. BUCHWALTER-R. PUPIER, Completion d'un espace uniforme et formes lineaires, Comptes rendus, 273, serie A, 1971, p. 96. H. BUCHWALTER-J. SCHMETS, Sur quelques proprietes de l'espace Cs(T), J. Math. pures et appl.,
a
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Voir aussi : Comptes rendus, 274, serie A, 1972, p. 1300. (C)
G. CHOQUET, Cardinaux 2-mesurables et cones faiblement complets, Ann. Inst. Fourier, Grenoble, 17-1, 1967, p. 383-393.
(D)
R. M. DUDLEY, Convergence of Baire measures, Studia Math., 27, 1966, p. 251-268.
(DJ)
J. DAZORD-M. JOURLIN, Sur quelques classes d'espaces localement convexes, Publ. Dep. Math. Lyon, 8-2, 1971, p. 39-69.
- 201 -
(GJ)
L. GILLMAN-M. JERISON, Rings of continuous functions, Princeton, 1960.
(H 1)
R. HAYDON, "Without title", Cormnunication personnelle, 1972,
(H 2)
E. HEWITT, Rings of real-valued continuous functions I, Trans. Amer.
Cambridge.
Math. Soc., 64, 1948, p. 45-99. (K)
Y. KOMURA, On linear topological spaces, Kumamoto J. of Sc., serie A, 5, 1962, p. 148-157.
(LS)
C. LEGER-P. SOURY, Le convexe topologique des probabilites sur un espace topologique, J. Math. pures et appl., 50, 1971, p. 363425.
(N 1)
L. NACHBIN, Topological vector spaces of continuous functions, Proc.
(N 2)
K. NOUREDDINE, L'espace infratonnele associe
(R
(R
(R
1)
2)
3)
(S)
Nat. Acad. Sc. USA, 40, 1954, p. 471-474.
a
un espace localement
convexe, Comptes rendus, 274, serie A, 1972, p. 1821. A. ROBERT, Quelques questions d'espaces vectoriels topologiques, Cormnent. Math. Helvet., 42, 1967, p. 314-342. M. ROME, Le dual de l'espace compactologique
Comptes rendus,
274, serie A, 1972, p. 1631. M. ROME, Ordre et compacite dans l'espace Moo(T), Comptes rendus, 274, serie A, 1972, p. 1817. T. SHIROTA, On locally conVex vector spaces of continuous functions, Proc. Japan Acad., 30, 1954, p. 294-298.
(SW J. SCHMETS-M. De WILDE, Caracterisation des espaces C(X) ultrabor1) nOlogiques, Bull. Soc. Roy. Sc. Liege, 40e annee, 3-4, 1971, p. 119-121. (SW J. SCHMETS-M. De WILDE, Locally convex topologies strictly finer 2) than a given topology and preserving barrelledness or similar properties, Bull. Soc. Roy. Sc. Liege, 40e annee, 3-4, 1971, p . 119-121, (T)
H. TAMANO, Some properties of the Stone-Cech compactification, J. Math. Soc. Japan, 12, 1960, p. 104-117.
(V)
V. S. VARADARAJAN, Measures on topological spaces, Amer. Math. Soc. Translations (2), 48, 1965, p , 161-228.
- 202 -
(W1)
S. WARNER, The topology of compact convergence on continuous functions spaces, Duke Math. J., 25, 1958, p. 265282.
(W 2)
R. F. WHEELER, The strict topology, separable measures and paracompactness, a paraitre au Pacific J. Math. en 1973.
(WH)
M. De WILDEC. HOUET, On increasing sequences of absolutely convex sets in locally convex spaces, Math. Ann., 192, 1971, p. 257261.
Convergence Structures on
E. Binz
Given a completely regular topological space X, it is well known that
the IR-algebra of all real-
valued continuous functions of X does not determine X. This means, two completely regular topological spaces Y and Z for which
is isomorphic to
(as
unitary IR-algebras) need not to be homeomorphic. In fact, the canonical map pactification
vX
i
x
from X into its realcom-
sending each point
p E.X
into its
point evaluation - called charactere by Buchwalter induces an isomorphism i
sending each
[121
*x
: ce.(vX) __ C0X),
ge cec"X)
into
g
Q
i
X
. One might consult
for examples of completely regular spaces being not
realcompact. However, equipping
and
both with the
topology of compact convergence yielding the topological algebras
and
homeomorphic iff
the spaces and
Y
and
Z
are
are bicontinuously
isomorphic. But in investigating the relationship between X and eco(X)
one has to deal with two unfortunate facts, namely: is in general not complete and in addition
the evaluation map
- ?04 -
co
(X)(
x -*
lR
W
\V
(f, p)
f(p)
is not continuous (with respect to the product structure). Moreover, there is in general no vector space topology T on
for which IJJ :
X - + IR
is continuous. We will see this later on.
[4J )
But one finds always (complete [7], structures on
convergence
making the evaluation map continuous
(simultaneously in both variables)
[9] .
Let me briefly repeat the notion of a convergence structure. For a given set W, we denote by filters on W. A map of
A
F(W)
the set of all
from W into j'(F(W)), the power-set
F(W), is a convergence structure, if for each point
PEW
the following axioms are satisfied:
(i)
p, the filter generated by all supersets of
{pj)
belongs to A (p). (ii)
Any filter'±'
finer than a filter
4E.
A(p)
belongs
to !\(p). (iii)
The infimum of two filters to
/\(p)
belongs
A(p).
A set W endowed with a convergence structure
A
called a convergence space. The filters belonging to are called the filters converging to
p
E.
W.
is
1\
(p)
- 205 -
Given a convergence space W. The fact that a filter
'
on
' ((3X\K)
converging
for some K.
The convergence structure, called I, defined in this way allows W
:
to be continuous, which means that
is continuous.
X-- lR.
- 208 -
The convergence structure just defined has the following characteristic universal property: For any topological ffi-vector space E a linear map I into
is continuous with respect to I iff it is
continuous with respect to If
I: E
Ac•
is continuous, then
for some compact
I(E) c
\X.
Kc
Using the universal property of
one quickly
deduces that given a vector space topology T on making id : set
W;
iPT (X)
x
X ---+
--. K c:.
X\X
IR
continuous, implying that,
is continuous, there exists a compact such that Xc
Hence if X is realcompact, such a topology T on requires X to be locally compact. On
therefore1we do
not find any vector space topology T for which W ;
- - IR
is continuous. The next theorem
[5J
and the following
comments indicate
parts of the aim, I intend to reach:
Theorem Let X be a completely regular topological space. The convergence algebras
ec (X)
and
It?r(X)
are identical iff
the following two conditions hold: a)
The intersection of countably many neighbourhoods of
X in
is a neighbourhood of X again.
- 209 -
b)
The points in X having no compact neighbourhood in vX form a compact set.
In fact,
(h) holds, iff tel (X) =
(X).
Condition (a) characterizes the identity of
ec (X)
and
The index u indicates the convergence structure of local uniform convergence. The last two results can be found in [13] ,where many more results of this type are presented.
Ref e r e n c e s
[5]
[7]
E. Binz, H.H. Keller
Funktionenraume in der Kategorie der Limesraume. Ann.Acad.Sci.Fenn. AI. 383, 1-21 (1966).
E. Binz, K. Kutzler
Uber metrische Raume und Cc(X). Ann.Scuola Norm. Sup. , Pisa. Vol. XXVI, Fasc.I, 197-223 (1972).
E. Binz, W. Feldman
A Functional Analytic Description of Normal Spaces. Can.J.Math., Vol.XXIV, No.1, 45-49 (1972)
E. Binz, W. Feldman
On a Marinescu Structure on C(X). Comm.Math.Helv.,Vol.46, Fasc.4, 436-450, (1971).
E. Binz, P.Butzmann W. Feldman, K.Kutzler and M. Schroder
On w -admissible Vector Space Topologies on C(X). Math.Ann. 196, 39-47 (1972).
E. Binz
Zu den Beziehungen zwischen c-einbettbaren Limesraumen und ihren limitierten Funktionenalgebren. Math.Ann. 181, 45-52 (1969).
E. Binz
Notes on a Characterization of Function Algebras. Math.Ann. 186, 314-326 (1970).
- 210 -
[8]
E. Binz
Kompakte Limesraume und limitierte Funktionenalgebren. Comm.Math.Helv., Vol.43. 195-203 (1968).
[ 9]
E. Binz
Recent Results in the Functional Analytic Investigations of Convergence Spaces. To appear in Proceedings of the Third Prague Topological Symposium.
[10]
W. Feldman
Topological Spaces and their Associated Convergence Function Algebras. Ph.D.Thesis. Queen's Univ .• Kingston.Can.
[11]
H.R. Fischer
Limesraume. Math.Ann. 137, 269-303 (1959).
[ 12)
L.E. Gilman. M. Jerison
r13]
Rings of Continuous Functions. van Nostrand. Princeton 1960.
K. Kutzler
tiber Zusammenhange. die zwischen elnlgen Limitierungen auf C(X) und dem Satz von Dini bestehen. Habilitationsschrift, Univ. Mannheim (1972).
[14}
B. Muller
tiber den c-Dual eines Limesvektorraumes. Dissertation, Univ. Mannheim (1972).
- 211 -
VARIOUS TYFES OF BARRELLEDNESS AND INCREASING SEQUENCES OF BALANCED AND CONVEX SETS IN LOCALLY CONVEX SPACES M.DE WILDE Various tjpes of barrelledness
1.
We use the notations of Horvath's notes in this volume. A locallj convex Hausdorff space
E is quasi-barrelled (a-barrel-
led) if everj a(E'. E)-bounded set of of equicontinuous subsets of
E'
which is a countable union
E' (a countable subset of
E') is equi-
continuous. The space
E is quasi-infra-barrelled (a-infra-barrelled) if
everj B(E'. E)-bounded subset of equicontinuous subsets of
E'
which is a countable union of
E' (a countable subset of
E') is equiconti-
nuous. The reason for considering these various tjpes of barrelledness finds its origin in the following proposition. due to Grothendieck [51. Froposition 1. for
If
E is metrizable. E'
is quasi-infra-barrelled
B(E'. E). An interesting problem was to find conditions impljing that
is even barrelled for in [5].
B(E'. E).
E'
It has been studied bj Grothendieck
Actuallj. Grothendieck has substituted to the duals of metri-
zable spaces. a new abstract class of spaces. the so-called "'!)J'-spaces". with the following properties: E is a
if
(a)
E is quasi-infra-barrelled.
(B)
E admits a fundamental sequence of bounded sets. It is worth noticing that l.Schwartz has provided a completely dif-
ferent approach to the barrelledness of strong duals of usual spaces. It is developped in Hogbe's notes in this volume. In [7]. Valdivia has given several new properties of barrelled
- 212 -
spaces.
It was clear that some of thse properties were inspired bj
Grothendieck's theorj of
although not including it.
The
gap between [51 and [7] was filled in [31 and. s ur pr i s t nql y , the gain of generalitj came along with a gain of simplicitj. matter of this lecture.
That will be the
The content is essentiallj the same as in [31.
presented in a somewhat more general setting. Absorbent and bornivorous sequences
2.
let
E be a locallj convex Hausdorff space.
An absorbent (bornivorous) sequence is an increasing sequence
em
of convex and balanced sets. such that each element (bounded set) in E is absorbed bJ one of the sets
em'
All the results included in these notes for absorbent sequences are also true for bornivorous sequences. when replacing the barrelledness assumptions bj the corresponding infra-barrelledness assumptions. Theorem 2.1.
let
l
an absorbent sequence in (H)
for each sequence
the set
mE
}
x'm E E'
U:=l em
l .. E.
Then
Thus e
(m
E
< x. x' > ..
1 +
xm I E eO m for each
x
(l+ )Uem.
< x , x'm > l.
m,
U:=l em'
Then. for each and
1 +
It is not a restriction to assu-
m E IN}
It has therefore an adherent point it is clear that
em
is the algebraic closure of
such that
The sequence is equicontinuous in me that
E and
such that
> O. assume that
Given
m, there exists
l
xm I (m E 1N) such that is equi conti nuous.
Then the closure of Froof.
be a vector subs pace of
is also equicontinuous in x'
for
and that
aCE'. E). x'
E
For that
eOm for each
E. x'. m.
x
(Uem)oo .. Ue m. BJ the obvious correspondance between the Cauchj filters on a set
and the points of its completion. theorem 2.1 can easilj be inter-
preted in a form similar to lemma 3.9 in Horvath's notes.
- 213 -
There are two important examples of absorbent sequences verifJing (H) •
(a)
If
spaces
L is the inductive limit of an increasing sequence of sub-
Lm• then If
(8)
em
= Lm (m
verifies
E
(H).
L is a-barrelled. each absorbent sequence in
L verifies
(H) •
Corollaries 2.2.
A strict inductive limit of complete spaces is complete
(Kl5the). Froof.
Take for
the inductive limit and for
L
E
its comple-
tion. 2.3.
r
If
is a-barrelled and has an absorbent sequence of com-
plete subsets. it is complete. 2.4.
If
Take
L
rand
=
E is a Baire space and if O.
em (m E
one of the
In particular. E is then barrelled.
It is worth noticing that
E is a Baire space when
zable. Without the strong assumption that get an interesting property.
= r.
E is a-barrelled. then.
for each absorbent sequence of closed sets em's is a neighbourhood of
E
E is metri-
.
E is a Baire space. we still
Before stating it. let us improve theo-
rem 2.1 by a trivial remark. that
If
em (m
E
Ue m
and
E
= ue'm'
then
e'm (m E
are increasing sequences such
E
= U( em n
.
Now, in theorem 2. I, assume that sequence in
where
em
e'm
E
such that
IN) is an absorbent
E
m.
e'm ue m = alg. cl. (Uem ) denotes the closure of
topologJ induced bJ Froof.
em E
e'm (m e'm for each
It
E.
is obvious. since
em
e' - m em
in
.
Then
e'm equipped with the
em n e'm'
- 214 2.5.
Let
E be a-barrelled and
be an absorbent sequence in
E.
A balanced, convex and absorbent set
a is algebraically closed. E is barrelled, and if a ('\ e'm is closed for
e ('\ e'm is closed in each
if
In particular, if each
m, a
e'm and
is a neighbourhood of
Froof.
a is a barrel if and only
O.
In the improved version of theorem 2.1. take
a ('\
em
Compare with proposition 3.10 of Horvath's notes. 2.6.
[5] If
E is metrizab1e. the following are equivalent
ex.
Ea (E ' • E)
is bornologica1.
B.
Ea(E' • E) ES(E'. E)
is u1trabornological.
y.
Since
is barrelled.
ES(E'.E) .. ex. If y
is
complete. ex
6 .. y.
a is bornivorous and if Urn nei ghbourhoods of 0 in E. e contains a' r( u Now
00
b1e
Am's.
m=1
We can write
a
is a basis of for suita-
I
N
Since
is a bornivorous sequence of closed subsets. m=1 by theorem 2.1 and proposition 1. the closure of a' is its algebraic closure.
3.
r( u
Thus
a
Theorem 3.1.
sed sets in
e'
Let
2
a'. the last member being a barrel in
em (m
be an absorbent sequence of clo-
E
E.
Each strongly bounded set in - If (m
E
em (m
E
verifies
E is absorbed bJ some
(H). (see theorem 2.1). then
IN) is bornivorous. ( [3].
th. 1. ) .
There is a kind of "dual" statement.
em' em
- 215 let 1.1
Theorem 3.2.
be a subset of :feE)
be a sequence of sets such that. if {x
m
: mE
for each
e is balanced and absorbs the elements of
If some
:B.
} E
xm E em
and let
em (m
IN)
E
m. it absorbs
em Corollaries. 3.3.
spaces
If
E is the inductive limit of an increasing sequence of
n
Em' ever) bounded set
(closure in
E).
If the
Em
is contained in some
E
are normed. jB is contained in the clo-
sure of a bounded set of some 3.4.
in
Em'
Under the same assumption on
and absorbs the equicontinuous sets of 3.5.
If the
E'm.s (Em.E ' m)
Em
E'
is balanced EOm for some
m.
E'
is bornological and is the .
3.4 and 3.5 are slight generalization of
r 51,
lemma 5 and
can be found in [21, prop.lO-lI, p.139-l40.
4.
also provides some interesting properties. Theorem 4.1.
E is quasi-barrelled and i f
If
absorbent sequence in U
Cf.
in
0
em (m E tl)
E = Ue m, a balanced and convex in E i f and onl) i f U n em is a
em
0
for each
m.
r 3] , theorem 3.
Theorem 4.2. subspace of
If
E is a-barrelled and
E. then each barrel in
l
a separable vector
E induces a neighbourhood of
l.
Cf.
r 3] • theorem 4.
Corollaries. 4.3.
is an
E such that
is a neighbourhood of
neighbourhood of
in
e
E'. then
E'S(E',E)
projective limit of the spaces
set
C
are moreover quasi-barrelled and the
bornological. then -
theorem 10.
e
E. if
If
E is a-barrelled and separable, it is barrelled.
0
- 216 4.4.
Let
its barrels. in
t
be the loca11j convex topo1ogj defined on
Then, if
E
E £l
a-barrelled, a sequence is convergent
Et if and on1j if it is convergent in E. Froof. Take for L the linear hull of such a sequence and its
limit and app1j 4.2. If
4.5. (m
E is quasi-barrelled and has an absorbent sequence
em
of metrizab1e subsets, it is barrelled.
E
Froof.
Bj 4.4, a barrel
each
e induces a neighbourhood of
Bj 4.1, it is thus a neighbourhood of 4.6.
[5]
bourhoods of
If
a
in
a
in
0
in
E.
E is metrizable and i f the po1ars of the neighE are metrizable for
R(E', E), then
ES(F',E)
is barrelled. Froof. po1ars. 5.
There is a bornivorous sequence of
E', made or such
The conclusion follows then from 4.5 and proposition 1.
Just like the concepts of barre11edness and infra-barre1ledness
extend to topological vector spaces, the definitions of § 1 can also be adapted to topological vector spaces, as well as absorbent and bornivorous sequences.
Most of the preceding results can be extended
although their formulation becomes rather sophisticated.
(see [4]).
REFERENCES 1.
AMEMI1A, I., KOMURA, 1.
Uber
Math.Ann., 177,273-277 (1968). 2.
DE WILDE, M. : Reseaux dans 1es espaces lineaires Mem.Soc.Roja1e Sc.Liege,
3.
a semi-normes.
2 (1909).
DE WILDE, M., HOUET, C. : On increasing sequences of abso1utelj convex sets in t ocel l y convex spaces. (1971).
Math.Ann., 192,257-261
- 217 4.
DE WILDE, M., GERARD-HOUET, C. :'Sur les pr opr t e t es de tonnelaqe des espaces vectoriels topologiques.
Bull .Soc.Ro}ale Sc.Liege,
11-12, 555-560 (1971). 5.
GROTHENDIECK, A. : Sur les espaces
(1)
et
Summa Brasil.
57-123 (1954). 6.
KOTHE,
u.
:
Topologische lineare Raume. I. Berlin-Heidelberg-
Springer, 1966. 7.
VALDIVIA, M. : Absolutel} convex sets in barrelled spaces. Ann.Inst.Fourier, 21 (1971).
LATTICE BOUNDING r1APPINGS
D.J.H. Garling
E
If
is a Banach space and
o
< p < (0) , y
f
E
E
LP W, u ) F
and
L(E,L P(S1,j.J) ) (for some
E
is said to be p-lattice bounded if there exists
/y (e)
such that
I
< f
are Banach spaces,
p-lattice bounding if y
y
yu
u
whenever L(E,F)
E
II
ell < 1-
is said to be
is p-lattice bounded whenever
(for arbitrary topological space
E
If
n
and regular
probability measure It turns out that p-lattice bounding mappings are closely related to p-absolutely summing and p-Radonifying mappings.
The
first two theorems are direct ones. THEOREM 1.
If
Y
is p-lattice bounded, then
£
y
is p-absolutely summing. THEOREM 2.
Suppose that either
p :
0
2
then
and u
is
q
p,
the diagonal mapping
summing if and only i f
ex E R,p
(when
p.:. r.:. q)
(when
q.:. r).)
Tong [8]
and
ex E R,q
0 < r
d
R,q , except
into
(For example i f is r-absolutely
ex
< p) , ex
R,r (when
E
Using ideas introduced by
(who characterised I-nuclear diagonal mappings), we can
then characterise all the r-integral and r-nuclear diagonal mappings, except for the case when
1 < r < min(p,q) .:. max(p,q) < 2.
It
turns out that (with the exceptions mentioned above) a diagonal mapping from
R,P'
into
R,q
r-absolutely summing, when into
of
is r-integral if (and only if) it is r
Is every
u
CONCLUDING REHARKS. of KwapieJ'l y
1.
In particular, the
r > 1.
is r-integral, for
summing diagonal mapping from r > I?
>
E
L(R,1,R,2)
p'
Is every r-absolutely r-integral, when
into
p-decomposable in the sense that there exist mapping of
each
e
into
E'
such that
is in
>
I?
Theorems 1-5 are closely related to results
is p-lattice bounding, then
0
0
if and only if there exists
be a linei'
F)
->
be an unbounded F)
->
a
be a non null
being a Hausdorff topological vector space. Then ->
r)
rV
C b
[resp G(f : b
a
->
a
F) C
and these inclusions are c ont.i nuoua ,
PROPOSITION
4.3. (cf [5J, proposition 2,b). Let
tp
be an unbounded
concave Orlicz function. Then bicontinuously where
i
tp
is the canonical injection
Ltp
->
L
O ,LO
is the space of all measu-
rable functions with convergence in measure.
Now, let us prove theorems 3.1 tinuous linear mapping
->
Ltp (resp b
a
a
continuously. So,
Itp C
rJ
f
be a non null con-
....
N
'"
Let
and 3.2
(resp (IJ
(resp some zero-neighborhood of
Itp
is bounded in
- 226 -
('I
It);) u
and, consequently,
(resp lim sup
0)
when
0 . This implies conch tions (i), and therefore (ii), cf theorem 3.1 (resp 3.2)
(of [5J) . BIBLIOGRAPHY
[1J
A. FROLICHER and W. BUCHER, Calculus in vector spaces without norn, Lecture Notes in Mathematics 30, Springer, 1966
[2J
W. ORLICZ, On spaces of functions, Proc. Intern. Symp. on Linear Spaces (Jerusalem, 1960), 357-365.
[3J
D. PALLASCHKE, The compact cnd omorpii s.cs of t':",11etric linear spaces
[4J
S. ROLEWICZ, Some
preprint. on the spaces
N(L)
and
N(1), Studia Math.18
(1959), 1-9. [5-]
P. TURPIN, Operateurs Li.nea i r c s en t r o e s j.ac e s d ' Crlicz non LocaLemen t convexes, Studia 46(2), to
[6 J
P. TURPIN, Sur t.n pro bl ome de S. SimlJns concernan t les bor-nes des espaces vectoriels topologiques, Bull. Soc. Math. Fr. (Memoires), to appear.
Lecture Notes in Mathematics Comprehensive leaflet on request
Vol. 146: A. B. Altman and S. Kleiman, Introduction to Grothendieck Duality Theory. II, 192 pages. 1970. OM 18,Vol. 147: D. E. Dobbs, Cech Cohomological Dimensions for Commutattve Rings. VI, 176 pages. 1970. OM 16,Vol. 148: R. Azencott, Espaces de Poisson des Groupes Localement Compacts. IX, 141 pages. 1970. OM 16,Vol. 149: R. G. Swan and E. G. Evans, K-Theory of Finite Groups and Orders. IV, 237 pages. 1970. OM 20,Vol. 150: Heyer, Dualitiit lokalkompakter Gruppen. XIII, 372 Seiten. 1970. OM 20,Vol. 151: M. Demazure et A. Grothendieck, Schemas en Groupes 1. (SGA 3). XV, 562 pages. 1970. DM 24,Vol. 152: M. Demazure et A. Grothendieck, Schemas en Groupes 11. (SGA 3). IX, 654 pages. 1970. DM 24,Vol. 153: M. Demazure et A. Grothendieck, Schemas en Groupes Ill. (SGA 3). VIII, 529 pages. 1970. DM 24,Vol. 154: A. Lascoux et M. Berger, Variates Kahleriennes Compactes. VII, 83 pages. 1970. DM 16,Vol. 155: Several Complex Vartables I, Maryland 1970. Edited by J. Horvath. IV, 214 pages. 1970. DM 18,-
Vol. 178: Th. Brocker und T. tom Dteck, Kobordismentheone. XVI, 191 Setten. 1970. DM 18,Vol. 179: Semtnatre Bourbaki - vol. 1968/69. Exposes 347-363. IV. 295 pages. 1971. OM 22,Vol. 180: Seminaire Bourbaki - vol. 1969/70. Exposes 364-381. IV, 310 pages. 1971. DM 22,Vol. 181: F. DeMeyer and E. Ingraham, Separable Algebras over Commutative Rings. V, 157 pages. 1971. DM 16.Vol. 182: L. D. Baumert. Cyclic Dtfference Sets. VI, 166 pages. 1971. DM 16,Vol. 183: Analyttc Theory of Differential Equations. Edited by P. F. Hsieh and A. W. J. Stoddart. VI, 225 pages. 1971. DM 20,Vol. 184: Symposium on Several Complex Vartables, Park City, Utah, 1970. Edtted by R. M. Brooks. V, 234 pages. 1971. DM 20,Vol. 185: Several Complex Vartables II, Maryland 1970. Edtted by J. Horvath. Ill, 287 pages. 1971. DM 24,Vol. 186: Recent Trends in Graph Theory. Edited by M. Capobianco/
J. B. Frechen/M. Kralik. VI, 219 pages. 1971. DM 18.-
Vol. 187: H. S. Shapiro, Topics in Approximatton Theory. VIII, 275 pages. 1971. DM 22,Vol. 188: Symposium on Semantics of Algorithmic Languages. Edited by E. Engeler. VI, 372 pages. 1971. DM 26,-
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