0047-2468/86/020105-1051.50+0.20/0 9 Birkh~user Verlag, Basel
Journal of Geometry Voi.26 (1986)
A KRASNOSEL'SKII
Marilyn
THEOREM FOR NONCLOSED
SETS IN
Rd
Breen
This w o r k will be concerned w i t h a K r a s n o s e l ' s k i i theorem for nonclosed bounded sets in R d , and the following theorem will be obtained: For each d ~ 2 , define f(d) = d 2 - 2d+3 if d # 3 and f(d) = 2d + 1 if d = 3 . Let S be a nonempty bounded set in R d , d ~ 2 , and assume that cl S ~ S is a finite union of convex components, each having closure a polytope. If every f(d) points of S see via S a common point, then there is a point p in cl S such that Bp ~ {s:s in S and (p,s]~ S} is nowhere dense in S.
i.
INTRODUCTION
We begin w i t h some definitions points
x
and
y
corresponding
in
sees
x
kernel
via of
[x,y]
is possible
Without
by examples
be a n o n e m p t y
in
S
bounded
of locally
and
throughout
in
S
be a subset
via
Set
S
S
of
Rd .
For
if and only if the
is said to be starshaped
such that, p
for every
is called
(p,s] ! S} the planar
in [3].
relative
respectively,
R2
the
components.
S
x
in
if
S,
p
(convex)
S .
dense in
Rd .
way:
The purpose
that
Let
S
in
S
see
B m {s : s
of this w o r k is
terminology
will be used
cl S , int S , rel int S , bdry S ,
the convex hull,
boundary,
relative
affine hull,
Boundary,
S
of a finite
in cl S , the set
The following
Conv S , aff S,
S .
consists
set
see via
no such theorem
If every 3 or fewer points
is nowhere
will denote
S
[2] it was shown
in the following
complement
a compact
of
be compact,
p
to
S
points
in [i] and
starshaped whose
that for
d+l
then for some point
interior,
for set
that
However,
to being
result
the paper.
[4] states
the requirement
compact
rel bdry S , and ker S interior,
p
y
if and only if every
set in
a common point,
to extend
S .
theorem by Krasnosel'skii
such sets may come close
S
sees
S
The set of all such points
is starshaped
a common point.
number
Let
S .
Rd , S
via
x
lies in
is some point
S .
A well-known in
S , we say
segment
and only if there
from [i].
closure,
and kernel,
106
Breen
If
S
is convex,
y , dist(x,y) L(x,y)
S
will be the dimension
will denote
will represent
referred
2.
dim
the distance
from
the line determined
to Valentine
of
x
by
S .
to x
For points
y , and when
and
y .
[6] and to Lay [5] for a discussion
x
~nd
x # y ,
The reader
is
of these concepts.
THE RESULTS
DEFINITION. points
Let
S
x I, .... x k
in
common point of that
xi
T
Let
If every
j(n+l)
common point
in
convex
by induction
that every in
6.18]).
n+l
T , where
points
T
for
assume k+l
t ~ T
We say
S
sets a
S 1 .... ,S k
in
(depending
on
~
such
xi
and
. compact
sets in
R d ~ j ~ i.
see via their respective
T , dim T ~ n , then
S
sets a
ker S I N oo. N k e r
S
convex
Let
every
T
For convenience
k(n+l)
the disjoint distinct
compact
sets
open halfspaces
Sk+ 1 N T ~ H+ and to see via
by our induction
in
T' in
T' c H
fails
(n-l)-flat and ker
hypothesis,
ker
S
k
n .
Then
(See [6, Theorem
or fewer
convex
sets,
of compact
, to
sets such that
see via
S
sets
at most
their
hypothesis,
T~
ker Sk+ 1 n T # ~ .
to meet
T'
to reach a contradiction.
loss of generality), H
1
set of dimension
S I U ... U S k
~n
aff
T
Sk+ 1 n T ~ let
determined
If every
their respective
at most
a common
see via their respective
in
Similarly,
aff T
j = ! and S1
T , so by our induction
(and without
Choose an
see via
theorem.
be a family Sk+ 1
points
ker Sk+ 1 n T
of notation
dim T = n .
is true for
is a closed
ker S I n ... n ker S k n T # ~ 9 that
S1
Let
j = 1 9
S I U ..~ U
sets a common point
We will assume
set
set of dimension
SI,.~O,Sk+ 1 in
of sets.
of Krasnosel'skii's
is true for
T , where
Then certainly
respective
of the compact
is closed
points
in
j , the number
that the result
sets.
(k+l)(n+l)
a common point
were
U Sj
set
on
by a version
Thus the result
Inductively,
that
a
of nonempty
SIU ...
in some closed
(ker S I) n T # ~
n .
be a family
points
T c Rd
in S} see via their respective
[xi,t] ~ S i , 1 ~ i ~ k
S 1 ..... Sj
We proceed
assume
every
and let
Tr
PROOF.
prove
: S
Rd
if and only if for every choice of
with
LEMMA i.
point
U{S
of sets in
E S i , 1 ~ i ~ k , there corresponds
S i , i ~ i ~ k)
S.n ]
be a family
k(n+l)
by
Separating
H+
~U
and
H , labeled
points
of
sets a common point
S IN:,.. N k e r
we may assume
strictly
so Lhat
S1 U ~ in
denote ker
U Sk
T n e! H+
S k n (T n cl H+) r ~ ,
, then
Breen
107
impossible since points of
ker S I N ... N ker S k N
S I U ... U S k
common point in w h i c h fail
Similarly,
Sk+ I
(k+l)(n+l)
fail to see via their respective
contradiction,
However,
COROLLARY. (n+l) 2
Let
2
S
n+l
points in
By induction,
U{S : S
in
2~
, every
in
2
S
(n+l) 2
THEOREM i.
in
Hence every
2} ~ (n{ker S : S in
For each
f(d) = 2d + i
if
and assume that
d ~ 2 , define
d = 3 . cl S ~ S
closure a polytope.
Let
n+l
p
S
S
in
T .
~.
S I U ... U Sn+ I ker
of the compact convex sets in By Helly's theorem,
2})N T r ~ .
f(d) = d 2 - 2d + 3
f(d)
If every
By Lemma i,
if
d # 3
be a nonempty bounded set in
points of
el S
j ~ i.
sets a common
S
such that
see via
B
and
R d , d ~ 2,
is a finite union of convex components,
If every
then there is a point
Rd .
points o f
{ker S N T : S in 2} have a nonempty intersection. N{ker S n T : S
for all
(N{ker S : S in 2 } ) n T #
sets a common point in
S I n o.. N ker Sn+ I N T # ~ .
U
We have a
see via their respective
PROOF.
S I .... ,Sn+ I
which
(T N cl H+)
the lemma is established
T, dim T ~ n, then
For
Sk+ I
ker Sk+ I N T N T' ~ ker S I N ...
point in some closed convex set
see via their respective
sets a
S I U ... U Sk+ I
be any family of nonempty compact sets in
points of
k(n+l)
Combining these
sets a common point of
is false, and
S
points of
T n cl H
this violates our hypothesis.
our a s s u m p t i o n
N ker Sk+ I n T # ~ .
there are
a common point in
points into one set, we obtain
(T N cl H_) = T.
Thus there are
w h i c h fail to see via their respective
T N cl H+ o
to see via
T ~ T' ! H_
each having
S a common point,
~ {s : s in S and
(p,s]
P S}
is nowhere dense in
PROOF.
S .
To begin, we dispose of the case in w h i c h
Observe that by [i, Lemma 2], cl
S
d = 2
and
of
cl S ~ S
are either isolated points or segments.
and
[2] hold~ and the result fellows from [2, Theorem I].
For the remainder
f(d) = 3 .
is starshaped and hence the components
of the argument assume
d > 3 .
Thus the lemmas in [i]
For convenience,
the proof
is divided into three parts. PART i.
We define families of convex sets
consider the collection of all points true:
There is some n e i g h b o r h o o d m ~ d-l, w h e r e
in
of N
x
m-flat
P
Let
be the collection of all the flats
P
for some
x
N
P,
@ , S
and
C .
for w h i c h the following
such that
N n s
is selected so that P .
First, is
lies in an m
is minimal.
108
Breen
Next, for each
P
in
cl(S N P) ~ (S N P)
P , let
O
denote the family of components A of P which are a full ((dim P)-l)-dimensional and which
satisfy the following property: sequences
{d n} , {d~}
halfspaces of e
in
in
S N P
determined by
a
in
rel int A , there exist
converging to aff A ~
Let
a
and in opposite open
@ = {A : A
in
0p
for some
P} .
Finally, a full c
P
For some
let
C
be the collection of components
(d-l)-dimensional
in
rel int
(N{P : P
that
N{P : P
in in
P}) N (n{aff P} # @ .
P # @ . Select a subfamily
B
If P'
Rd
a minimal collection
there are at most
{bn}, {b~} in
determined by
:
B
of
PI,...,Ps
P
for which N{P d'k .
from
P
which are
of the sets
PI,...,Ps
For some
converging to
aff C .
: P
Clearly
such that
Since
We assert that for each
S
in 0UC}) # @ .
PI .... 'Ps ~ P ' ~ k
cl S ~ S
c
We will Show
We begin by showing
P = @ , the result is immediate,
and has smallest possible dimension
We may assume that
of
and which satisfy the following property:
C , there exist sequences
and in opposite open halfspaces of that
C
in
so we assume
~}
is nonempty
0 ~ d-k ~ d-i
Choose
dimn{P i : i ~ i ~ s} = d-ko
dim Pi ~ d-I , so
for
i ~ i ~ s,
I ~ s ~ k ~ d o
in P P0 contains K ~ n {Pi : i ~ i ~ s} . o Of course, there are only three possibilities for flats PO and K : Either P0
meets
K
P0
contains
P
in a nonempty set of dimension less than K .
P0 n K = ~ ~ or
The first of these cannot occur by our choice of
see that the second cannot occur, proceed as follows: {P0,PI,...,Ps } , select a point of
xi
xi
in
such that
S n P.1
neighborhood
Ni
Xo,Xl,...,Xs
yield a collection of at most
By our hypothesis,
d-k ,
they see via
S
Ni N S !Pi
For each
P. i
P~ .
To
in
and an associated ' 0 ~ i ~ s .
s+l ~ d+l ~ f(d)
a common point
The point s points in
z , and clearly
S o
z ~ O{Pi:
0 ~ i ~ s} ~ P
N K . Hence p n K # ~ , and the second possibilit~ cannot p o The only remaining possibility is that K ~ P0 for each P0 in ~ ,
occur.
and the assertion is established. ... N p
= N{p :
Moreover,
it is easy to see that
K ~ PI N
p in P} # ~.
s
Next we will show that that
OUC
that
P # ~ , and let
Q{aff B : B in
P1 .... 'Ps
and
associated points selected previously. empty) of
OU~}
Meets
# @ , for otherwise the result is trivial.
OUC
for which
Xl,...,x s
N{P : P
in
P}.
be the members of
Choose a subfamily
K N (N{aff B : B
in
B'})
Assume
For the moment, assume
B'
~
and
(possibly
is nonempty and has
Breen
109
smallest
possible
d-j < d-k that
dimension
, choose
d-j ~ d-k
a minimal
.
Define
co]lection
Define
J = K
1 4 s+r ~ j ~ d We assert soning,
that
{d~n}
and
in
S N P0 by
in
rel int C O
to
cO
r 4 j-k
for each
B0
a0
0UT
to
select
associated
sequences
above,
accordin~
to whether
a0
B0
sequences
{din} B.z
{don}
of 9
and E0
If
Rd
opposite don
sees via
S
ds+l, n , ds+l,n'
If
B.I EC
we have near
in
to point
said that
J .
for
near
J .
of
P0
For each
' ds+r,n}
If
same contradiction, The case for
r
and
d+l
S q
in q
points.
J ~ aff B 0 .
point
cl S .
P0 cO
converging aff C O .
that
J N aff B 0 =
J !P0
' J
must
by
aff A 0
For an appro-
n , {x I ..... Xs} U {d
qn
points
s+l + 2r = S .
By
sees via
our assumption
is false,
of
: 1 ~ i ~ s} =
N aff Bs+ r = J 9
lars
changes
of
{qn} _c N{P.I
don
B 0 = C O , minor
S and
in the argument
However, no point J N aff A 0 =
above yield
the
J N aff B 0 # fl .
is a simplified
The details
of at most
,
on
, and some subsequence
Clearly
( K N aff Bs+ 1 N " "
sufficiently
and again
d-j = d-k
S
by
of
Select
determined
is a collection
a common
We have a contradiction 9
J Q aff B 0 r fl .
s+l ~
n
in
,
{d' } sequence {d } belongs to the on ~ on (aff A0) - . Observe that for n sufficiently large,
'''''ds+r,n
p } z K ~ and
{don}
B0 = CO ~
both are flats) 9
(j-k) + 1 = 2j - k+l < 2d+l ~ f(d)
converges
B0 =
open halfspaces
Assume
see via
: P
~0, let
sequences
B 0 = A 0 , then since
A0
rea-
B. ~ s+l ~ f < s+r I in the manner described
(s+r) + r+l < j +
{qn }
B0
, {d~n}
hypothesis,
N{P
case we have
and
no point
these
J = K
Using previous
determined
{din}
or
(since
}
define
For each set
(aff A0) +
from
on open halfspace
such
Bs+l,...,Bs+ r
in either
(C 9 let
lie in one of the open halfspaces
{d
Then
If
OUC
d-j = d-k,
and in opposite if
and a positive
of
that
with associated
d-j < d-k
r 9 to reach a contradiction.
distance
from
, .7 ~ aff B 0 .
open halfspaces
the case for
labelin~
If
J N aff B 0 # ~ o
Similarly,
associated
and in opposite
priate
Assume
r = 0 ,
rel int A 0
converging
with
as follows:
. in
in
aff A 0 ,
consider
let
to show that
Select
determined
First
of notation,
it suffices
A0 (O P0
,
N aff g s + I N ... N aff Bs+ r .
and for convenience
J
Bs+ 1 .... ,Bs+ r
d i m ( K N aff B s + i N --o N aff Bs+ r) = d-j
B'.
set
version
are omitted.
The assertion
of the argument
We conclude
is established.
that
Moreover,
above,
using
J N aff B 0 #
ii0
Breen
J = K n {aff
: B
in
0UC
} =
(n{P
: P
in
P }) .q (N{aff
B : B
in
}) ~ ~ .
ouc If
B
P = ~ , then
n{aff
C : C
(n{aff
O = ~ , and an argument
in
B : B
C } r ~ ,
iu
PART
2.
seen
that
T # ~ ,
PIn
''' n P s
0 aff
chosen
Define
@UC set
Hence
}) ~ ~
T = For
(n{P
: P
in P }) n
convenience
Also
the one above
that
(N{P
shows
: P
in
that
P }) N
in general,
Bs+ I n ,.-n aff
previously.
like
we c o n c l u d e
assume
(n{B
of n o t a t i o n ,
Bs+r that
where
: B
the
points
in
when P
x.
@UC
P # ~ and
are
})
B
sets
chosen
,
just d-j
as they w e r e
{din}
earlier.
Recall
for
P.
that
this
by w r i t i n g
those
,
l
chosen
for
B i ' s+l ~< i ~< s + r ~
dim(P 1 n . . , n P ) = d-k
dim T =
0 ~< r ~< j-k
T = aff Bs+ 1 R . . . N a f f
,
G/hen
Bs+ r , w i t h
s = 0 .
Define will
I~
consider,
X(P) P =
CASE
to be the r
prove
define
n {ker
determined % - %(P)
= r
that
I.
=
Assume
cl W
If
P
that
P
contains
We will
show
that
every
respective
Let
.
Parts
{Vl,.,.,v%}
arbitrary
W.
of sets
If
S)
P
has
in
P
: P
in P
There
are
Hence
at least
one member,
} U {S} three
for
We
cases
convenience
two d i s t i n c t ~(P)
.
in
IV
at least
and d i m ( n { P
~ E (d-j+l) 2
cl W
sets
= 2(d-j+l)
W
with
v.
: W
( cl W.
I
I
members,
in I~ }) ~< d-2
points
of U {cl W
are
_cU{cl
two distaoct
: P
a common
of the a r g u m e n t
I
a collection 2) =
However,
we
members, If
point
: W
in the closed
numbered
in ~ } .
.
for
For each
, 1 ~< i ~< % ~
Hence
Thus
k ~> 2
in W } couvex
future
reference.
point
v.1 ' select
Observe
that
,
see set
T ,
an
either
W. = P n S for some 1 i in W. c o n v e r g i n g to l {Vln .... ,V%n}
to
d-j+l
}) # d-i
dim T = d-j
{(Pn
W } n T # r .
has e x a c t l y
in P
their
iu
by the number
: P
via
: W
as follows:
(d-j+l) 2 , %(P)
of sets
dim(n{P
i)
are
, 1 ~< s ~< k ~< d , I ~< s+r ~< j ~< d , k < j , and
P = r , we m o d i f y k=
' {d', In }
T =
are
I
i ~< i ~< s , and s e q u e n c e s
We have
assume
P. in P or W. = S . T h e r e is a s e q u e n c e {vin} I I " v. , 1 ~< i ~ % . For every n , the points 1 ' ~ } yield U {x I .... ,x s} U {ds+l, n , d s+l,n .... 'ds+r,n ' d ser,n
of at most %+s+2r
(d-j) 2 + 2(d-j)
%+s+2r
points
= (d-j+l) 2 +
+ ! + 2j-k =
(s+r)
in
S .
+ r ~< (d-j+l) 2 + j +
(j-k)
(d-j) 2 + 2d - k + 1 ~< (d-k) 2 + 2d - k + 1
Breen
The
Ill
function
1 < 0 o
g(k)
Thus
is as small
=
g
(d-k) 2 + 2d - k + 1
is d e c r e a s i n g
as possible.
That
2d - 1 = d 2 - 2d + 3 ~ f(d) 3)
Thus
we h a v e
pothesis, n{P
: P
q
in
they in
see v i a
For each then
S
is, w h e n
a common
q ( P1 n . . . n Ps
6 Pin
assumes
k = 2 .
f(d)
point
qn
a subsequence
i , 1 < i ~ % , we
Vin,q n
and
of at most
Moreover,
cl S , and
k
derivative
c S ~ W.
n aff
show
that
S , so
[Vin,q n ] c
Hence
by a simple
--
that
point
4) B y
= -2d + 2k value
g(k) ~
k
points "
of
in
Clearly {qn }
qn (
converges
Bs+I n -.. n a f f [Vin,q n] c W i :
Pi N
S .
S ~ W.
By our hyPI N... N P s to some
Bs+ r ~ T If
If
o
W i = P1. n
W. = S
1
1
convergence
point
S '
clearly '
argument,
[vi, q] c c l
W.
--
points
of
when
(d-2) 2 +
i
We c o n c l u d e common
.
its m a x i m u m We have
--
[Vin,q n]
g'(k)
.
a collection
P } .
in
has
Vl,...,v %
see v i a
their
respective
cl W
o
i
sets
a
T o
the c o r o l l a r y
to L e m m a
i, n { k e r
cl W
: W
in
W } n T r ~ , the d e s i r e d
result. CASE
2.
W~
{PIn
Assume
that
S , S}
and a s s o c i a t e d argument S . (j-k)
contains
i, Part
%+s+2r
Vl,...,v %
see via
Finally,
we m a y
by L e m m a
apply
their i, ker
cl
the d e s i r e d
CASE
that
Again
Assume
select
via W
cl S in
PART in
at most
+ 0 + 2r ~
a common
W } n T # r . 3.
Finally,
N } n T .
(PIn
This
choose
Then
(d-j+l)
Then
1 = s ~ k
points
,
v. i of
+ r ~ 2d - 2j + 2 + j + contains
a common
at most
that
f(d)
points
point
cl S R T ~ N { k e r
s = k = 0 , ~ = {S}
of
T
point
sequences
of
cl W
T . : W
%+s+2r
i, Part
, and by L e m m a
p
point
Case
in W
}
~ = d-j+l
3),
I, ker
~
i, Part time,
, so the c o l l e c t i o n
points
Vl,...,v %
see
cl S N T ~ n {ker
cl W
3.
in the n o n e m p t y p
, and
{v~ } as in Case In p o i n t s of S . This
+ 2j ~ 2d + 1 ~ f(d)
By Case
finishes
that
(s+r)
sets
S) n ker
points.
point
We assert
"
Select
result.
~ = ~ .
f(d)
P1
3) to c o n c l u d e
cl W
v. and a s s o c i a t e d 1 a c o l l e c t i o n of at most
= (d-j+l)
contains
i, Part
points
and o b t a i n
%+s+2r
+
, so the c o l l e c t i o n
Case
respective
n T r r , again 3.
one m e m b e r
% = 2(d-j+l)
= 2(d-j+l)
~ 2d + 2-1 = 2d + 1 ~ f(d) Thus
and
{v. } as in Case i, Part i). The s u b s e q u e n t In i) yields a c o l l e c t i o n of at most %+s+2r points
n o w we h a v e
elements.
i),
exactly
two m e m b e r s ,
sequences
in Case
However,
P
has
satisfies
intersection the
theorem.
N {cl W Let
: W
:
112
Breen
B = {s : s E S
and
(p,s] ~ S
S ~ cl B c S , cl(S ~
choose
x
in
S
the case for
cl B) ! c! S ~
to show that
p
N
N
is selected
E ker cl S , [p,x]
of
k = 1 , then
(p,x) cl(P
k
P E P
, and
the reverse
.
p
in
conclude
that
N Q S .
Hence
N N S
is m i n i m a l
of
Since
inclusion,
It suffices
to censi'der
k ~ 1 .
z .
(p,x]
in
c S .
P ~ S , and
6 aff{z}
= {z}
Similarly,
N n B = @
and
.
Since
could not lie in a segment
p
k-flat
p ~ N
.
P
Since
We p r o c e e d by in--
P , 1 ~ k ~ d .
some point
T ~ then
lies in a
and so that
p ( ker cl(P N S)
have to be an isolated point choice of
such that k
and
at
z
x
c c] S , L(p,x) c p , and
would m e e t ~ S n S)
To e s t a b l i s h
x ( cl(S ~ cl B)
so that
d u c t i o n on the dimension If
cl(S ~ cl B) = cl S o
x # p .
Select a n e i g h b o r h o o d where
to show that
(p,x]
~S
, then
p E ker el(P A S) in
P ~ S .
Hence
z
However,
would
(@
and
p = z ~ impossible~
cS
o
~ [p~x]
{z}
(p,x']
x E S~cl
If
for all
B ! cl(S ~ cl B)
x~
by our
in
We
N NP AS =
, the desired
result. Assume
that the result
There are two cases j+l < d
or
CASE i.
Suppose
is not
sion at most
j
to consider.
j+l = d .
contained
We will
is true for
k , i ~ k < j < d , to prove Each argument
Of course~ w h e n
is independent
j+l = d , then
that for every n e i g h b o r h o o d in a finite union of flats
N' in
and c o n t a i n i n g
F
p , such that
of flats, B n P c U{F
: F
I)
For component
E
j-!
, aff(p
U E) to
with
N ~ c N ~ N~N S
of
cl(P
is a flat
N S) ~
in
P
(P N S)
in
F } .
Members
of
F
w h i c h has d i m e n s i o n at most
of d i m e n s i o n
at most
j o
Assign
F
For component
which
R = Rd
each h a v i n g d i m e n s i o n at most
in one of the following ways;
2)
of w h e t h e r
j .
define a finite family
U E)
x
j+l
P , each of w h i c h has dimen-
will be d e t e r m i n e d
aff(p
of
for
E EOUC
E
of
, assign
cl(P N S) ~ aff E
(P N S)
to
F
9
whose
Recall
dimension
p ( aff E
is
j
and for
for every
E
in
0UC 3)
Fqr component
which
E
~@UC
E
of ci(P N S) ~
(P N S)
, p r o c e e d as follows:
Since
whose E
dimension
is a
is
j
j-polytope,
and for each facet
Breen
G
113
of
E
or a
determines
(j-l)-flat
We assert
that
a
in
P .
P E ker cl(p
(P N S)
,
If
above~
Since
Thus
E
and
E
~0UC
If
c aff(p U E)
~OUC
, then
p E aff E ~ then
of
E , aff(p
c
U{F
: F
If
and
E
{F
L(p,s)
U G) = aff E
s E B n P ~
a component
j-i
, then
E aff E
: F
in
c aff E ~
and
aff E
Then of
rel bdry E .
If
E
~ S,
by I)
If
E
has
by 2) above.
has dimension
j
to examine: for an oppropriate
by 3) above.
Again
facet
s E aff E
(p,s)
meets
aff E
Let
G
be a facet of
U G)
(~
by 3) above,
at a singleton
point
E
e
containing
e~ , Then
O
U G)
We conclude Moreover,
, aff(p
that
since
cI(U{F
: F
Recall
that
B n P cU ~
in
N N S
N' n S
is not
: F
lies
in a finite
{xn}
: F
in
s EU
{F : F
collection
of closed
in F }
is establisbed.
sets,
cl(B n P)
c
N
is selected
in F}. (j+l)-flat
for every union
P
where
neighborhood
of flats
in F } .
N n S
and hence
in F } , and tbe a s s e r t i o n
in the
Moreover,
N' N S ~ U { F
sequence
{F : F
is a finite
F }) = U{F
is minimal~
Hence
(p,s]
EF
EF
O
s E aff(p
j+l
j-flat
cl(P n S)
in F } . aff E
Moreover, E F
E
aff(p U E)
and
F } .
a
o
, s EU {F : F
p
is either
in F } .
p ~ aff E ~ then
e
c
F
Let
meets
at most
to
, then there are two p o s s i b i l i t i e s
G
b)
E
aff(p U G)
in F } .
, (p,s)
has d i m e n s i o n
s E L(p,s)
j
Hence
aff(p U G)
{F : F N S)
s E aff(p U E) = aff E
and a)
Assign
B N P !
and since
dimension
(j-l)-flat.
in
P
to
x
of
having
By a standard
converging
N'
x
dimension
argument,
so that no
with
so that N' c
at most
we may select
x
N j a
is in U {F : F D
in F } ~
Then
S c p , so
{xn} i S
~
(U{F
: F
B N N ~ B N N n S !
in
F }) !
B N P , and
(S ~ cl(B N N)) = N N ( S ~ cl B) .
S ~cl(B
n P)
{x } c N n
We have a sequence
~
However,
(S ~ cl(B {x }
in
N N
N p)) c
N
N
S ~ cl B
n
converging
to
x , and
x
E cl(S ~ cl B)
, the desired
result.
Tbis
finishes
Case i, CASE 2,
Suppose
that for some n e i g h b o r h o o d
lies in a finite union j .
Choose
a sequence
and only one of these M
n
with
minimal
M and
n
n S
in a
kn K j
.
of flats {yn } flats.
to
Thus each
Yn
By o u r
P
of
x
P , each of which
converging
k -flat n
in
N'
n
where
induction
x
with
N' c
has dimension
so that each
YD
has an associated M
~
is
hypothesis,
E cl(S
, N'n S at most
lies in one
neighborhood
chosen so that Yn
N
~
cl
k B)
n
is for
114
each
Breen
n.
Hence there is a sequence
{z
} nm
Moreover,
we may assume that
dist(yn,Znm)
arguments reveal that the sequence cl B) , again the desired result.
{Znn }
in S ~ cl B I < --m for each converges to
This completes
converging
Standard
x ~ and
x ~ cl(S
Case 2.
k , 1 ~ k ~ j < d ~ it is true for
By induction,
k , 1 < k ~ d .
it is true for all
for all
x E S , so
the two sets are equal.
Thus
Yn ~
m .
Thus when the result is true for
cl B)
to
We conclude that
j§ x
.
~ cl(S
S ! cl(S ~ el B) , cl $ c cl(S ~ cl B) ~ and B
is nowhere dense in
S , and the proof of
Theorem 1 is established. Observe that when In conclusion,
d = 2 , the number
[i, Example 3]
finite Krasnosel'skii
f(d)
in the theorem is best possible~
shows that the theorem fails and in fact no
number is possible without
the requirement
that
~
S
have finitely many components.
REFERENCES [i]
BREEN, Mari!yn: 'A Krasnosel~skii-type theorem for nonclosed the plane,' Journal of Geometry 18 (1982), 28-42.
[2]
BREEN, Marilyn: 'An improved Krasnosel'skii theorem for nonclosed in the plane,' Journal of Geometry 21 (1983), 97-100.
[3]
BREEN, Marilyn: 'The dimension of the kernel of a planar set, ~ :Pacific J. Math. 82 (1979), 15-21.
[4]
KRASNOSEL'SKII, M.A.: 'Sur un critere pour Math. Sb. (61) 19 (1946), 309-310.
[5]
LAY, Steven R.: York, 1982.
[6]
VALENTINE,
qu' u n
Convex Sets and Their Applications,
F.A.:
Convex Sets, McGraw-Hill,
(Eimgegangen
am
29.
Nai
q98@)
sets
domain soit etoi!~, ~ John Wiley, New
New York, 1964.
University of Oklahoma Norman, Ok 73019 U.s.A.
sets in
