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Chapter 14 Notation and Multilinear Mappings
CHAPTER 14 NOTATION AND MULTILINEAR MAPPINGS
Unless stated otherwise, U
locally convex spaces, and
IN, IR
E.
subset of
G
and
E
and
F
will denote complex
will denote a non-empty open denote respectively the sets of
natural numbers, of real numbers and of complex numbers. IN*
{1,2,3, ...).
denotes the set and
SC(E)
SC(F)
denote respectively the sets of conand
tinuous seminorms on
E
DEFINITION 14.1
m E N*.
Let
F.
ra(%;F)
E~ = EXE
all m-linear mappings o f
denotes the set of
x...~ E
times) into F,
(m
the operations of addition and scalar multiplication being defined pointwise. Ca(%;F)
Ca,(%;F)
denotes the subspace of
of all symmetric m-linear mappings. (%;F)
'as
for every
means that
xl,...,x
m E E
and every
set of all permutations of
If A E Sa(%;F), element
As
Thus
of
u E Sm, Sm
{1,2,...,m].
the symmetrization of
.Cas(%;F)
being the
defined by
155
A
is the
14
CHAPTER
156 for
x1,x2
,...,
xm E E .
We d e n o t e by
C(%;F)
v e c t o r subspaces of
and
ga(%;F)
Xs(%;F)
respectively the
gas (%;F)
and
c o n s i s t i n g of
c o n t i n u o u s mappings.
m = 0,
For
we d e f i n e
La(OE;F)
:= L(OE;F) := Ss(OE;F) := F
= A
A
for
E
:= SaS(OE;F) :=
a s v e c t o r s p a c e s , and we s e t
~,(OE;F).
Ak+As
i s a pro-
which maps
S(%;F)
I t i s e a s y t o s e e t h a t t h e mapping j e c t i o n of onto
ea(%;F)
Ss(%;F)
onto
= S(%)
write
Sa(’E;F)
t h e spaces
m
for e v e r y
E
= ga(E;F)
gas
ga(”’E),
= Cs(%).
gs(%;C)
and
and
X(’E;F)
,...,1,
E
(c,
s o t h e mapping
then
A(X1
and
f i n e d as follows:
m = 0,
if
Ax
0
we
If E = C,
Ls(mC;F) a r e
A(1,
...,I),
and
i s an isomorphism.
A E Sa(%;F)
Let
= Sas(%),
For if
= X1...l,
.,.,l) E F
A+-A(l,
DEFINITION 1 4 . 2
,..,X m )
we
m = 1,
= L(E;F).
a l l n a t u r a l l y isomorphic w i t h one a n o t h e r .
hl
(%el
For
gas (mC;F), S(%;F)
Ca(mG;F),
F = C
I n the case
[N.
s ~ ( ? E ; c )=
w r i t e for s i m p l i c i t y ,
L(%;C)
Sas(%;F)
and
x E E.
= A E F.
Axm
m E
If
i s deIN”,
m times
...,x ) . Sa(%;F), x1 ,...,xk E 7----L_\
Axm More g e n e r a l l y , l e t
E N,
m,nl,n2,,..’nk n Axl’.
If
.
n .xkk
A
E
and
= A(x,x,
n = n +n2 1
i s d e f i n e d as f o l l o w s :
m = n > 0,
+...+ If
n
E,
s m.
m = 0,
k E IN”,
Then
nl Axl
.,
n .xkk = A.
157
NOTATION AND MULTILINEAR MAPPINGS
where
each
xi
is repeated
by
5
n n 1 k (AX1 * * * X k)(Y1,***tYm-,) ~
1
n l Axl
Then
, Y ~ ,E ~E
9
...
nk
xk
is symmetric if
times
and
0,
is defined
nk times
,. - J
'(X~Y...YX~Y***,~,*~. ,X~,Y~Y***YY,-,)
nl in each casey and Ax1
E Xa(m-%;F) A
...x2
,-A
=
ni >
times if n m > n, Axl
ni = 0. And if
omitted if
where
ni
is symmetic, and continuous if
...xn
k
k
is
A
continuous. LEMMA 14.1 (Newtonfs Formula). x1
,...,xk E
E,
k E N*,
m,n E IN
A(x 1+X 2+...+x~)~ =
PROOF: A(xl+
+...+nk
The case
...+xk)
n
then f o r each
n = 0
A E Las(%;F),
and
n c m.
' ...
the sum being taken over all n = n,
Let
nl!
n
n!
nk!
nl,...,nk E
is trivial.
Then
If
...+x~,...~x1+...+x (y, ,...,ymen) E Em-n,
= A(xl+
ax^ l [N
nk k '
f o r which
m = n > 0, then
k).
If m > n >
0,
In each case, the given expression may be expanded, using the fact that
A
is multilinear and symmetric, and it is easy to
see that the number of occurrences of.:xA the number of permutations of
xl,.. .,xk,
.
.xF
where
is equal to x1
is re-
158 peated
CHAPTER
nl
times,
this number is
...,xk
... n!
nl!
!nk!
14
i s repeated
nk
times.
t h e lemma is proved.
Since
Q.E.D.
Unless stated otherwise, U
locally convex spaces, and
IN, IR
E.
subset of
G
and
E
and
F
will denote complex
will denote a non-empty open denote respectively the sets of
natural numbers, of real numbers and of complex numbers. IN*
{1,2,3, ...).
denotes the set and
SC(E)
SC(F)
denote respectively the sets of conand
tinuous seminorms on
E
DEFINITION 14.1
m E N*.
Let
F.
ra(%;F)
E~ = EXE
all m-linear mappings o f
denotes the set of
x...~ E
times) into F,
(m
the operations of addition and scalar multiplication being defined pointwise. Ca(%;F)
Ca,(%;F)
denotes the subspace of
of all symmetric m-linear mappings. (%;F)
'as
for every
means that
xl,...,x
m E E
and every
set of all permutations of
If A E Sa(%;F), element
As
Thus
of
u E Sm, Sm
{1,2,...,m].
the symmetrization of
.Cas(%;F)
being the
defined by
155
A
is the
14
CHAPTER
156 for
x1,x2
,...,
xm E E .
We d e n o t e by
C(%;F)
v e c t o r subspaces of
and
ga(%;F)
Xs(%;F)
respectively the
gas (%;F)
and
c o n s i s t i n g of
c o n t i n u o u s mappings.
m = 0,
For
we d e f i n e
La(OE;F)
:= L(OE;F) := Ss(OE;F) := F
= A
A
for
E
:= SaS(OE;F) :=
a s v e c t o r s p a c e s , and we s e t
~,(OE;F).
Ak+As
i s a pro-
which maps
S(%;F)
I t i s e a s y t o s e e t h a t t h e mapping j e c t i o n of onto
ea(%;F)
Ss(%;F)
onto
= S(%)
write
Sa(’E;F)
t h e spaces
m
for e v e r y
E
= ga(E;F)
gas
ga(”’E),
= Cs(%).
gs(%;C)
and
and
X(’E;F)
,...,1,
E
(c,
s o t h e mapping
then
A(X1
and
f i n e d as follows:
m = 0,
if
Ax
0
we
If E = C,
Ls(mC;F) a r e
A(1,
...,I),
and
i s an isomorphism.
A E Sa(%;F)
Let
= Sas(%),
For if
= X1...l,
.,.,l) E F
A+-A(l,
DEFINITION 1 4 . 2
,..,X m )
we
m = 1,
= L(E;F).
a l l n a t u r a l l y isomorphic w i t h one a n o t h e r .
hl
(%el
For
gas (mC;F), S(%;F)
Ca(mG;F),
F = C
I n the case
[N.
s ~ ( ? E ; c )=
w r i t e for s i m p l i c i t y ,
L(%;C)
Sas(%;F)
and
x E E.
= A E F.
Axm
m E
If
i s deIN”,
m times
...,x ) . Sa(%;F), x1 ,...,xk E 7----L_\
Axm More g e n e r a l l y , l e t
E N,
m,nl,n2,,..’nk n Axl’.
If
.
n .xkk
A
E
and
= A(x,x,
n = n +n2 1
i s d e f i n e d as f o l l o w s :
m = n > 0,
+...+ If
n
E,
s m.
m = 0,
k E IN”,
Then
nl Axl
.,
n .xkk = A.
157
NOTATION AND MULTILINEAR MAPPINGS
where
each
xi
is repeated
by
5
n n 1 k (AX1 * * * X k)(Y1,***tYm-,) ~
1
n l Axl
Then
, Y ~ ,E ~E
9
...
nk
xk
is symmetric if
times
and
0,
is defined
nk times
,. - J
'(X~Y...YX~Y***,~,*~. ,X~,Y~Y***YY,-,)
nl in each casey and Ax1
E Xa(m-%;F) A
...x2
,-A
=
ni >
times if n m > n, Axl
ni = 0. And if
omitted if
where
ni
is symmetic, and continuous if
...xn
k
k
is
A
continuous. LEMMA 14.1 (Newtonfs Formula). x1
,...,xk E
E,
k E N*,
m,n E IN
A(x 1+X 2+...+x~)~ =
PROOF: A(xl+
+...+nk
The case
...+xk)
n
then f o r each
n = 0
A E Las(%;F),
and
n c m.
' ...
the sum being taken over all n = n,
Let
nl!
n
n!
nk!
nl,...,nk E
is trivial.
Then
If
...+x~,...~x1+...+x (y, ,...,ymen) E Em-n,
= A(xl+
ax^ l [N
nk k '
f o r which
m = n > 0, then
k).
If m > n >
0,
In each case, the given expression may be expanded, using the fact that
A
is multilinear and symmetric, and it is easy to
see that the number of occurrences of.:xA the number of permutations of
xl,.. .,xk,
.
.xF
where
is equal to x1
is re-
158 peated
CHAPTER
nl
times,
this number is
...,xk
... n!
nl!
!nk!
14
i s repeated
nk
times.
t h e lemma is proved.
Since
Q.E.D.