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Appendix 2: Ultrapowers That are Enlargements
& ULTRAPOWERS THAT ARE ENLARGEMENTS
APPENDIX
The
goal of this Appendix is to construct a special kind of
nonstandard models, in
the so-called enlargements,
that are needed
Section (0.4) as a first step in the process of defining
superstructure extensions (0.4.2),
(0.4.3)
that, we define
for which
the
the
important principles
and (0.4.4) are shown to hold.
In order to do
the ultrapower of a superstructure with respect
an ultrafilter, and then we show that for suitable ultra-
to
filters, this construction produces enlargements.
(APP.2.1) DEFINITION: J
Let U
5
be a nonempty set. A family of subsets of
U,V E U
(2) if
,
is called an ultrafilter when
P(J)
(1) if
J
€ U
U
,
then and
U n V EU V
,
satisfies U
V
C_
J
,
then
u ,
V € (3) for
every
subset
V ' SJ ,
complement J \ V € U ,
either
V € U
or
its
and not both.
(APP.2.2) REMARK: Nonempty (1)
and
prove
(2)
families of nonempty subsets of above are called filters.
J
It is not
that
satisfy
difficult
to
that 'ultrafilter' is the same as 'maximal filter' for the
relation
of inclusion, C
.
A standard application of
Zorn's
Lemma shows that each filter is contained in some ultrafilter.
Appendix
466
2
(APP.2.3) DEFINITION: Let
X
be a superstructure (see
infinite set, and
€u
g
J
x ,
into
f,g E
xJ ,
{j € J : f(j) = g(j)} € U
iff
J
an
.
If
call
{j € J : f(j) € g(j)} E U
iff
f =U g
J
an ultrafilter of subsets of
U
f,g are functions from f
(O.l.l)),
.
(APP.2.4) EXERCISE: are some simples exercises for the reader to get
Here
to these definitions. Show that for any (1)
=u
(2)
f
(3) f (4)
f, g
iff
{j E: J : f(j) f g(j)} E U ;
gU
iff
{j E: J : f(j)
g
f cUg
k
a l l €u-members of
(i.e.,
{j € J : f(j) 5 g(j))
,
f(j) = g(j)
and
then
f =
U
g
€ U ;
X
(3.8.3)],
x'
(see
, with x'(j)
that
in
transformed sentences,
into
=
want
to replace
.
super-
Stroyan-Luxemburg,
or Barwise [1978, Ch.
=
x
X
into
A.3, XJ
Theorem
given by
,
for all j E J
analog of the Transfer Principle (0.2.3)(a)
*
j's,
.
we know that for the embedding of --->
many
will be a fixed
Xo consequence of gas' Theorem
a
x an
are €u-members of
.
the rest of this Appendix,
[1976, Theorem 3.1]),
f
except for finitely
structure over a fixed ground set As
g(j)} 6 U ;
if the ultrafilter is free, that is, if n [ U : U E U ] =
0
For
,
f,g E X J
is an equivalence relation;
g) iff (5)
used
holds, provided
is changed into
eu
and
=
When we deal with nonstandard extension, though, we
EU,
=u
by actual 'belongs to'
and
'equals
2
Appendix
467
to'. That is why we make the next construction.
(APP.2.5) DEFINITION: Let
be any ultrafilter over
U
collapsing function
M
Xo
and call
Yo
class; let
.
The
Mostowski
is defined as follows.
(i) Take an element in
J
M(f)
f
of
whose images are
XJ
the corresponding
be the set of those
all
=U-equivalence
equivalence
classes
interpreted as new individuals. (ii) Assume
M(f)
for each
the elements in
xP
not in
p 2 0
that for some f & XpJ ; X
P+l
\
X P
we
have
defined
we are going to define it :
' M(f) = IM(g) : g
if
f
is in
J Xp
, g EU
X
for
and is
P+l
f}
(APP.2.6) DEFINITION: With the same notations as above, call structure on the ground set
where j E J
,
and define
* :x----
the constant function x ' ( j ) = x The ultrapower X J / U is the image of X
XI
.
Yo
the super-
Y
is
> Y
for
all
under
*.
(APP.2.7) REMARK: The
map
*
is a superstructure extension.
This means (see
its definition in the comments before (0.4.6)): (i)
*
is injective; the reader is invited to
supply
a
proof of this. (ii)
*
satisfies part (a) of Leibniz' Principle; this
is
Appendix
468
not
difficult
to
of
prove, but it is outside the scope
2
this
Appendix, since a much more careful treatment of bounded formulas is needed.
For a full proof of this and the Internal
Principle, we
refer
to any of the
following
Definition
books:
Stroyan-
Luxemburg [1976, Chapter 3, Sections 4 & 81, Davis [ 1977, Chapter Sections 7 & 81,
1,
Barwise [1978, Chapters A.6 & A.31; and for
an elementary version, to Keisler [1976, Section 1D*l
.
(APP.2.8) REMARK:
Moreover, whenever the ultrafilter chain
contains a descending
U
* is not
of sets with empty intersection, the map
(prove
so it becomes a meaningful extension.
it),
Examples
of
such ultrafilters are not hard to find; maybe the simplest one is a
maximal
filter
of parts of
N
that contains
the
so-called
Frbchet filter {A 5 N : N \ A
(apply
Zornls
is finite]
Lemma to prove the existence of
such
a
maximal
filter). However, we are interested in superstructure extensions that enjoy the stronger property of being enlargements, of
(0.4.6).
through
The
the
consistent
existence of enlargements can
Compactness
if
Theorem
("a
set
each of its finite subsets is
of
in the
be
sense
established
sentences
is
consistent"),
see
Robinson [1966, Chapter 21 for that approach; instead, we prefer to
show
stronger not
only
that
for
'adequate' ultrafilters
than that of the descending chain), a
true extension, but also
original superstructure.
an
(with a
property
the ultrapower enlargement
of
is the
2
Appendix
469
DEFINITION:
(APP.2.9)
We
say
the
ultrapower
e v e r y nonempty f a m i l y intersection
i s adequate
XJ/U
of s u b s e t s of
R
property ( i . e . ,
X
of
s € XJ
so t h a t
R
V B E R
3 U E U ,
for
with th e f i n i t e
such that every f i n i t e
h a s nonempty i n t e r s e c t i o n ) ,
family
when
sub-
there is a
map
.
B 2 s ( U )
(APP.2.10) EXAMPLES:
Let
(1)
X
,
be t h e s e t of f i n i t e p a r t s of t h e power s e t
J
J = Pf(P(X))
,
and
an u l t r a f i l t e r t h a t c o n t a i n s
U
of the
sets { j € J : A € j i s We c l a i m t h e u l t r a p o w e r
J X /U
A E X .
i s adequate.
t h e f i n i t e i n t e r s e c t i o n p r o p e r t y , then f o r each A . = n[B € R : B
s:J--->X
B € R
, i t is obvious t h a t
C a l l a binary relation
s u b s e t o f i t s domain,
finite
b € X
element
.
the
relations finite
x
concurrent i f f o r
,
S C_ dom(r)
every
t h e r e is always an
,
(a,b) € r
.
be t h e C a r t e s i a n p r o d u c t o f t h e f a m i l y
J
{Pf(dom(r)) : r € i.e.,
r €
such t h a t V a € S
Let
, the set
.
j E J
B z s ( { j € J : B € J}) (2)
J
be a c h o i c e f u n c t i o n
s ( j ) € Aj
Then f o r e v e r y
j
has
jl
J
i s n o t empty. Let
REP(X)
If
x
s e t o f a l l maps of
subset
i s a concurrent r e l a t i o n } j
d e f i n e d on t h e s e t o f
X
and such t h a t t h e image
of
i t s domain.
j(r)
( I t i s obvious
of
that
concurrent
r
is
a
concurrent
2
Appendix
470
r e l a t i o n s do e x i s t ,
so
i s n o t empty.) Next,
J
t a k e as
U
an
u l t r a f i l t e r that contains the s e t s i s a concurrent r e l a t i o n , then j o ( r ) c j ( r ) I . Then t h e u l t r a p o w e r X J / U i s adequate: l e t R E P ( X ) be a
U ( j ) = { j € J : i f r€X 0
family
the f i n i t e intersection property,
with
and
define
the
following binary r e l a t i o n : ( B , x ) E ro
ro i s a member of set
n j(ro)
and is c o n c u r r e n t :
X
n o t empty.
is
x E B € 8 ;
iff
Let
f o r each
--- >
s : J
j
be
X
€ J
, the
a
choice
function
s(j)e nj(ro) , For
every
B
if
j
Then,
therefore,
in
,
R
take a
,
cU(jB)
B 2 s(U(jB))
,
s
.
J
jBE J
the set
by d e f i n i t i o n of
E
j
so that
j B ( r o )= {B]
.
j(ro)
;
i s a member
B
s(j) € B
.
of
We have shown t h a t
.
(APP.2.11) PROPOSITION:
Every adequate u l t r a p o w e r i s an enlargement. PROOF: Let
A
be any member of
a *finite entity
in
F
X
.
We need t o show t h a t t h e r e i s
such t h a t
XJ/U
'A
C_ F
.
The f a m i l y IF € Pf(A) has
the
,
a E A
f i n i t e i n t e r s e c t i o n property.
a d e q u a t e , t h e r e i s a map
s : J --->X
s(U) 5 f o r some
: a € FI
U
in
U
.
{F
Pf(A)
Since th e ultrapower s o t h a t f o r each
is
a € A
: a € F]
Then { j € J : a E s ( j ) }€
By t h e d e f i n i t i o n of
,
M
,
u
it follows that
.*
a € M(s) €
*
Pf(A)
.
Appendix
Thus,
M(s)
471
is *finite and contains all
More simple ultrafilters, (APP.2.8),
‘A
= (*a
: a € A}
like the one mentioned in
. Remark
enjoy weaker forms of the Saturation and Comprehension
Principles (0.4.2) and (0.4.3). Stroyan-Luxemburg
[19761
properties of this type.
for
We refer the interested reader to
a
more
detailed
discussion
of
APPENDIX
The
goal of this Appendix is to construct a special kind of
nonstandard models, in
the so-called enlargements,
that are needed
Section (0.4) as a first step in the process of defining
superstructure extensions (0.4.2),
(0.4.3)
that, we define
for which
the
the
important principles
and (0.4.4) are shown to hold.
In order to do
the ultrapower of a superstructure with respect
an ultrafilter, and then we show that for suitable ultra-
to
filters, this construction produces enlargements.
(APP.2.1) DEFINITION: J
Let U
5
be a nonempty set. A family of subsets of
U,V E U
(2) if
,
is called an ultrafilter when
P(J)
(1) if
J
€ U
U
,
then and
U n V EU V
,
satisfies U
V
C_
J
,
then
u ,
V € (3) for
every
subset
V ' SJ ,
complement J \ V € U ,
either
V € U
or
its
and not both.
(APP.2.2) REMARK: Nonempty (1)
and
prove
(2)
families of nonempty subsets of above are called filters.
J
It is not
that
satisfy
difficult
to
that 'ultrafilter' is the same as 'maximal filter' for the
relation
of inclusion, C
.
A standard application of
Zorn's
Lemma shows that each filter is contained in some ultrafilter.
Appendix
466
2
(APP.2.3) DEFINITION: Let
X
be a superstructure (see
infinite set, and
€u
g
J
x ,
into
f,g E
xJ ,
{j € J : f(j) = g(j)} € U
iff
J
an
.
If
call
{j € J : f(j) € g(j)} E U
iff
f =U g
J
an ultrafilter of subsets of
U
f,g are functions from f
(O.l.l)),
.
(APP.2.4) EXERCISE: are some simples exercises for the reader to get
Here
to these definitions. Show that for any (1)
=u
(2)
f
(3) f (4)
f, g
iff
{j E: J : f(j) f g(j)} E U ;
gU
iff
{j E: J : f(j)
g
f cUg
k
a l l €u-members of
(i.e.,
{j € J : f(j) 5 g(j))
,
f(j) = g(j)
and
then
f =
U
g
€ U ;
X
(3.8.3)],
x'
(see
, with x'(j)
that
in
transformed sentences,
into
=
want
to replace
.
super-
Stroyan-Luxemburg,
or Barwise [1978, Ch.
=
x
X
into
A.3, XJ
Theorem
given by
,
for all j E J
analog of the Transfer Principle (0.2.3)(a)
*
j's,
.
we know that for the embedding of --->
many
will be a fixed
Xo consequence of gas' Theorem
a
x an
are €u-members of
.
the rest of this Appendix,
[1976, Theorem 3.1]),
f
except for finitely
structure over a fixed ground set As
g(j)} 6 U ;
if the ultrafilter is free, that is, if n [ U : U E U ] =
0
For
,
f,g E X J
is an equivalence relation;
g) iff (5)
used
holds, provided
is changed into
eu
and
=
When we deal with nonstandard extension, though, we
EU,
=u
by actual 'belongs to'
and
'equals
2
Appendix
467
to'. That is why we make the next construction.
(APP.2.5) DEFINITION: Let
be any ultrafilter over
U
collapsing function
M
Xo
and call
Yo
class; let
.
The
Mostowski
is defined as follows.
(i) Take an element in
J
M(f)
f
of
whose images are
XJ
the corresponding
be the set of those
all
=U-equivalence
equivalence
classes
interpreted as new individuals. (ii) Assume
M(f)
for each
the elements in
xP
not in
p 2 0
that for some f & XpJ ; X
P+l
\
X P
we
have
defined
we are going to define it :
' M(f) = IM(g) : g
if
f
is in
J Xp
, g EU
X
for
and is
P+l
f}
(APP.2.6) DEFINITION: With the same notations as above, call structure on the ground set
where j E J
,
and define
* :x----
the constant function x ' ( j ) = x The ultrapower X J / U is the image of X
XI
.
Yo
the super-
Y
is
> Y
for
all
under
*.
(APP.2.7) REMARK: The
map
*
is a superstructure extension.
This means (see
its definition in the comments before (0.4.6)): (i)
*
is injective; the reader is invited to
supply
a
proof of this. (ii)
*
satisfies part (a) of Leibniz' Principle; this
is
Appendix
468
not
difficult
to
of
prove, but it is outside the scope
2
this
Appendix, since a much more careful treatment of bounded formulas is needed.
For a full proof of this and the Internal
Principle, we
refer
to any of the
following
Definition
books:
Stroyan-
Luxemburg [1976, Chapter 3, Sections 4 & 81, Davis [ 1977, Chapter Sections 7 & 81,
1,
Barwise [1978, Chapters A.6 & A.31; and for
an elementary version, to Keisler [1976, Section 1D*l
.
(APP.2.8) REMARK:
Moreover, whenever the ultrafilter chain
contains a descending
U
* is not
of sets with empty intersection, the map
(prove
so it becomes a meaningful extension.
it),
Examples
of
such ultrafilters are not hard to find; maybe the simplest one is a
maximal
filter
of parts of
N
that contains
the
so-called
Frbchet filter {A 5 N : N \ A
(apply
Zornls
is finite]
Lemma to prove the existence of
such
a
maximal
filter). However, we are interested in superstructure extensions that enjoy the stronger property of being enlargements, of
(0.4.6).
through
The
the
consistent
existence of enlargements can
Compactness
if
Theorem
("a
set
each of its finite subsets is
of
in the
be
sense
established
sentences
is
consistent"),
see
Robinson [1966, Chapter 21 for that approach; instead, we prefer to
show
stronger not
only
that
for
'adequate' ultrafilters
than that of the descending chain), a
true extension, but also
original superstructure.
an
(with a
property
the ultrapower enlargement
of
is the
2
Appendix
469
DEFINITION:
(APP.2.9)
We
say
the
ultrapower
e v e r y nonempty f a m i l y intersection
i s adequate
XJ/U
of s u b s e t s of
R
property ( i . e . ,
X
of
s € XJ
so t h a t
R
V B E R
3 U E U ,
for
with th e f i n i t e
such that every f i n i t e
h a s nonempty i n t e r s e c t i o n ) ,
family
when
sub-
there is a
map
.
B 2 s ( U )
(APP.2.10) EXAMPLES:
Let
(1)
X
,
be t h e s e t of f i n i t e p a r t s of t h e power s e t
J
J = Pf(P(X))
,
and
an u l t r a f i l t e r t h a t c o n t a i n s
U
of the
sets { j € J : A € j i s We c l a i m t h e u l t r a p o w e r
J X /U
A E X .
i s adequate.
t h e f i n i t e i n t e r s e c t i o n p r o p e r t y , then f o r each A . = n[B € R : B
s:J--->X
B € R
, i t is obvious t h a t
C a l l a binary relation
s u b s e t o f i t s domain,
finite
b € X
element
.
the
relations finite
x
concurrent i f f o r
,
S C_ dom(r)
every
t h e r e is always an
,
(a,b) € r
.
be t h e C a r t e s i a n p r o d u c t o f t h e f a m i l y
J
{Pf(dom(r)) : r € i.e.,
r €
such t h a t V a € S
Let
, the set
.
j E J
B z s ( { j € J : B € J}) (2)
J
be a c h o i c e f u n c t i o n
s ( j ) € Aj
Then f o r e v e r y
j
has
jl
J
i s n o t empty. Let
REP(X)
If
x
s e t o f a l l maps of
subset
i s a concurrent r e l a t i o n } j
d e f i n e d on t h e s e t o f
X
and such t h a t t h e image
of
i t s domain.
j(r)
( I t i s obvious
of
that
concurrent
r
is
a
concurrent
2
Appendix
470
r e l a t i o n s do e x i s t ,
so
i s n o t empty.) Next,
J
t a k e as
U
an
u l t r a f i l t e r that contains the s e t s i s a concurrent r e l a t i o n , then j o ( r ) c j ( r ) I . Then t h e u l t r a p o w e r X J / U i s adequate: l e t R E P ( X ) be a
U ( j ) = { j € J : i f r€X 0
family
the f i n i t e intersection property,
with
and
define
the
following binary r e l a t i o n : ( B , x ) E ro
ro i s a member of set
n j(ro)
and is c o n c u r r e n t :
X
n o t empty.
is
x E B € 8 ;
iff
Let
f o r each
--- >
s : J
j
be
X
€ J
, the
a
choice
function
s(j)e nj(ro) , For
every
B
if
j
Then,
therefore,
in
,
R
take a
,
cU(jB)
B 2 s(U(jB))
,
s
.
J
jBE J
the set
by d e f i n i t i o n of
E
j
so that
j B ( r o )= {B]
.
j(ro)
;
i s a member
B
s(j) € B
.
of
We have shown t h a t
.
(APP.2.11) PROPOSITION:
Every adequate u l t r a p o w e r i s an enlargement. PROOF: Let
A
be any member of
a *finite entity
in
F
X
.
We need t o show t h a t t h e r e i s
such t h a t
XJ/U
'A
C_ F
.
The f a m i l y IF € Pf(A) has
the
,
a E A
f i n i t e i n t e r s e c t i o n property.
a d e q u a t e , t h e r e i s a map
s : J --->X
s(U) 5 f o r some
: a € FI
U
in
U
.
{F
Pf(A)
Since th e ultrapower s o t h a t f o r each
is
a € A
: a € F]
Then { j € J : a E s ( j ) }€
By t h e d e f i n i t i o n of
,
M
,
u
it follows that
.*
a € M(s) €
*
Pf(A)
.
Appendix
Thus,
M(s)
471
is *finite and contains all
More simple ultrafilters, (APP.2.8),
‘A
= (*a
: a € A}
like the one mentioned in
. Remark
enjoy weaker forms of the Saturation and Comprehension
Principles (0.4.2) and (0.4.3). Stroyan-Luxemburg
[19761
properties of this type.
for
We refer the interested reader to
a
more
detailed
discussion
of