1. Introduction and preliminaries
In the following, we tried very hard to make the present article as self-contained as possible. For notions and notation which remain unexplained, the reader may refer to [Reference Jech23, Reference Kanamori24], or [Reference Kunen25]. Set-theoretic forcing is treated here just as in [Reference Kunen25] with the exception that
${\mathbb {P}}$
-names for a poset
${\mathbb {P}}$
are represented with an under-tilde, e.g., as 
. We adopt the (fake but consistently interpretable) narration that generic filters “exist” though otherwise we remain in the ZFC narrative so that all classes mentioned here are (meta-mathematically) definable classes.
The main theorem of Viale [Reference Viale32] states the following.
Theorem 1.1 [(M. Viale, Theorem 1.4 in [Reference Viale32])].
Assume that MM
$^{++}$
holds, and there are class many Woodin cardinals. Then, for any stationary preserving poset
${\mathbb {P}}$
with
$\,\|\hspace {-.35ex}\textsf {--}_{\,{\mathbb {P}}\,}{"}\,\textsf {BMM}\text{"}$
, we have
$$ \begin{align*} {\mathcal{H}}(\aleph_2)^{\mathsf{V}}\prec_{\Sigma_2}{\mathcal{H}}(\aleph_2)^{{\mathsf{V}}[{\mathbb{G}}]}\quad \textit{for} \ ({\mathsf{V}},{\mathbb{P}})\text{-}\textit{generic}\ {\mathbb{G}}. \end{align*} $$
Here MM
$^{++}$
is the following strengthening of the Martin’s Axiom (MM):
-
(MM ++): For any stationary preserving
${\mathbb {P}}$
, any family
${\mathcal {D}}$
of dense subsets of
${\mathbb {P}}$
with
$\mathopen {|\,}{\mathcal {D}}\mathclose {\,|}<\aleph _2$
, and any family
${\mathcal S}$
of
${\mathbb {P}}$
-names of stationary subsets of
$\omega _1$
with
$\mathopen {|\,}{\mathcal S}\mathclose {\,|}<\aleph _2$
, there is a
${\mathcal {D}}$
-generic filter
${\mathbb {G}}$
on
${\mathbb {P}}$
such that is a stationary subset of
$\omega _1$
for all .
is a stationary subset of 
.
BMM is the Bounded Martin’s Maximum, a weakening of MM which is an instance of Bounded Forcing Axioms: for a class
${\mathcal P}$
of posets closed under forcing equivalence and a cardinal
$\kappa $
, the Bounded Forcing Axiom for
${\mathcal P}$
and
${<}\,\kappa $
is the axiom stating:
-
(BFA < κ (𝒫)): For any complete BooleanFootnote 2
${\mathbb {P}}\in {\mathcal P}$
, and a family
${\mathcal {D}}$
of maximal antichains in
${\mathbb {P}}$
such that
$\mathopen {|\,}{\mathcal {D}}\mathclose {\,|}<\kappa $
and
$\mathopen {|\,}I\mathclose {\,|}<\kappa $
for all
$I\in {\mathcal {D}}$
, there is a
${\mathcal {D}}$
-generic filter
${\mathbb {G}}$
on
${\mathbb {P}}$
.
The Bounded Martin’s Maximum (BMM) is
$\textsf {BFA}_{{<}\,\aleph _2}(\text {stationary pres. posets})$
. Bounded Forcing Axioms were introduced by Goldstern and Shelah [Reference Goldstern and Shelah18] answering a problem asked by the first author of the present paper in [Reference Fuchino10].
In Theorem 1.1, the condition “
$\,\|\hspace {-.35ex}\textsf {--}_{\,{\mathbb {P}}\,}{"}\,\textsf {BMM}\,\text{"}$
” cannot be simply dropped. For example, the formula saying that there is a set which is the power set of
$\omega $
is
$\Sigma _2$
. Since
$\neg \textsf {CH}$
holds in
$\mathsf {V}$
under MM, if
${\mathbb {P}}$
forces CH then
${\mathcal {H}}(\aleph _2)^{\mathsf {V}}\not \prec _{\Sigma _2}{\mathcal {H}}(\aleph _2)^{\mathsf {V}[{\mathbb {G}}]}$
for
$(\mathsf {V},{\mathbb {P}})$
-generic
${\mathbb {G}}$
.
We show that a conclusion similar to and more general than that of Theorem 1.1 follows from each of
$({\mathcal P},{\mathcal {H}}(\kappa))_{\Sigma _2}$
-RcA
$^+$
which is a fragment of Recurrence Axiom (a reformulation of Maximality Principle introduced in [Reference Fuchino and Usuba15]) for
${\mathcal P}$
and
${\mathcal {H}}(\kappa)$
, see Section 2 below, and the existence of the tightly
${\mathcal P}$
-Laver-gen. large cardinal (Theorems 4.1 and 5.7).
The notion of Laver-generic large cardinal is introduced in Fuchino et al., [Reference Fuchino, Rodrigues and Sakai13]. The definition we give here is the slightly modified version in later papers such as in Fuchino [Reference Fuchino11].
For an iterable class
${\mathcal P}$
of posets (i.e., class
${\mathcal P}$
of posets satisfying (1.2) and (1.3) below) a cardinal
$\kappa $
is said to be (tightly, resp.)
${\mathcal P}$
-Laver-gen. supercompact if, for any
$\lambda>\kappa $
and
${\mathbb {P}}\in {\mathcal P}$
, there is a
${\mathbb {P}}$
-name 
with 
, such that for 
-generic
$\mathbb {H}$
, there are
$j, M\subseteq \mathsf {V}[\mathbb {H}]$
such that
$j:\mathsf {V}\stackrel {\prec \hspace {0.8ex}}{\rightarrow }_{\kappa }M$
,Footnote
3
$j(\kappa)>\lambda $
,
${\mathbb {P}},\mathbb {H}, j{}^{\,{\prime }{\prime }}\lambda \in M$
(and 
is of size
$\leq j(\kappa)$
, resp.).
This definition can be adopted to many other large cardinal notions other than supercompactness. The reader may refer to [Reference Fuchino11] for definitions of other variants of Laver-generic large cardinal. Defined as above, it is not obvious at first glance that the Laver-genericity is formalizable in the language
${{\mathcal L}}_{\in }$
of ZFC. That it is actually the case, is shown in Fuchino and Sakai [Reference Fuchino and Sakai14].
A tightly
${\mathcal P}$
-Laver-generic large cardinal, if it exists, is unique and decided to be
$\kappa _{\mathfrak {r}\mathfrak {e}\mathfrak {f}\mathfrak {l}\,}:=\max (\{\aleph _2,2^{\aleph _0}\})$
for all known reasonable non-trivial instances of
${\mathcal P}$
with a strong enough large cardinal notion (see [Reference Fuchino, Rodrigues and Sakai13], or [Reference Fuchino11, Reference Fuchino12]). This is the reason why we often simply talk about the tightly
${\mathcal P}$
-Laver-generic large cardinal.
While under “
${\mathcal P}=$
all semi-proper posets”, our results are not much more than slight variants of Viale’s (but without relying on the stationary tower forcing technique), for other classes of posets, for example, “
${\mathcal P}=$
all proper posets” or “
${\mathcal P}=$
all ccc posets”, they are not at all covered by Viale’s result in [Reference Viale32] nor by its proof.
In the following we shall always assume that the classes
${\mathcal P}$
of posets we consider are normal, that is,
-
(1.1)
${\mathcal P}$
is closed with respect to forcing equivalence, and
$\{{\mathord {\mathbb {1}}}\}\in {\mathcal P}$
.
In particular, we assume that for any
${\mathbb {P}}_0\in {\mathcal P}$
there is a complete Boolean3
${\mathbb {P}}\in {\mathcal P}$
which is forcing equivalent to
${\mathbb {P}}_0$
. In some cases like the case “
${\mathbb {P}}=$
all
$\sigma $
-closed posets” where the original class of posets is not normal we just replace
${\mathcal P}$
with its closure with respect to forcing equivalence without mention.
In some cases (like in the definition of Laver-genericity above) it is natural to consider (normal) classes of posets which are closed with respect to two-step iteration. A class
${\mathcal P}$
of posets is called iterable if
-
(1.2)
${\mathcal P}$
is closed with respect to restriction. That is, for
${\mathbb {P}}\in {\mathcal P}$
and , we always have , and -
(1.3) For any
${\mathbb {P}}\in {\mathcal P}$
, and any
${\mathbb {P}}$
-name of a poset with , we have .
, we always have 
, and
of a poset with 
, we have 
. Viale’s Absoluteness Theorem 1.1 is a result built upon the following Theorem 1.2. We shall use the following notation for the formulation of the Theorem. For an ordinal
$\alpha $
, let
${\alpha ^{(+)}}:=\sup (\{\mathopen {|\,}\beta \mathclose {\,|}^+\,:\,\beta <\alpha \})$
. Note that
$\alpha ^{(+)}=\alpha $
if
$\alpha $
is a cardinal. Otherwise, we have
$\alpha ^{(+)}=\mathopen {|\,}\alpha \mathclose {\,|}^+$
.
In Bagaria [Reference Bagaria3] the following theorem contains the extra assumption that, translated into the context of the following formulation,
$\kappa $
is a successor of a cardinal of uncountable cofinality. However we can eliminate this assumption by slightly modifying the proof in [Reference Bagaria3].
Theorem 1.2 (Bagaria’s Absoluteness Theorem, Theorem 5 in [Reference Bagaria3]).
For an uncountable cardinal
$\kappa $
and a class
${\mathcal P}$
of posets closed under forcing equivalence, and restriction (in the sense of (1.2)) the following are equivalent:
-
(a)
$\textsf {BFA}_{{<}\,\kappa }({\mathcal P})$
. -
(b) For any
${\mathbb {P}}\in {\mathcal P}$
,
$\Sigma _1$
-formula
$\varphi $
in
${{\mathcal L}}_{\in }$
and
$a\in {\mathcal {H}}(\kappa)$
,
$\,\|\hspace {-.35ex}\textsf {--}_{\,{\mathbb {P}}\,}{"}\,\varphi (a)\text{"} \Leftrightarrow \varphi (a)$
. -
(c) For any
${\mathbb {P}}\in {\mathcal P}$
and
$(\mathsf {V},{\mathbb {P}})$
-generic
${\mathbb {G}}$
, we have
${\mathcal {H}}(\kappa )^{\mathsf {V}}\prec _{\Sigma _1}{\mathcal {H}}((\kappa ^{(+)})^{\mathsf {V}[{\mathbb {G}}]})^{\mathsf {V}[{\mathbb {G}}]}$
.
Proof. Note that (b)
$\Leftrightarrow $
(c) is trivial since ZFC proves that
-
(1.4)
${\mathcal {H}}(\mu)\prec _{\Sigma _1}\mathsf {V}$
for any uncountable cardinal
$\mu $
(Lévy [Reference Lévy27]).
Note also that if
$\kappa =2^{\aleph _0}$
, we also have the equivalence of (a), (b), (c) with
-
(c′) For any
${\mathbb {P}}\in {\mathcal P}$
and
$(\mathsf {V},{\mathbb {P}})$
-generic
${\mathbb {G}}$
, we have
${\mathcal {H}}(2^{\aleph _0})^{\mathsf {V}}\prec _{\Sigma _1}{\mathcal {H}}((2^{\aleph _0})^{\mathsf {V}[{\mathbb {G}}]})^{\mathsf {V}[{\mathbb {G}}]}$
.
The following is one of many nice applications of Theorem 1.2.
Corollary 1.3. If
${\mathcal P}$
contains a poset adding a new real then
$\textsf {BFA}_{{<}\,\kappa }({\mathcal P})$
for
$\kappa>\aleph _1$
implies
$\neg \textsf {CH}$
.
Proof. Assume that
$\textsf {BFA}_{{<}\,\kappa }({\mathcal P})$
holds for
$\kappa>\aleph _1$
, but also CH holds in
$\mathsf {V}$
. Let 
. We have
$a\in {\mathcal {H}}(\kappa)^{\mathsf {V}}$
by CH and 
. The statement can be formulated as a
$\Pi _1$
-formula with the parameter a. But if
${\mathbb {P}}\in {\mathcal P}$
adds a real, 
. This is a contradiction to Theorem 1.2, (c).
Suppose that
${\mathcal R}$
is a definable class (proper or set). We shall say that a class
${\mathcal P}$
of posets is provably correct for
${\mathcal R}$
if the following is provable in ZFC:
-
(1.5) for any
${\mathbb {P}}\in {\mathcal P}$
and
$a (\in \mathsf {V})$
,
$a\in {\mathcal R} \Leftrightarrow \,\|\hspace {-.35ex}\textsf {--}_{\,{\mathbb {P}}\,}{"}\,a\in {\mathcal R}\text{"}$
.
Thus if
${\mathcal P}$
is provably correct for
${\mathcal R}$
and
${\mathbb {G}}$
is a
$(\mathsf {V},{\mathbb {P}})$
-generic for a
${\mathbb {P}}\in {\mathcal P}$
then
$(\mathsf {V},\in ,{\mathcal R}^{\mathsf {V}})$
is a (class) substructure of
$(\mathsf {V}[{\mathbb {G}}],\in ,{\mathcal R}^{\mathsf {V}[{\mathbb {G}}]})$
.
Let
$I_{\mathsf {NS}}$
denote the non stationary ideal over
$\omega _1$
. Thus
-
$I_{\textsf {NS}}:=\{X\subseteq \omega _1\,:\,X \text { is non stationary}\}$
.
Lemma 1.4. If (we can prove that) all
${\mathbb {P}}\in {\mathcal P}$
are stationary preserving then
${\mathcal P}$
is provably correct for
$I_{\textsf {NS}}$
.
Let
${\mathcal R}$
be (the
${{\mathcal L}}_{\in }$
-definition of) a class. Let 
be the language which extends
${{\mathcal L}}_{\in }$
with a new unary predicate symbol 
where 
is interpreted as
$a\in {\mathcal R}^M$
in an
$\in $
-structure M. In the following, we shall often identify the (definition) of the class
${\mathcal R}$
with the symbol 
of
${\mathcal R}$
, and simply write
${\mathcal R}$
and
${\mathcal L}_{\in ,{\mathcal R}}$
instead of 
and 
. This also applies when we are talking about
$I_{\textsf {NS}}$
and
${\mathcal L}_{\in ,I_{\textsf {NS}}}$
.
The following Lemma 1.5 can be proved in the same way as with the corresponding lemma for
${{\mathcal L}}_{\in }$
formulas.
Lemma 1.5. For transitive (sets or classes) M, N with
$M\subseteq N$
and a class
${\mathcal R}$
(i.e. an
${{\mathcal L}}_{\in }$
-formula with one single free variable) such that
${\mathcal R}^M={\mathcal R}^N\cap M$
, we have:
-
(1)
$\langle M,\in ,{\mathcal R}^M\rangle \models \varphi (\overline {a}) \Leftrightarrow \langle N,\in ,{\mathcal R}^N\rangle \models \varphi (\overline {a})$
for all
$\Sigma _0$
-formula
$\varphi =\varphi (\overline {x})$
in
${\mathcal L}_{\in ,{\mathcal R}}$
and
$\overline {a}\in M$
. -
(2)
$\langle M,\in ,{\mathcal R}^M\rangle \models \varphi (\overline {a}) \Rightarrow \langle N,\in ,{\mathcal R}^N\rangle \models \varphi (\overline {a})$
for all
$\Sigma _1$
-formula
$\varphi =\varphi (\overline {x})$
in
${\mathcal L}_{\in ,{\mathcal R}}$
and
$\overline {a}\in M$
.
Lemma 1.6. For a
$\Sigma _1$
-formula
$\varphi $
in
${\mathcal L}_{\in ,I_{\textsf {NS}}}$
we can find a
$\Sigma _2$
-formula in
${{\mathcal L}}_{\in }$
with the parameter
$\omega _1$
equivalent to
$\varphi $
.
Proof. “
$x\in I_{\textsf {NS}}$
” can be expressed by a
$\Sigma _1$
-formula in
${{\mathcal L}}_{\in }$
:
-
$\exists y\,(y\subseteq \omega _1\ \land \ x\subseteq \omega _1\ \land \ y\text { is a club in }\omega _1\ \land \ x\cap y=\emptyset).$
Thus “
$x\not \in I_{\textsf {NS}}$
” can be expressed by a
$\Pi _1$
-formula in
${{\mathcal L}}_{\in }$
.
Lemma 1.7 (A special case of Lemma 6.3 in Venturi and Viale [Reference Venturi and Viale31]).
For a cardinal
$\lambda \geq 2^{\aleph _1}$
, we have
$\langle {\mathcal {H}}(\lambda),\,{\in },\,I_{\textsf {NS}}\rangle \prec _{\Sigma _1}(\mathsf {V},\,{\in },\,I_{\textsf {NS}})$
.
The following Theorem 1.8 is an extension of Bagaria’s Absoluteness Theorem 1.2. A special case of this theorem (the case where
${\mathcal P}={}$
the stationary preserving posets) is also attributed to Bagaria in [Reference Woodin33]. Though Theorem 1.8 in its generality must have been known, we included it here since we could not find any proof in the literature.
We consider the following “plus”-version of Bounded Forcing Axioms: For a (normal) class of posets
${\mathcal P}$
,
-
(
${\sf BFA}^{+{<}\,\kappa}_{{<}\,\kappa}({\mathcal P})$
): For any complete Boolean
${\mathbb {P}}\in {\mathcal P}$
, a family
${\mathcal {D}}$
of maximal antichains in
${\mathbb {P}}$
such that
$\mathopen {|\,}{\mathcal {D}}\mathclose {\,|}<\kappa $
and
$\mathopen {|\,}I\mathclose {\,|}<\kappa $
for all
$I\in {\mathcal {D}}$
, and for a set
${\mathcal S}$
of
${\mathcal P}$
-names of cardinality
$<\kappa $
such that each is a
${\mathbb {P}}$
-name of a stationary subset of
$\omega _1$
, there is a
${\mathcal {D}}$
-generic filter
${\mathbb {G}}$
on
${\mathbb {P}}$
such that are stationary subsets of
$\omega _1$
.
is a 
are stationary subsets of 
Theorem 1.8. Suppose that
${\mathcal P}$
is a class of posets closed under forcing equivalence, and restriction (in the sense of (1.2)) such that all elements of
${\mathcal P}$
are stationary preserving and
$\kappa =2^{\aleph _0}=2^{\aleph _1}$
.Footnote
4
Then the following are equivalent:
-
(a)
$\textsf {BFA}^{+{<}\,\kappa }_{{<}\,\kappa }({\mathcal P})$
. -
(b) For any
$\Sigma _1$
-formula
$\varphi =\varphi (x)$
in
${\mathcal L}_{\in ,I_{\textsf {NS}}}$
,
$a\in {\mathcal {H}}(\kappa)$
, and
${\mathbb {P}}\in {\mathcal P}$
, we have
$$ \begin{align*} \,\|\hspace{-.35ex}{\mathsf--}_{\,{\mathbb{P}}\,}{"}\,\varphi(a)\text{"}\ \Leftrightarrow\ \varphi(a). \end{align*} $$
-
(c) For any
${\mathbb {P}}\in {\mathcal P}$
, and
$(\mathsf {V},{\mathbb {P}})$
-generic
${\mathbb {G}}$
, we have
$$ \begin{align*} \langle{\mathcal{H}}(2^{\aleph_0})^{\mathsf{V}},\in,I_{\textsf{NS}}^{\mathsf{V}}\rangle\prec_{\Sigma_1} \langle{\mathcal{H}}(\left(2^{\aleph_1}\right)^{\mathsf{V}[{\mathbb{G}}]})^{\mathsf{V}[{\mathbb{G}}]}, \in,I_{\textsf{NS}}^{\mathsf{V}[{\mathbb{G}}]}\rangle. \end{align*} $$
Proof. The equivalence of (b) and (c) follows from Lemma 1.7.
(a)
$\Rightarrow $
(b): Assume that
$\textsf {BFA}^{+{<}\,\kappa }_{{<}\,\kappa }({\mathcal P})$
holds, and let
${\mathbb {P}}\in {\mathcal P}$
. Without loss of generality, we may assume that
${\mathbb {P}}$
is completely Boolean with
${\mathbb {P}}={\mathbb {B}}\setminus \{{\mathord {\mathbb {0}}}_{\mathbb {B}}\}$
. Suppose
$a\in {\mathcal {H}}(\kappa )$
and
$\varphi $
is a
$\Sigma _1$
-formula in
${\mathcal L}_{\in ,I_{\textsf {NS}}}$
. If
$\varphi (a)$
holds in
$\mathsf {V}$
, then we also have
$\,\|\hspace {-.35ex}\textsf {--}_{\,{\mathbb {P}}\,}{"}\,\varphi (a)\text{"}$
by Lemma 1.5.
Suppose now that
$\varphi =\exists y\,\psi (x,y)$
for a bounded formula
$\psi $
in
${\mathcal L}_{\in ,I_{\textsf {NS}}}$
, and
$\,\|\hspace {-.35ex}\textsf {--}_{\,{\mathbb {P}}\,}{"}\,\varphi (a)\text{"}$
. Without loss of generality, we may assume that
$a\subseteq \mu $
for some cardinal
$\mu <\kappa $
(this is because a can be reconstructed from 
, and 
can be coded by a subset
$a^*$
of 
). The formula
$\varphi (a)$
can be then replaced by another formula saying:
-
$\exists x\,(\,x \text { is the set "}a \text {" reconstructed from the transitive set coded by }a^*\text {and }\varphi (x)\text { holds})$
.
Note that this formula is
$\Sigma _1$
in
${\mathcal L}_{\in ,I_{\textsf {NS}}}$
with the parameter
$a^*$
if
$\varphi $
is
$\Sigma _1$
in
${\mathcal L}_{\in ,I_{\textsf {NS}}}$
.
We may also assume that a is not an ordinal (if necessary, we can replace a with a subset of
$\mu $
with some redundant complexity to make
$a\not \in \text {On}$
).
Let 
be a
${\mathbb {P}}$
-name such that 
. Let
${\mathbb {G}}$
be a
$(\mathsf {V},{\mathbb {P}})$
-generic filter and we work in
$\mathsf {V}[{\mathbb {G}}]$
. Letting 
, we have
$\psi (a,b)$
.
Working further in
$\mathsf {V}[{\mathbb {G}}]$
, let
$\lambda $
be large enough such that
$V_\lambda $
satisfies a large enough fragment of ZFC, a,
$b\in V_\lambda $
, and
$V_\lambda \models \psi (a,b)$
. Let
$M\prec V_\lambda $
be such that
$\mu \subseteq M$
, a,
$b\in M$
, and
$\mathopen {|\,}M\mathclose {\,|}=\mu <\kappa $
. Note that we have
$\langle M,\in , I_{\textsf {NS}}\cap M\rangle \prec \langle V_\lambda ,\in ,I_{\textsf {NS}}\rangle $
since
$I_{\textsf {NS}}$
is definable in
$\langle V_\lambda ,\in \rangle $
. Let
$m:M\stackrel {\cong \hspace {0.8ex}}{\rightarrow }M_0$
be the Mostowski collapse of M and let
$\nu =\text {On}\cap M_0$
. Note that we have
$m\restriction \mu \cup \{a\}\cup (I_{\textsf {NS}}\cap M)=\mathop {id\,}_{\mu \cup \{a\}\cup (I_{\textsf {NS}}\cap M)}$
and hence
$I_{\textsf {NS}}\cap M=I_{\textsf {NS}}\cap M_0$
.
Let
$\mathfrak {M}:=\langle \nu +\mu ,E,I,f,g\rangle $
be the structure in the language 
such that there is an isomorphism
-
(1.6)
$i:\langle M_0, \in , I_{\textsf {NS}}\cap M_0, rank, g_0\rangle \stackrel {\cong \hspace {0.8ex}}{\rightarrow }\langle \nu +\mu , E,I,f,g\rangle $
such that
$i\restriction {\nu }=\mathop {id\,}_{\nu }$
,
$i(a)=\nu $
, and
$i(m(b))=\nu +1,$
where
$rank$
is the rank function restricted to
$M_0$
and
$g_0:M_0\rightarrow M_0$
is a mapping such that
$g_0\restriction \mu $
is an enumeration of 
(
$=( \text {the set of all stationary subsets of } \omega _1)^{M_0}$
) and
$g_0{}^{\,{\prime }{\prime }}{(M_0\setminus \mu )}=\{\emptyset \}$
.
Clearly,
$\langle \nu +\mu ,E, I\rangle \models \psi ^*(\nu ,\nu +1)),$
where
$\psi ^*$
is the formula obtained from
$\psi $
by replacing symbols 
and 
in
$\psi $
by 
and 
.
Note that we have
-
(1.7)
$\langle \nu +\mu , E,I,f,g\rangle \models \forall x\subseteq \omega _1\ (I(x)\lor \exists \alpha <\kappa \,(g(\alpha )=x))$
.
Let 
, 
, 
, 
, 
be
${\mathbb {P}}$
-names of
$\mathfrak {M}$
, E, I, f and
$g,$
respectively. By replacing
${\mathbb {P}}$
with 
for some 
if necessary, we may assume that
-
(1.8) all the properties of
$\langle \nu +\mu , E, I,f,g\rangle $
used below are forced (as a statement on ) by
${\mathord {\mathbb {1}}}_{\mathbb {P}}$
.
) by 
In
$\mathsf {V}$
, let
${\mathcal {D}}$
be the family of dense sets in
${\mathbb {P}}$
generated by the following predense sets in
${\mathbb {P}}$
, each of size
$\leq \mu <\kappa $
. Note that since
${\mathbb {P}}$
is assumed to be completely Boolean, each predense subset of
${\mathcal P}$
can be replaced by a maximal antichain of at most the same size.
-
(1.9)
, and , for all
$\alpha \in \nu +\mu $
. -
(1.10)
, for all
$\Sigma _0$
-formulas
$\theta $
in
${\mathcal L}$
and
$a_0,{} [0]\hspace {0.04ex}{{.}{.}{.}\hspace {0.1ex},\,} [0] a_{k-1}\in \nu +\mu $
. -
(1.11)
, for all
$\Sigma _0$
-formulas
$\eta $
,
$\theta $
in
${\mathcal L}$
and
$a_0,{} [0]\hspace {0.04ex}{{.}{.}{.}\hspace {0.1ex},\,} [0] a_{k-1}\in \nu +\mu $
. -
(1.12)
, for all
$\Sigma _1$
-formulas
$\eta =\eta (x,x_0,{} [0]\hspace {0.04ex}{{.}{.}{.}\hspace {0.1ex},\,} [0] x_{k-1})$
in
${\mathcal L}$
and c,
$a_0,{} [0]\hspace {0.04ex}{{.}{.}{.}\hspace {0.1ex},\,} [0] a_{k-1}\in \nu +\mu $
.
, and 
, for all 
, for all 
, for all 
, for all 
To see that each of the sets in (1.9) is a maximal antichain in
${\mathbb {P}}$
of size
$\leq \mu $
, suppose that
$\alpha \in \nu +\mu $
and 
. Then there is 
which decides 
by (1.8), if follows that 
for some
$\beta \in \nu $
. For the sets corresponding to 
the argument is the same.
It is clear that elements of each of the sets in (1.9) are pairwise incompatible, and these sets are of size
$\leq \mu <\kappa $
.
The sets in (1.11) and (1.12) are not necessarily maximal antichains but it can be proved similarly that each of them sums up to
${\mathord {\mathbb {1}}}_{\mathbb {B}}$
and is of size
$\leq \mu <\kappa $
.
By (1.8), we have that
-
(1.13)
.
. Now, in
$\mathsf {V}$
, let
${\mathbb {G}}$
be
${\mathcal {D}}$
-generic filter such that
-
(1.14)
is a stationary subset of
$\omega _1$
for all
$\alpha <\mu $
.
is a stationary subset of 
${\mathbb {G}}$
exists by
$\textsf {BFA}^{+{<}\,\kappa }_{{<}\,\kappa }({\mathcal P})$
, by (1.13), and since
${\mathcal {D}}$
is a family of dense sets generated by small sets with
$\mathopen {|\,}{\mathcal {D}}\mathclose {\,|}<\kappa $
.
Let
-
.
.where
-
,
-
,
-
, and
-
.
,
,
, and
.Claim 1.8.1
-
(1)
is an
${\mathcal L}$
-structure. -
(2) For each
$\Sigma _1$
-formula
$\theta =\theta (x_0,{} [0]\hspace {0.04ex}{{.}{.}{.}\hspace {0.1ex},\,} [0] x_{k-1})$
in
${\mathcal L}$
and
$a_0,{} [0]\hspace {0.04ex}{{.}{.}{.}\hspace {0.1ex},\,} [0] a_{k-1}\in \nu +\mu $
,
is an 
-
(1.15)
if and only if .
if and only if 
.-
3
is extensional and well-founded. on
$\nu +\mu $
coincides with the canonical ordering on
$\nu +\mu $
.
is extensional and well-founded. 
on 
$\vdash $
(1): Since the maximal antichains in (1.9) are in
${\mathcal {D}}$
, we have 
and 
.
(2): By induction on the construction of the formula
$\theta $
using (1.10), (1.11), and (1.12).
(3): By (1.8), we have 
, and
-
(ℵ1.1)
.
.By (2), it follows that 
is extensional and the statement on the structure 
corresponding to (
$\aleph 1.1$
) holds. A similar argument shows that the canonical ordering on
$\nu $
coincides with 
. This and the property of 
corresponding to (
$\aleph 1.1$
) implies that 
is well-founded.
By Claim 1.8.1, (3), we can take the Mostowski collapse of the structure 
. Since 
by (1.6), (1.8), and Claim 1.8.1, (2), we have
$m^*(\nu )=a$
and hence
$\langle M_2,\in , I^*\rangle \models \psi (a,m^*(\nu +1)),$
where the predicate
$I_{\textsf {NS}}$
is interpreted as
$I^*$
. Thus
$\langle M_2,\in , I^*\rangle \models \varphi (a)$
. By (1.7), (1.8), (1.14), and Claim 1.8.1, (2), we have
$I^*=I_{\textsf {NS}}\cap M_2$
.
Since
$\varphi $
is
$\Sigma _1$
, it follows that
$V\models \varphi (a)$
by Lemma 1.5, (2).
(b)
$\Rightarrow $
(a): Assume that (b) holds, and suppose that
${\mathbb {P}}\in {\mathcal P}$
is complete Boolean,
${\mathcal {D}}$
is a set of maximal antichains each of size
$<\kappa $
with
$\mathopen {|\,}{\mathcal {D}}\mathclose {\,|}<\kappa $
, and
${\mathcal S}$
is a set of
${\mathbb {P}}$
-names of stationary subsets of
$\omega _1$
with
$\mathopen {|\,}{\mathcal S}\mathclose {\,|}<\kappa $
.
By replacing elements of
${\mathcal S}$
by equivalent
${\mathbb {P}}$
-names which are sufficiently nice, we may assume that each element of
${\mathcal S}$
is nice
${\mathbb {P}}$
-name of size
$\aleph _1$
(this is possible since we assumed that
${\mathbb {P}}$
is completely Boolean).
Let
$X=\bigcup {\mathcal {D}}$
then
$\mathopen {|\,}X\mathclose {\,|}<\kappa $
. Let
$\mu :=\max \{\mathopen {|\,}X\mathclose {\,|},\mathopen {|\,}{\mathcal S}\mathclose {\,|}\}$
. Let
$\lambda $
be sufficiently large with
$V_\lambda \prec _{\Sigma _n}\mathsf {V}$
for sufficiently large n. Let
$M\prec V_\lambda $
be such that
$\mathopen {|\,}M\mathclose {\,|}=\mu $
, (1.16)
${\mathbb {P}}$
,
${\mathcal {D}}$
, X,
${\mathcal S}\in M$
, and
$\mu +1\subseteq M$
. Note that (1.16) implies
${\mathcal {D}},{\mathcal S}\subseteq M$
and 
.
Let
$m:M\stackrel {\cong \hspace {0.8ex}}{\rightarrow }M_0$
be the Mostowski collapse and
$\langle {\mathbb {P}}_0,\leq _{{\mathbb {P}}_0}\rangle :=m(\langle {\mathbb {P}},\leq _{\mathbb {P}}\rangle )$
. Let 
.
Since
$(\mathsf {V},{\mathbb {P}})$
-generic filter
${\mathbb {G}}$
generates an
$(M_0,{\mathbb {P}}_0)$
-generic filter, we have
-
$\,\|\hspace {-.35ex}{\mathsf {-}}_{\,{\mathbb {P}}\,}{"}\, \begin {array}[t]{@{}l} \text {there is a }(M_0,{\mathbb {P}}_0)\text {-generic filter which realizes each element of }{\mathcal S}_0\\ \text { to be a stationary subset of }\omega _1\text{"}. \end {array} $
By the assumption (b), it follows that
-
$\mathsf {V}\models \!{"\,} \begin {array}[t]{@{}l} \text {there is a }(M_0,{\mathbb {P}}_0)\text {-generic filter which realizes each element of }{\mathcal S}_0\\ \text { to be a stationary subset of }\omega _1\text{"}. \end {array} $
Let
${\mathbb {G}}_0$
be such a filter. Then
$m^{-1}{}^{\,{\prime }{\prime }}{{\mathbb {G}}_0}$
generates a
${\mathcal {D}}$
-generic filter
${\mathbb {G}}_1$
on
${\mathbb {P}}$
which realizes each element of
${\mathcal S}$
to be a stationary subset of
$\omega _1$
.
2. Recurrence Axioms and the Ground Axiom (GA)
2.1. Hierarchies of Recurrence and Maximality
The term “Recurrence Axiom” was coined in Fuchino and Usuba [Reference Fuchino and Usuba15] (see also Fuchino [Reference Fuchino11]). The Recurrence Axiom for a (normal) class
${\mathcal P}$
of posets, a set A of parameters, and a set
$\Gamma $
of
${{\mathcal L}}_{\in }$
-formulas (
$({\mathcal P},A)_\Gamma $
-RcA, for short) is the statement (2.1) below.
A ground of a (transitive set or class) model
$\mathsf {W}$
(of some set theory) is an inner model
$\mathsf {W}_0$
of
$\mathsf {W}$
such that there is a poset
${\mathbb {P}}\in \mathsf {W}_0$
such that
$\mathsf {W}$
is a
${\mathbb {P}}$
-generic extension of
$\mathsf {W}_0$
. For a class
${\mathcal P}$
of posets, a ground
$\mathsf {W}_0$
of
$\mathsf {W}$
is a
${\mathcal P}$
-ground of
$\mathsf {W}$
if there is a poset
${\mathbb {P}}\in \mathsf {W}_0$
such that
$\mathsf {W}_0\models \!{"\,}{\mathbb {P}}\in {\mathcal P}\,\text{"}$
and
$\mathsf {W}$
is a
${\mathbb {P}}$
-generic extension of
$\mathsf {W}_0$
.
The Recurrence Axiom
$({\mathcal P},A)_\Gamma $
-RcA is the following statement formulated in an axiom scheme in
${{\mathcal L}}_{\in }$
(that this axiom is not formalizable in a single formula is discussed in [Reference Fuchino12]).
-
(2.1) For any
${\mathbb {P}}\in {\mathcal P}$
,
$\varphi (\overline {x})\in \Gamma $
, and
$\overline {a}\in A$
, if
$\,\|\hspace {-.35ex}\textsf {--}_{\,{\mathbb {P}}\,}{"}\,\varphi (\overline {a}^{\checkmark })\text{"}$
, then there is a ground
$\mathsf {W}$
of
$\mathsf {V}$
such that
$\overline {a}\in \mathsf {W}$
and
$\mathsf {W}\models \varphi (\overline {a})$
.
The definition of a stronger variant
$({\mathcal P},A)_\Gamma $
-RcA
$^+$
of
$({\mathcal P},A)_\Gamma $
-RcA is obtained when we replace “ground” in (2.1) by “
${\mathcal P}$
-ground”. If
$\Gamma ={{\mathcal L}}_{\in }$
, we simply drop
$\Gamma $
and talk about
$({\mathcal P},A)$
-RcA(
$^+$
).
For definability of these axioms in the language of ZFC, see the paragraphs around Lemma 3.5.
As we have already followed these conventions without explanations, we often identify check names of sets with the sets themselves and drop the symbol “
$^{\checkmark }$
”. Also we shall often replace tuples
$\overline {a}$
of parameters by a single parameter a for simplicity (actually without loss of generality in most of the cases).
Recurrence Axioms are almost identical with Maximality Principles introduced in [Reference Hamkins20] with the same parameters. For
${\mathcal P}$
, A as above, the Maximality Principle for
${\mathcal P}$
and A (
$\textsf {MP}({\mathcal P},A)$
for short) is defined as below.
For a class
${\mathcal P}$
of posets, an
${{\mathcal L}}_{\in }$
-formula
$\varphi (\overline {a})$
with parameters
$\overline {a}$
(
$\in \mathsf {V}$
) is said to be a
${\mathcal P}$
-button if there is
${\mathbb {P}}\in {\mathcal P}$
such that for any
${\mathbb {P}}$
-name 
of poset with 
, we have 
.
If
$\varphi (\overline {a})$
is a
${\mathcal P}$
-button then we call
${\mathbb {P}}$
as above a push of the
${\mathcal P}$
-button
$\varphi (\overline {a})$
.
For a class
${\mathcal P}$
of posets and a set A (of parameters), the Maximality Principle for
${\mathcal P}$
and A (
$\textsf {MP}({\mathcal P},A)$
, for short) is the following assertion which is formulated as an axiom scheme in
${{\mathcal L}}_{\in }$
.
-
MP(𝒫, A): For any
${{\mathcal L}}_{\in }$
-formula
$\varphi (\overline {x})$
and
$\overline {a}\in A$
, if
$\varphi (\overline {a})$
is a
${\mathcal P}$
-button then
$\varphi (\overline {a})$
holds.
Similarly to the restricted versions of Recurrence Axiom, we define, for a set
$\Gamma $
of
${{\mathcal L}}_{\in }$
-formulas.
-
MP(𝒫, A)Γ: For any
$\varphi (\overline {x})\in \Gamma $
and
$\overline {a}\in A$
, if
$\varphi (\overline {a})$
is a
${\mathcal P}$
-button then
$\varphi (\overline {a})$
holds.
Proposition 2.1 (Barton et al. [Reference Barton, Caicedo, Fuchs, Hamkins, Reitz and Schindler6], see also Proposition 2.2 in [Reference Fuchino and Usuba15]).
Suppose that
${\mathcal P}$
is a class of posets and A a set (of parameters).
-
(1)
$({\mathcal P}, A)$
-RcA
$^+$
is equivalent to
$\textsf {MP}({\mathcal P},A)$
. -
(2)
$({\mathcal P}, A)$
-RcA is equivalent to the following assertion:
-
(2.2) For any
${{\mathcal L}}_{\in }$
-formula
$\varphi (\overline {x})$
and
$\overline {a}\in A$
, if
$\varphi (\overline {a})$
is a
${\mathcal P}$
-button then
$\varphi (\overline {a})$
holds in a ground of
$\mathsf {V}$
.
See Lemma 3.4 in Section 3 below and its proof.
Recurrence Axiom (
$\Leftrightarrow $
Maximality Principle) can be also characterized as the ZFC version of Sy-David Friedman’s Inner Model Hypothesis [Reference Friedman9] (see Barton et al [Reference Barton, Caicedo, Fuchs, Hamkins, Reitz and Schindler6], see also Fuchino and Usuba [Reference Fuchino and Usuba15] or Fuchino [Reference Fuchino11]).
In contrast to the proposition above,
$({\mathcal P}, A)_\Gamma $
-RcA
$^+$
is not necessarily equivalent to
$\textsf {MP}({\mathcal P}, A)_\Gamma $
for some set
$\Gamma $
of formulas. In the next section, we prove that (under the consistency of certain large cardinal axioms)
$\textsf {MP}({\mathcal P},A)_{\Sigma _2}$
does not imply
$({\mathcal P},A)_{\Sigma _2}$
-RcA and
$\textsf {MP}({\mathcal P},A)_{\Pi _2}$
does not imply
$({\mathcal P},A)_{\Pi _2}$
-RcA (see Corollary 3.12).
Later we shall also consider a restricted form of (2.2) which we will call
$\textsf {MP}^-({\mathcal P},A)_\Gamma $
.
-
MP −(𝒫, A)Γ: For any
$\varphi (\overline {x})\in \Gamma $
and
$\overline {a}\in A$
, if
$\varphi (\overline {a})$
is a
${\mathcal P}$
-button then
$\varphi (\overline {a})$
holds in a ground of
$\mathsf {V}$
.
Writing
$\textsf {MP}^-({\mathcal P},A)$
for
$\textsf {MP}^-({\mathcal P},A)_{{{\mathcal L}}_{\in }}$
, the assertion of Proposition 2.1, (2) is reformulated as
$({\mathcal P},A)$
-RcA
$\Leftrightarrow $
$\textsf {MP}^-({\mathcal P},A)$
.
While Recurrence Axioms are assertions about the richness of the grounds of the universe
$\mathsf {V}$
, their characterizations as Maximality Principles may be seen as a variation of generic absoluteness.
The following is an immediate consequence of Bagaria’s Absoluteness Theorem 1.2.
Theorem 2.2 (Ikegami and Trang (reformulated for our hierarchy of restricted Recurrence Axioms) [Reference Ikegami and Trang22]).
For a
$($
normal
$)$
class
${\mathcal P}$
of posets and a cardinal
$\kappa $
, the following are equivalent:
-
(a)
$({\mathcal P},{\mathcal {H}}(\kappa ))_{\Sigma _1}$
-RcA
$^+$
. -
(b)
$({\mathcal P},{\mathcal {H}}(\kappa ))_{\Sigma _1}$
-RcA. -
(c)
$\textsf {BFA}_{{<}\,\kappa }({\mathcal P})$
.
Proof. (a)
$\Rightarrow $
(b): is trivial.
(b)
$\Rightarrow $
(c): Assume that
$({\mathcal P},{\mathcal {H}}(\kappa ))_{\Sigma _1}$
-RcA holds, and suppose that
${\mathbb {P}}\in {\mathcal P}$
,
$\varphi $
is a
$\Sigma _1$
-formula in
${{\mathcal L}}_{\in }$
and
$a\in {\mathcal {H}}(\kappa )$
. By Bagaria’s Absoluteness Theorem 1.2, it is enough to show that
$\,\|\hspace {-.35ex}\textsf {--}_{\,{\mathbb {P}}\,}{"}\,\varphi (a)\text{"} \Leftrightarrow \varphi (a)$
holds.
$\,\|\hspace {-.35ex}\textsf {--}_{\,{\mathbb {P}}\,}{"}\,\varphi (a)\text{"} \Leftarrow \varphi (a)$
: is clear since
$\varphi $
is
$\Sigma _1$
.
$\,\|\hspace {-.35ex}\textsf {--}_{\,{\mathbb {P}}\,}{"}\,\varphi (a)\text{"} \Rightarrow \varphi (a)$
: Assume that
$\,\|\hspace {-.35ex}\textsf {--}_{\,{\mathbb {P}}\,}{"}\,\varphi (a)\text{"}$
. By
$({\mathcal P},{\mathcal {H}}(\kappa ))_{\Sigma _1}$
-RcA, there is a ground
$\mathsf {W}$
of
$\mathsf {V}$
such that
$a\in \mathsf {W}$
and
$\mathsf {W}\models \varphi (a)$
. Since
$\varphi $
is
$\Sigma _1$
it follows that
$\mathsf {V}\models \varphi (a)$
.
(c)
$\Rightarrow $
(a): Assume that
$\textsf {BFA}_{{<}\,\kappa }({\mathcal P})$
holds. Suppose that
$\,\|\hspace {-.35ex}\textsf {--}_{\,{\mathbb {P}}\,}{"}\,\varphi (a)\text{"}$
for
${\mathbb {P}}$
,
$\varphi $
, a as above. Then, by Bagaria’s Absoluteness Theorem 1.2, we have
$\varphi (a)$
. In particular, since
$\{{\mathord {\mathbb {1}}}\}\in {\mathcal P}$
(remember the convention set at (1.1)),
$\varphi (a)$
holds in a
${\mathcal P}$
-ground of
$\mathsf {V}$
(namely,
$\mathsf {V}$
itself).
According to Joel Hamkins [Reference Hamkins20] it is an observation of his former PhD student George Leibman that MA follows from Maximality Principle for
${\mathcal P}=$
ccc posets, and the set of parameters
${\mathcal {H}}(2^{\aleph _0})$
. Actually the corresponding statement had been proved much earlier by Stavi and Väänänen [Reference Stavi and Väänänen30] (see also the introduction of [Reference Stavi and Väänänen30]). This observation is now a part of Theorem 2.2, since MA is equivalent to
$\textsf {BFA}_{{<}\,2^{\aleph _0}}({\mathcal P})$
for this
${\mathcal P}$
.
Strictly speaking, Theorem 2.2 is different from the original theorem in Ikegami–Trang [Reference Ikegami and Trang22] (Theorem 1.13 there) in that Ikegami and Trang are talking about the
$\Sigma _n$
,
$\Pi _n$
-hierarchy
$\textsf {MP}(\cdots )_\Gamma $
for
$\Gamma =\Sigma _n$
,
$\Pi _n$
etc., which is shown to be different from
$(\cdots )_{\Gamma }$
-RcA
$^+$
hierarchy (see Corollary 3.12 and the remark before the corollary). The proof above together with the proof of Theorem 1.13 in [Reference Ikegami and Trang22] actually shows that for a normal class of posets,
$({\mathcal P},{\mathcal {H}}(\aleph _2))_{\Sigma _1}$
-RcA
$^+$
coincides with
$\textsf {MP}({\mathcal P},{\mathcal {H}}(\aleph _2))_{\Sigma _1}$
(see Theorem 3.1 and Corollary 3.2).
$({\mathcal P},{\mathcal {H}}(\aleph _2))_{\Gamma }$
-RcA
$^+$
and
$\textsf {MP}({\mathcal P},{\mathcal {H}}(\aleph _2))_{\Gamma }$
in general can be different principles. We will address to this subtle difference in the next Section 3, and show that these two hierarchies can split up drastically on the
$\Pi _2$
and
$\Sigma _2$
levels (see Corollary 3.12).
2.2. (In)compatibility of Recurrence and Maximality with GA
The GA is the axiom asserting that there is no proper ground of the universe
$\mathsf {V}$
. The axiom is introduced by Joel Hamkins and Jonas Reitz. Its basic properties including the formalizability of the axiom in
${{\mathcal L}}_{\in }$
are proved in Reitz [Reference Reitz28].
The relative consistency of GA with PFA is proved in [Reference Reitz28] (see also the proof of Theorem 3.8 below; actually GA is even consistent with
$\textsf {MM}^{++}$
, see Theorem 6.3). In particular, this and Ikegami–Trang Theorem 2.2 imply the following.
Theorem 2.3.
GA is relatively consistent with
$({\mathcal P},{\mathcal {H}}(\aleph _2))_{\Sigma _1}$
-RcA
$^+$
for a class of posets
${\mathcal P}$
whose elements are proper.
Since the Recurrence Axiom implies that there are “many” different grounds, it is clear that Proposition 2.3 cannot be generalized for
$(\cdots )_\Gamma $
-RcA for arbitrary
$\Gamma $
. In particular, since GA itself is formalizable in a
$\Pi _3$
-sentence in
${{\mathcal L}}_{\in }$
(see the remark after Lemma 3.4), and it is not true in any non-trivial generic extension of the ground model, we obtain the following.
Theorem 2.4. Suppose
$({\mathcal P},\emptyset )_{\Sigma _3}$
-RcA holds for a non-trivial class
${\mathcal P}$
of posets. Then GA does not hold.
$\textsf {MP}^-({\mathcal P},\emptyset )_{\Sigma _3}$
for a non-trivial
${\mathcal P}$
also implies
$\neg \textsf {GA}$
.
Proof. Assume toward a contradiction that
$({\mathcal P},\emptyset )_{\Sigma _3}$
-RcA holds for a non-trivial class
${\mathcal P}$
of posets, and GA also holds. Let
$\psi $
be the
$\Pi _3$
-sentence expressing that the universe does not have a non-trivial ground. Let
${\mathbb {P}}\in {\mathcal P}$
be non-trivial forcing. Then
$\,\|\hspace {-.35ex}\textsf {--}_{\,{\mathbb {P}}\,}{"}\,\neg \psi \text{"}$
. Since
$\neg \psi $
is a
$\Sigma _3$
-sentence,
$({\mathcal P},\emptyset )_{\Sigma _3}$
-RcA implies that there is a ground
$\mathsf {W}$
of
$\mathsf {V}$
such that
$\mathsf {W}\models \neg \psi $
. Since we also assumed GA,
$\mathsf {W}$
must be identical with
$\mathsf {V}$
. Thus
$\mathsf {V}\models \neg \psi $
. This is a contradiction.
Since
$\psi $
above is a
${\mathcal P}$
-button, the same proof leads to a contradiction under
$\textsf {MP}^-({\mathcal P},\emptyset )_{\Sigma _3}$
.
Actually we also have the following delimitation, which shows that Theorem 2.3 is optimal in many instances of
${\mathcal P}$
.
In the following, we use a variant of the cardinal invariant
${\mathfrak b}^*$
introduced in Eda et al. [Reference Eda, Kada and Yuasa8]:
Lemma 2.5.
-
(1)
${\mathfrak b}=\aleph _1$
can be formulated as a
$\Sigma _2$
-sentence
$\varphi $
in
${{\mathcal L}}_{\in }$
. -
(2)
${\mathfrak b}^{**}=\aleph _1$
can be formulated as a
$\Pi _2$
-sentence
$\psi $
in
${{\mathcal L}}_{\in }$
. -
(3)
${\mathfrak b}<{\mathfrak d}$
can be formulated as a
$\Pi _2$
-sentence
$\eta $
in
${{\mathcal L}}_{\in }$
.
Proof. (1): The following formula
$\varphi $
will do:
-
$\exists B\ \exists R\ \exists F\ (\, \begin {array}[t]{@{}l} B\subseteq {}^{{\omega }\hspace {-0.02em}}\omega \land \ \text {"}R\text { is an }\omega _1\text {-like linear ordering on }B\text { which is}\\ \text {witnessed by }F\,\text {"}\ \land \ \forall f\,(f\in {}^{{\omega }\hspace {-0.02em}}\omega \ \rightarrow \ (\exists g\in B)\,(g\not <^* f)))\,. \end {array}$
(2): The following formula
$\psi $
will do:
(3): “
${\mathfrak b}={\mathfrak d}$
” is characterized by the existence of a bounding family
$\subseteq {}^{{\omega }\hspace {-0.02em}}\omega $
which is well ordered with respect to
$\leq ^*$
. Similarly to above, this can be formulated by a
$\Sigma _2$
-sentence. Hence, the negation of the equality (
$\Leftrightarrow {\mathfrak b}<{\mathfrak d}$
) is
$\Pi _2$
in
${{\mathcal L}}_{\in }$
.
Lemma 2.6.
${\mathfrak b}\leq {\mathfrak b}^{**}\leq {\mathfrak d}$
.
Proof. Let
$\langle f_\alpha \,:\,\alpha <{\mathfrak b}\rangle $
be such that
$f_\alpha \leq ^*f_{\alpha '}$
for all
$\alpha <\alpha '<{\mathfrak b}$
, and
$\{f_\alpha \,:\,\alpha <{\mathfrak b}\}$
is unbounded in
${}^{{\omega }\hspace {-0.02em}}\omega $
(this can be done by letting
$\{g_\alpha \,:\,\alpha <{\mathfrak b}\}$
be an unbounded subset of
${}^{{\omega }\hspace {-0.02em}}\omega $
, and defining
$f_\alpha $
,
$\alpha <{\mathfrak b}$
inductively such that we have
$g_\alpha \leq ^* f_\alpha $
for all
$\alpha <{\mathfrak b}$
). Let
$B=\{f_\alpha \,:\,\alpha <{\mathfrak b}\}$
. Then no
$B'\subseteq B$
with
$\mathopen {|\,}B'\mathclose {\,|}<\mathopen {|\,}B\mathclose {\,|}={\mathfrak b}$
is unbounded in
${\mathcal B}$
.
Note that the sequence
$\langle f_\alpha \,:\,\alpha <{\mathfrak b}\rangle $
as above also shows that
${\mathfrak b}$
is a regular cardinal.
This proves that
${\mathfrak b}\leq {\mathfrak b}^{**}$
.
To show that
${\mathfrak b}^{**}\leq {\mathfrak d}$
, suppose that
$D\subseteq {}^{{\omega }\hspace {-0.02em}}\omega $
is dominating in
${}^{{\omega }\hspace {-0.02em}}\omega $
(with respect to
$\leq ^*$
), and
$\mathopen {|\,}D\mathclose {\,|}={\mathfrak d}$
.
For any unbounded
$B\subseteq {}^{{\omega }\hspace {-0.02em}}\omega $
, and for each
$d\in D$
let
$b_d\in B$
be such that
$b_d\not \leq ^* d$
. Then
$B'=\{b_d\,:\,d\in D\}\subseteq B$
is unbounded in
${}^{{\omega }\hspace {-0.02em}}\omega $
and hence also unbounded in B and is of cardinality
$\leq {\mathfrak d}$
. This shows that
${\mathfrak b}^{**}\leq {\mathfrak d}$
.
In the following, we denote with
${\mathbb {C}}_\kappa $
the finite support
$\kappa $
-product of Cohen forcing, and with
${\mathbb {D}}$
the finite support iteration of Hechler forcing of length
$\omega _1$
. It is easy to see that (over an arbitrary ground model
$\mathsf {V}$
) we have
$\,\|\hspace {-.35ex}\textsf {--}_{\,{\mathbb {C}}_\kappa \,}{"}\,{\mathfrak b}=\aleph _1, {\mathfrak d}\geq \kappa \text{"}$
for any regular
$\kappa \geq \aleph _1$
, and
$\,\|\hspace {-.35ex}\textsf {--}_{\,{\mathbb {D}}\,}{"}\,{\mathfrak d}=\aleph _1\text{"}$
. More generally, letting
${\mathbb {D}}_\kappa $
be the FS-iteration of Hechler forcing of length
$\kappa $
for regular
$\kappa $
, we have
$\,\|\hspace {-.35ex}\textsf {--}_{\,{\mathbb {D}}_\kappa \,}{"}\,{\mathfrak b}={\mathfrak d}=\kappa \text{"}$
.
Proposition 2.7. Suppose
${\mathcal P}$
is a class of posets with
${\mathbb {D}}\in {\mathcal P}$
and (2.3)
${\mathfrak b}>\aleph _1$
holds.
-
(1) If
$({\mathcal P},\emptyset )_{\Sigma _2}$
-RcA holds, then GA does not hold. -
(2) If
$({\mathcal P},\emptyset )_{\Pi _2}$
-RcA holds, then GA does not hold.
Proof. Suppose that
${\mathcal P}$
is as above, and (2.3) holds.
(1): Suppose that
$({\mathcal P},\emptyset )_{\Sigma _2}$
-RcA and GA hold.
Since we have
$\,\|\hspace {-.35ex}\textsf {--}_{\,{\mathbb {D}}\,}{"}\,{\mathfrak b}=\aleph _1\text{"}$
, and since “
${\mathfrak b}=\aleph _1$
” is expressible in a
$\Sigma _2$
-sentence in
${{\mathcal L}}_{\in }$
by Lemma 2.5, (1), it follows by
$({\mathcal P},\emptyset )_{\Sigma _2}$
-RcA, that there is a ground
$\mathsf {W}_0$
with
$\mathsf {W}_0\models \!{"\,}{\mathfrak b}=\aleph _1\text{"}$
. Since
$\mathsf {V}=\mathsf {W}_0$
by GA, this is a contradiction to (2.3).
(2): Suppose that
$({\mathcal P},\emptyset )_{\Pi _2}$
-RcA and GA hold.
Note that by (2.3) and Lemma 2.6, we have (2.4)
$\mathsf {V}\models {\mathfrak b}^{**}>\aleph _1$
.
Since we have
$\,\|\hspace {-.35ex}{\mathsf {--}}_{\,{\mathbb {D}}\,}{"}\,{\mathfrak d}=\aleph _1\text{"}$
, we have
$\,\|\hspace {-.35ex}\textsf {--}_{\,{\mathbb {D}}\,}{"}\,{\mathfrak b}^{**}=\aleph _1\text{"}$
by Lemma 2.6. Since “
${\mathfrak b}^{**}=\aleph _1$
” is expressible in a
$\Pi _2$
-sentence in
${{\mathcal L}}_{\in }$
by Lemma 2.5, (2), it follows by
$({\mathcal P},\emptyset )_{\Pi _2}$
-RcA, that there is a ground
$\mathsf {W}_0$
with
$\mathsf {W}_0\models \!{"\,}{\mathfrak b}^{**}=\aleph _1\text{"}$
. Since
$\mathsf {V}=\mathsf {W}_0$
by GA, it follows that
$\mathsf {V}\models \!{"\,}{\mathfrak b}^{**}=\aleph _1\text{"}$
. This is a contradiction to (2.4).
The following can be proved similarly to Proposition 2.7, (1).
Proposition 2.8. Suppose that
${\mathcal P}$
is a class of posets with
${\mathbb {C}}_{\aleph _1}\in {\mathcal P}$
and
${\mathfrak b}\geq \aleph _2$
holds. Then
$({\mathcal P},\emptyset )_{\Sigma _2}$
-RcA implies that
$\textsf {GA}$
does not hold.
Lemma 2.9.
CH can be formulated both as
$\Sigma _2$
-sentence and
$\Pi _2$
-sentence in
${{\mathcal L}}_{\in }$
without parameters.
Proposition 2.10.
-
(1) Suppose that
$\neg \textsf {CH}$
holds and
${\mathcal P}$
contains a poset collapsing
$2^{\aleph _0}$
to
$\aleph _1$
without adding reals. Then each of
$({\mathcal P},\emptyset )_{\Sigma _2}$
-RcA and
$({\mathcal P},\emptyset )_{\Pi _2}$
-RcA implies
$\neg \textsf {GA}$
. -
(2) Suppose that
$\textsf {CH}$
holds and
${\mathcal P}$
contains a poset
${\mathbb {Q}}$
adding
${\geq }\,\aleph _2$
reals without collapsing cardinals
${\leq }\,\aleph _2$
. Then each of
$({\mathcal P},\emptyset )_{\Sigma _2}$
-RcA and
$({\mathcal P},\emptyset )_{\Pi _2}$
-RcA implies
$\neg \textsf {GA}$
. -
(3) Suppose that
${\mathcal P}$
contains sufficiently many ccc posets (containing enough CS-iterations of Cohen and Hechler posets would suffice), then each of
$({\mathcal P},\emptyset )_{\Sigma _2}$
-RcA and
$({\mathcal P},\emptyset )_{\Pi _2}$
-RcA implies
$\neg \textsf {GA}$
.
2.3. Incompatibility of Laver genericity with GA
In the following we want to discuss the impact of the results we obtained above on axioms stating that there is a Laver-generic large cardinal (Laver-gen. large cardinal axioms).
The strongest variant of Laver-generic large cardinal axiom which has been considered so far, is the tightly super-
$C^{(\infty )} {\mathcal P}$
-Laver-generically hyperhuge cardinal (see Fuchino and Usuba [Reference Fuchino and Usuba15]).
Here, a cardinal
$\kappa $
is said to be (tightly, resp.) super-
$C^{(\infty )} {\mathcal P}$
-Laver-generically hyperhuge if for all
$n\in {{\mathbb {N}}}$
and for any
$\lambda _0>\kappa $
and
${\mathbb {P}}\in {\mathcal P}$
, there are
$\lambda \geq \lambda _0$
with
$V_\lambda \prec _{\Sigma _n}\mathsf {V}$
, and
${\mathbb {P}}$
-name 
with 
such that for 
-generic
$\mathbb {H}$
, there are j,
$M\subseteq \mathsf {V}[\mathbb {H}]$
with
$j:\mathsf {V}\stackrel {\prec \hspace {0.8ex}}{\rightarrow }_{\kappa }M$
,
$j(\kappa )>\lambda $
,
$j{}^{\,{\prime }{\prime }}{j(\lambda )}$
, 
,
${V_{j(\lambda )}}^{\mathsf {V}[\mathbb {H}]}\prec _{\Sigma _n}\mathsf {V}[\mathbb {H}]$
(and 
is of size
$\leq j(\kappa )$
, resp.).Footnote
5
We can also define (tightly) super-
$C^{(\infty )} {\mathcal P}$
-Laver gen. large cardinal analogously for notions of large cardinal other than hyperhugeness (see [Reference Fuchino and Usuba15] or [Reference Fuchino11]). For an iterable class
${\mathcal P}$
of posets which also permits transfinite iteration with some suitable support, we can prove that the existence of the tightly super-
$C^{(\infty )} {\mathcal P}$
-Laver gen. hyperhuge cardinal is consistent under a 2-huge cardinal [Reference Fuchino and Usuba15].
Note that we cannot formulate the (genuine) large cardinal property corresponding to (tightly) super-
$C^{(\infty )} {\mathcal P}$
-Laver-generically large cardinal in
${{\mathcal L}}_{\in }$
. However, for a natural class
${\mathcal P}$
of posets like proper posets, semiproper posets, ccc posets, etc. we can formulate the notion of (tightly) super-
$C^{(\infty )} {\mathcal P}$
-Laver-generically hyperhugeness in an axiom scheme in
${{\mathcal L}}_{\in }$
. This is because
${\mathcal P}$
-Laver-generically hyperhugeness of a cardinal
$\kappa $
implies
$\kappa =\kappa _{\mathfrak {r}\mathfrak {e}\mathfrak {f}\mathfrak {l}\,}$
(
$:=\max \{\aleph _2,2^{\aleph _0}\}$
) for these classes
${\mathcal P}$
of posets, and hence we can formulate the (tightly) super-
$C^{(\infty )} {\mathcal P}$
-Laver-generically hyperhugeness of such
$\kappa $
in infinitely many formulas without introducing a new constant symbol for the cardinal.
In Fuchino and Usuba [Reference Fuchino and Usuba15], it is proved that if
$\kappa $
is tightly super-
$C^{(\infty )} {\mathcal P}$
-Laver-generically ultrahuge, then
$({\mathcal P},{\mathcal {H}}(\kappa ))$
-RcA
$^+$
holds. Here the tightly super-
$C^{(\infty )} {\mathcal P}$
-Laver-generically ultrahugeness is apparently much weaker than tightly super-
$C^{(\infty )} {\mathcal P}$
-Laver-generically hyperhugeness.
Note that
$({\mathcal P},{\mathcal {H}}(\kappa ))$
-RcA
$^+$
is also an assertion formalizable only in infinitely many formulas. In contrast, it is proved in [Reference Fuchino12], that, in a sense, Laver-genericity without “super-
$C^{(\infty )}$
” details never implies the full
$({\mathcal P},{\mathcal {H}}(\kappa ))$
-RcA
$^+$
.
By the result mentioned above and by Theorem 2.4, it follows immediately that:
Proposition 2.11. For any iterable class
${\mathcal P}$
of posets, if
$\kappa $
is tightly super-
$C^{(\infty )} {\mathcal P}$
-Laver-generically ultrahuge, then
$\textsf {GA}$
does not hold.
In [Reference Fuchino and Usuba15], it is proved that if
$\kappa $
is tightly
${\mathcal P}$
-generically hyperhuge (not necessarily Laver-generic) then there is the bedrock (i.e., the ground satisfying GA) and
$\kappa $
is hyperhuge in the bedrock.
On the other hand, it is shown in [Reference Fuchino11] that a tightly
${\mathcal P}$
-Laver-generically ultrahuge cardinal for nice iterable
${\mathcal P}$
is
$\leq \kappa _{\mathfrak {r}\mathfrak {e}\mathfrak {f}\mathfrak {l}\,}$
. Here an iterable class
${\mathcal P}$
of posets is said to be nice if the following is provable in ZFC: either
${\mathcal P}$
preserves
$\omega _1$
and
$\text {Col}(\omega _1,\{\omega _2\})\in {\mathcal P}$
, or
${\mathcal P}$
contains a poset which adds a new real. Actually the following lemma is one of the main rationales of the definition of the cardinal
$\kappa _{\mathfrak {r}\mathfrak {e}\mathfrak {f}\mathfrak {l}\,}$
.
Lemma 2.12. Suppose that
${\mathcal P}$
is a nice iterable class of posets. If
$\kappa $
is
${\mathcal P}$
-Laver-gen. supercompact, then
$\kappa \leq \kappa _{\mathfrak {r}\mathfrak {e}\mathfrak {f}\mathfrak {l}\,}$
.
Proof. By Lemma 6., (2) and (3) in [Reference Fuchino11].
Thus we obtain the following.
Proposition 2.13. For a nice iterable class
${\mathcal P}$
of posets, suppose that there is a tightly
${\mathcal P}$
-Laver-generically hyperhuge cardinal. Then the bedrock exists and it is different from
$\mathsf {V}$
. In particular, GA does not hold.
Proof. By Lemma 2.12, the tightly
${\mathcal P}$
-Laver-generically hyperhuge cardinal is
$\leq \kappa _{\mathfrak {r}\mathfrak {e}\mathfrak {f}\mathfrak {l}\,}$
(in
$\mathsf {V}$
) while
$\kappa $
is hyperhuge in the bedrock
$\overline {\mathsf {W}}$
. This implies that
$\mathsf {V}\not =\overline {\mathsf {W}}$
. In particular, GA does not hold.
At the moment we do not know if the existence of a tightly
${\mathcal P}$
-generically hyperhuge in theorem in [Reference Fuchino and Usuba15] mentioned above can be weakened to the existence of some tight generic large cardinal of lower consistency strength. However, in [Reference Fuchino11], it is proved that for an iterable class
${\mathcal P}$
of posets, if
$\kappa $
is tightly
${\mathcal P}$
-Laver-gen. ultrahuge then
$({\mathcal P},{\mathcal {H}}(\kappa ))_{\Sigma _2}$
-RcA
$^+$
holds ([Reference Fuchino11, Theorem 21]). Note that ultrahuge cardinal is apparently much weaker than hyperhuge cardinal.
Theorem 2.14. Suppose that
${\mathcal P}$
is an iterable class of posets satisfying one of the conditions in Proposition 2.10.
If
$\kappa _{\mathfrak {r}\mathfrak {e}\mathfrak {f}\mathfrak {l}\,}$
is tightly
${\mathcal P}$
-Laver-gen. ultrahuge then GA does not hold.
Proof. If
$\kappa $
is tightly
${\mathcal P}$
-Laver-gen. ultrahuge then
$({\mathcal P},{\mathcal {H}}(\kappa ))_{\Sigma _2}$
-RcA
$^+$
holds by Theorem 21 in [Reference Fuchino11]. Thus if
${\mathbb {D}}\in {\mathcal P}$
then (by Proposition 5.5 below and) by Proposition 2.7,(1), it follows that GA does not hold.
Other cases can treated similarly by applying other assertions of Proposition 2.10.
3. Hierarchies of restricted Recurrence Axioms and Maximality Principles
The proof of Theorem 2.2 can be reused almost without any change to prove the following generalization of Theorem 1.13 in Ikegami–Trang [Reference Ikegami and Trang22].
Theorem 3.1 (Generalization of the original Ikegami–Trang Theorem).
For a
$($
normal
$)$
class
${\mathcal P}$
of posets, and a cardinal
$\kappa $
the following are equivalent:
-
(a)
$\textsf {MP}({\mathcal P},{\mathcal {H}}(\kappa ))_{\Sigma _1}$
. -
(b)
$\textsf {MP}^-({\mathcal P},{\mathcal {H}}(\kappa ))_{\Sigma _1}$
. -
(c)
$\textsf {BFA}_{{<}\,\kappa }({\mathcal P})$
.
Corollary 3.2. For a class
${\mathcal P}$
of posets and for an infinite cardinal
$\kappa $
, we have
-
$\textsf {MP}({\mathcal P},{\mathcal {H}}(\kappa ))_{\Sigma _1}$
,
$\Leftrightarrow $
$\textsf {MP}^-({\mathcal P},{\mathcal {H}}(\kappa ))_{\Sigma _1}$
,
$\Leftrightarrow $
$\textsf {BFA}_{{<}\,\kappa }({\mathcal P})$
,
$\Leftrightarrow $
$({\mathcal P},{\mathcal {H}}(\kappa ))_{\Sigma _1}$
-RcA,
$\Leftrightarrow $
$({\mathcal P},{\mathcal {H}}(\kappa ))_{\Sigma _1}$
-RcA
$^+$
.
The following lemma holds since
$\Pi _1$
-formulas are downward absolute.
Lemma 3.3. For any class
${\mathcal P}$
of posets, and any set A,
$({\mathcal P},A)_{\Pi _1}$
-RcA
$^+$
and
$\textsf {MP}({\mathcal P},A)_{\Pi _1}$
hold
$($
in ZFC
$)$
. In particular, we have
-
$({\mathcal P},A)_{\Pi _1}$
-RcA
$\Leftrightarrow $
$({\mathcal P},A)_{\Pi _1}$
-RcA
$^+$
$\Leftrightarrow $
$\textsf {MP}^-({\mathcal P},A)_{\Pi _1}$
$\Leftrightarrow $
$\textsf {MP}({\mathcal P},A)_{\Pi _1}$
.
In the following, we show that the equivalence in Lemma 3.3 does not hold for
$\Pi _2$
.
Nevertheless, we have the following implications.
Lemma 3.4. Suppose that
${\mathcal P}$
is a
$($
normal
$)$
class of posets defined by a
$\Sigma _m$
-formula without parameters for some number m, and A a set.Footnote
6
-
(1)
$({\mathcal P},A)_{\Pi _n}$
-RcA
$^+$
$\Rightarrow $
$\textsf {MP}({\mathcal P},A)_{\Pi _n}$
, for all
$n\geq \max \{m,1\}$
. -
(2)
$\textsf {MP}({\mathcal P},A)_{\Sigma _n}$
$\Rightarrow $
$({\mathcal P},A)_{\Sigma _n}$
-RcA
$^+$
, for all
$n\geq \max \{m,3\}$
.
Proof. The following proofs are just re-examinations of the easy proof of Proposition 2.1, (1) (e.g., the one given in Fuchino and Usuba [Reference Fuchino and Usuba15]).
-
(1): Note that, for
$n=1$
, the claim also follows from Lemma 3.3.
Assume that
$({\mathcal P},A)_{\Pi _n}$
-RcA
$^+$
holds for
$n\geq \max \{m,2\}$
. To show that
$\textsf {MP}({\mathcal P},A)_{\Pi _n}$
holds, suppose that
$\varphi =\varphi (\overline {x})$
is a
$\Pi _n$
-formula,
$\overline {a}\in A$
, and
${\mathbb {P}}\in {\mathcal P}$
is such that
$\,\|\hspace {-.35ex}\textsf {--}_{\,{\mathbb {P}}\,}{"}\,\forall P\in {\mathcal P}\,(\,\|\hspace {-.35ex}\textsf {--}_{\,P\,}{"}\,\varphi (\overline {a})\text{"})\text{"}$
holds in
$\mathsf {V}$
.
“
$\forall P\in {\mathcal P}\,(\,\|\hspace {-.35ex}\textsf {--}_{\,P\,}{"}\,\varphi (\overline {x})\text{"})$
” is
$\Pi _n$
by the choice of n. Let us denote this formula by
$\varphi ^*$
. Thus, we have
$\,\|\hspace {-.35ex}\textsf {--}_{\,{\mathbb {P}}\,}{"}\,\varphi ^*(\overline {a})\text{"}$
.
By
$({\mathcal P},A)_{\Pi _n}$
-RcA
$^+$
, it follows that there is a
${\mathcal P}$
-ground
$\mathsf {W}$
of
$\mathsf {V}$
such that
$\overline {a}\in \mathsf {W}$
and
$\mathsf {W}\models \varphi ^*(\overline {a})$
. By the definition of
$\varphi ^*$
, and since
$\mathsf {W}$
is a
${\mathcal P}$
-ground, it follows that
$\mathsf {V}\models \varphi (\overline {a})$
. (2): Assume that
$\textsf {MP}({\mathcal P},A)_{\Sigma _n}$
holds. Suppose that
$\varphi $
is
$\Sigma _n$
-formula,
$\overline {a}\in A$
, and
${\mathbb {P}}\in {\mathcal P}$
is such that
-
(3.1)
$\,\|\hspace {-.35ex}{\mathsf {-}}_{\,{\mathbb {P}}\,}{"}\,\varphi (\overline {a})\text{"}$
.
Then we have
$\,\|\hspace {-.35ex}\textsf {--}_{\,{\mathbb {P}}\,}{"}\,\varphi (\overline {a})\text { holds in a }{\mathcal P}\text {-ground}\text{"}$
.
The assertion
-
(3.2) “
$\varphi (\overline {x})$
holds in a
${\mathcal P}$
-ground”
can be expressed in a
$\Sigma _n$
-formula
$\varphi ^{**}=\varphi ^{**}(\overline {x})$
(see the remark after the proof of the present lemma). By (3.1) and by the definition (3.2) of
$\varphi ^{**}$
we have 
for all
${\mathbb {P}}$
-names 
with 
. Thus, by
$\textsf {MP}({\mathcal P},A)_{\Sigma _n}$
, it follows that
$\mathsf {V}\models \varphi ^{**}(\overline {a})$
. By the definition of
$\varphi ^{**}$
, it follows that there is a
${\mathcal P}$
-ground
$\mathsf {W}_0$
such that
$\mathsf {W}_0\models \varphi (\overline {a})$
.
The fact that (3.2) can be formulated in a
$\Sigma _n$
-formula for
$n\geq \max \{m,3\}$
, can be seen as follows.
First, let us notice the fact formulated in Lemma 3.5 below.
In the following, for formulas
$\varphi $
and
$\psi =\psi (x,\overline {y})$
we denote by
$\varphi ^{\psi (x;\overline {y})}$
the formula
$\varphi $
restricted to
$\psi (x,\overline {y})$
where
$\psi (x,\overline {y})$
is thought to be the definition of the class
${\mathcal A}_{\overline {y}}=\{x\,:\,\psi (x,\overline {y})\}$
with parameters (or, more precisely, place holders for parameters)
$\overline {y}$
. The semi-colon in “
$\varphi ^{\psi (x;\overline {y})}$
” should remind this allocation of roles among the free variables of
$\psi $
.
Thus
$\varphi ^{\psi (x;\overline {y})}$
corresponds to the informal statement:
${\mathcal A}_{\overline {y}}\models \varphi $
.
Lemma 3.5. Suppose that
$\psi =\psi (x,\overline {y})$
is a
$\Sigma _m$
-formula and
$\varphi $
is
$\Sigma _n$
-formula
$($
$\Pi _n$
-formula, resp.
$)$
. Then
$\varphi ^{\psi (x;\overline {y})}$
is a
$\Sigma _{max\{m,n\}}$
-formula
$($
a
$\Pi _{max\{m,n\}}$
-formula, resp.
$)$
.
Proof. For quantifier free formula
$\varphi $
, the claim of the Lemma is true since
$\varphi ^\psi =\varphi $
.
Suppose that, for a
$\Sigma _n$
-formula
$\varphi _0=\varphi _0(x_0,\overline {x})$
(
$\Pi _n$
-formula
$\varphi _1=\varphi _1(x_0,\overline {x})$
),
${\varphi _0}^{\psi (x;\overline {y})}$
is
$\Sigma _k$
(
${\varphi _1}^{\psi (x;\overline {y})}$
is
$\Pi _k$
resp.).
Then
-
$(\forall x_0)(\psi (x_0,\overline {y})\rightarrow {\varphi _0}^{\psi (x;\overline {y})})$
is
$\Pi _{\max \{m,k+1\}}$
, and
-
$(\exists x_0)(\psi (x_0,\overline {y})\land {\varphi _1}^{\psi (x;\overline {y})})$
is
$\Sigma _{\max \{m,k+1\}}$
.
Using this fact, the claim of the Lemma can be proved now by induction on n.
An examination of [Reference Bagaria and Hamkins5, Reference Reitz28] reveals a construction of a
$\Pi _2$
-formula
$\Phi (x,\underline {P},\underline {\delta },r,\underline {G})$
which says that
-
$\underline {P}$
is a poset,
$\underline {\delta }$
is a regular cardinal in
$\mathsf {V}$
, there is a uniquely determined inner model
${\mathcal M}$
with
$\underline {\delta }$
-cover and
$\underline {\delta }$
-approximation properties such that
$r=({}^{{\underline {\delta }{>}\,}\hspace {-0.02em}}2)^{\mathcal M}$
,
$\underline {P}\in {\mathcal M}$
,
${\mathcal M}\not =\mathsf {V}$
,
$\underline {G}$
is an
$({\mathcal M},\underline {P})$
-generic set such that
$\mathsf {V}={\mathcal M}[\underline {G}]$
, and
$x\in {\mathcal M}$
.
Let
$\psi =\psi (x)$
be a
$\Sigma _m$
-formula expressing “
$x\in {\mathcal P}$
”. Then, for a
$\Sigma _n$
-formula
$\varphi =\varphi (\overline {x})$
for
$n\geq \max \{m,3\}$
, the formula
$\varphi ^{**}(\overline {x})$
defined as
-
$\exists \,\underline {P}\exists \,\underline {\delta }\,\exists \,r\,\exists \,\underline {G}\, (\Phi (\emptyset ,\underline {P},\underline {\delta },r,\underline {G})\land \psi ^{\Phi (x;\cdots )}(\underline {P}) \land \varphi ^{\Phi (x;\cdots )}(\overline {x}))$
is
$\Sigma _n$
by Lemma 3.5, and
$\varphi ^{**}(\overline {a})$
expresses “
$\varphi (\overline {a})$
holds in a
${\mathcal P}$
-ground”.
We shall also use the following variant of Maximality Principle. Let
${\mathcal P}$
, A,
$\Gamma $
be as before.
-
MP +(𝒫, A)Γ: For
$\varphi \in \Gamma $
, and
$\overline {a}\in A$
, if
$\varphi (\overline {a})$
is a
${\mathcal P}$
-button, then
$\{{\mathord {\mathbb {1}}}\}$
is a push of the
${\mathcal P}$
-button
$\varphi (\overline {a})$
.
As before, we drop the subscript
$\Gamma $
from
$\textsf {MP}^+({\mathcal P},A)_\Gamma $
if
$\Gamma ={{\mathcal L}}_{\in }$
.
Lemma 3.6.
-
(1)
$\textsf {MP}^+({\mathcal P},A)_\Gamma $
$\Rightarrow $
$\textsf {MP}({\mathcal P},A)_\Gamma $
. -
(2) (Hamkins [Reference Hamkins20]) For an iterable
${\mathcal P}$
,
$\textsf {MP}^+({\mathcal P},A)$
$\Leftrightarrow $
$\textsf {MP}({\mathcal P},A)$
. More precisely, if
${\mathcal P}$
is
$\Sigma _m$
-definable, then for any
$n\geq \max \{m,1\}$
, we have
$\textsf {MP}^+({\mathcal P},A)_{\Pi _n}$
$\Leftrightarrow $
$\textsf {MP}({\mathcal P},A)_{\Pi _n}$
. -
(3) For an iterable
${\mathcal P}$
, if
$\textsf {MP}^+({\mathcal P},A)_\Gamma $
, then for any
${\mathbb {P}}\in {\mathcal P}$
, we have-
$\,\|\hspace {-.35ex}\textsf {--}_{\,{\mathbb {P}}\,}{"}\,\textsf {MP}^+({\mathcal P},A)_\Gamma \text{"}$
.
-
Proof. (1): is clear by definition.
(2): By (1), it is enough to show “
$\Leftarrow $
”, Assume that
$\textsf {MP}({\mathcal P},A)$
holds, and suppose that
$\varphi (\overline {a})$
is a
${\mathcal P}$
-button for an
${{\mathcal L}}_{\in }$
-formula
$\varphi $
and
$\overline {a}\in A$
. Then
$\varphi ^*:=\forall Q\,(Q\in {\mathcal P}\ \rightarrow \ \,\|\hspace {-.35ex}\textsf {--}_{\,Q\,}{"}\,\varphi (\overline {a})\text{"})$
is a
${\mathcal P}$
-button. Hence, by
$\textsf {MP}({\mathcal P},A)$
,
$\varphi ^*$
holds in
$\mathsf {V}$
. But this means that
$\{{\mathord {\mathbb {1}}}\}$
is a push for the button
$\varphi $
.
(3): Suppose that
$\textsf {MP}^+({\mathcal P},A)_\Gamma $
holds (in
$\mathsf {V}$
). For
$\varphi \in \Gamma $
, and
$\overline {a}\in A$
, let
${\mathbb {P}}\in {\mathcal P}$
be such that it forces that
$\varphi (\overline {a})$
is a
${\mathcal P}$
-button. By Maximal Principle (of forcing), there is a
${\mathbb {P}}$
-name 
of a poset such that
-
.
. Since
${\mathcal P}$
is iterable, it follows that
$\varphi (\overline {a})$
is a
${\mathcal P}$
-button over
$\mathsf {V}$
. Thus, by
$\textsf {MP}^+({\mathcal P},A)_\Gamma $
,
$\{{\mathord {\mathbb {1}}}\}$
is a push of the
${\mathcal P}$
-button
$\varphi (\overline {a})$
(in
$\mathsf {V}$
).
Again since
${\mathcal P}$
is iterable, it follows that
$\,\|\hspace {-.35ex}\textsf {--}_{\,{\mathbb {P}}\,}{"}\,\{{\mathord {\mathbb {1}}}\}\text { is a push of the }{\mathcal P}\text {-button }\varphi (\overline {a})\text{"}$
.
The following should be folklore.
Lemma 3.7. (1) If
$\alpha $
is a limit ordinal and
$V_\alpha $
satisfies a sufficiently large finite fragment of ZFC, then for any
${\mathbb {P}}\in V_\alpha $
and
$(\mathsf {V},{\mathbb {P}})$
-generic
${\mathbb {G}}$
, we have
$V_\alpha [{\mathbb {G}}]={V_\alpha }^{\mathsf {V}[{\mathbb {G}}]}$
.
(2) If
$\alpha $
is a limit ordinal and
$V_\alpha $
satisfies a sufficiently large finite fragment of ZFC, then for any direct limit
${\mathbb {P}}$
of an iteration of length
$\text {On}^{V_\alpha }$
in
$V_\alpha $
, which is definable and preserving cardinals in
$V_\alpha $
, if
${\mathbb {G}}$
is
$(\mathsf {V},{\mathbb {P}})$
-generic, then we have
-
$V_\alpha [{\mathbb {G}}]={V_\alpha }^{\mathsf {V}[{\mathbb {G}}]}$
.
(3) For each natural number k, there is a sufficiently large
$k'>k$
such that for any
$\alpha \in \text {On}$
if
$V_\alpha \prec _{\Sigma _{k'}}\mathsf {V} ($
i.e.,
$\alpha $
is
$\Sigma _{k'}$
-correct
$)$
, then for any poset
${\mathbb {P}}\in V_\alpha $
and
$(\mathsf {V},{\mathbb {P}})$
-generic
${\mathbb {G}}$
,
${V_\alpha }^{\mathsf {V}[{\mathbb {G}}]}\prec _{\Sigma _k}\mathsf {V}[{\mathbb {G}}]$
.
(4) Suppose that 
is an Easton support class iteration of increasingly directed closed posets and
$\mathfrak {P}$
is the class direct limit of the iteration. If k is a natural number and
$\kappa $
is a regular cardinal which is
$\Sigma _{k'}$
-correct for a sufficiently large
$k'>k$
, then we have
${V_\kappa }^{\mathsf {V}[{\mathbb {G}}_\kappa ]}\prec _{\Sigma _{k}}\mathsf {V}[\mathfrak {G}]$
for any
$(\mathsf {V},\mathfrak {P})$
-generic
$\mathfrak {G}$
and
${\mathbb {G}}_\kappa =\mathfrak {G}\cap {\mathbb {P}}_\kappa $
.
Proof. (1): See, e.g., Lemma 3.2 in [Reference Fuchino and Usuba15]. (2): follows from (1).
(3): See the proof of Lemma 4.8, (1) in the extended version of [Reference Fuchino and Usuba15].
(4): Let
$\Phi =\Phi (x)$
be an
${{\mathcal L}}_{\in }$
-formula which defines
$\mathfrak {P}$
. Then by the choice of
$\kappa $
, we have
${\mathbb {P}}_\kappa =\Phi ^{{V_\kappa }^{\mathsf {V}}}$
. The claim (4) follows from this fact with an argument practically identical to that for (3).
By Theorem 2.4, we cannot replace
$\Pi _2$
in the next theorem by
$\Sigma _3$
.
Theorem 3.8. Suppose that
${\mathcal P}$
is a
$\Sigma _2$
-definable iterable class of posets containing all
$\sigma $
-closed posets, and that
$\textsf {MP}^+({\mathcal P},{\mathcal {H}}(\kappa _{\mathfrak {r}\mathfrak {e}\mathfrak {f}\mathfrak {l}\,}))_{\Pi _2}$
holds. Suppose further that there is a proper class
${\mathcal K}$
of supercompact cardinals.
If
$\mathfrak {P}$
is the class poset for Laver preparation for
${\mathcal K} $
(see the proof below for more details), then we have
-
$\,\|\hspace {-.35ex}\textsf {--}_{\,\mathfrak {P}\,}{"}\,{} \begin {array}[t]{@{}l} \textsf {GA}\ +\ \textsf {MP}({\mathcal P},{\mathcal {H}}(\kappa _{\mathfrak {r}\mathfrak {e}\mathfrak {f}\mathfrak {l}\,}))_{\Pi _2}\\ +\ \text {there are class many supercompact cardinals}\text{"}. \end {array}$
Proof. Let
${\mathcal P}$
,
${\mathcal K}$
be as above.
Let
$f:\text {On}\rightarrow \mathsf {V}$
be a universal Laver function for
${\mathcal K}$
. I.e., a class function f such that
-
(3.3) for any
$\kappa \in {\mathcal K}$
, we have
$f\restriction \kappa :\kappa \rightarrow V_\kappa $
, and for any
$x\in \mathsf {V}$
and any , there is a normal ultrafilter
${\mathcal U}_{\kappa ,\lambda ,x}$
over and associated elementary embedding
$j_{\kappa ,\lambda ,x}:\mathsf {V}\stackrel {\prec \hspace {0.8ex}}{\rightarrow }_{\kappa }M$
with
$j_{\kappa ,\lambda ,x}(f)(\kappa )=x$
.
, there is a normal ultrafilter 
and associated elementary embedding 
We may also assume that
-
(3.4)
$f(\alpha )=0$
for all
$\alpha <\kappa _{\mathfrak {r}\mathfrak {e}\mathfrak {f}\mathfrak {l}\,}$
.
Note that
$f\restriction \kappa $
,
$\kappa \in {\mathcal K}$
are uniformly definable across
$V_\kappa $
(
${}={\mathcal {H}}(\kappa )$
) for all
$\kappa \in {\mathcal K}$
.
A universal Laver function exists (see, e.g., Apter [Reference Apter1, Lemma 1]).
Let
$\langle {\mathbb {P}}_\alpha \,:\,\alpha \in \text {On}\rangle $
be the Laver preparation along with f making supercompactness of all
$\kappa \in {\mathcal K}$
indestructible by
$\kappa $
-directed closed forcing. That is,
$\langle {\mathbb {P}}_\alpha \,:\,\alpha \in \text {On}\rangle $
is defined as the iterative part of the Easton support iteration 
with a control sequence
$\langle \lambda _\alpha \,:\,\alpha \in \text {On}\rangle $
of cardinals defined recursively by the following.
-
(3.5) If
$\alpha \in \text {On}$
is a limit and closed with respect to
$\langle \lambda _\beta \,:\,\beta <\alpha \rangle $
, with , then and
$\lambda _\alpha =\lambda $
. -
(3.6) Otherwise
$\lambda _\alpha =\sup \{\lambda _\beta \,:\,\beta <\alpha \}$
and
$\,\|\hspace {-.35ex}\textsf {--}_{\,{\mathbb {P}}_\alpha \,}{"}\,{\mathbb {Q}}_\alpha =\{{\mathord {\mathbb {1}}}\}\text{"}$
.
with 
, then 
and 
Let
$\mathfrak {P}$
be the class forcing which is the direct limit of
$\langle {\mathbb {P}}_\alpha \,:\,\alpha \in \text {On}\rangle $
. For each
$\kappa \in {\mathcal K}$
, let
$\mathfrak {P}_{{>}\,\kappa }$
be (the class
${\mathcal P}_\kappa $
-name of) the
$\kappa $
-directed closed tail part of the iteration. Thus
$\mathfrak {P}\sim {\mathbb {P}}_\kappa \ast \mathfrak {P}_{{>}\,\kappa }$
and
$\,\|\hspace {-.35ex}\textsf {--}_{\,{\mathbb {P}}_\kappa \,}{"}\,\mathfrak {P}_{{>}\,\kappa }\text { is a }\kappa \text {-directed closed class poset}\text{"}$
.
Let
$\mathfrak {G}$
be
$(\mathsf {V}, \mathfrak {P})$
-generic. For each
$\kappa \in {\mathcal K}$
, let
${\mathbb {G}}_\kappa =\mathfrak {G}\cap {\mathbb {P}}_\kappa $
. Each
$\kappa \in {\mathcal K}$
is made indestructible under
$\kappa $
-directed closed forcing by
${\mathbb {P}}_\kappa $
(see, e.g., [Reference Laver26]). In particular,
$\kappa $
remains supercompact in
$\mathsf {V}[{\mathbb {G}}_\lambda ]$
for all
$\lambda \in {\mathcal K}$
. It follows that
$\kappa $
remains supercompact also in
$\mathsf {V}[\mathfrak {G}]$
.
$\mathsf {V}[\mathfrak {G}]\models \textsf {GA}$
. This is because
$\mathsf {V}[\mathfrak {G}]$
satisfies Continuum Coding Axiom (CCA), and GA follows from it (see [Reference Reitz28, Theorem 3.2]). That
$\mathsf {V}[\mathfrak {G}]$
satisfies CCA follows from the fact that in
$\mathsf {V}[\mathfrak {G}]$
there are cofinally many indestructible supercompact cardinals.
Thus, it is enough to show that
$\mathsf {V}[\mathfrak {G}]\models \textsf {MP}({\mathcal P},{\mathcal {H}}(\kappa _{\mathfrak {r}\mathfrak {e}\mathfrak {f}\mathfrak {l}\,}))_{\Pi _2}$
. Note that we have
-
(3.7)
${\mathcal {H}}(\kappa _{\mathfrak {r}\mathfrak {e}\mathfrak {f}\mathfrak {l}\,})^{\mathsf {V}}={\mathcal {H}}(\kappa _{\mathfrak {r}\mathfrak {e}\mathfrak {f}\mathfrak {l}\,})^{\mathsf {V}[{\mathbb {G}}_\kappa ]}={\mathcal {H}}(\kappa _{\mathfrak {r}\mathfrak {e}\mathfrak {f}\mathfrak {l}\,})^{\mathsf {V}[\mathfrak {G}]}$
by
$\min ({\mathcal K})$
-directed closedness of
$\mathfrak {P}$
, and (3.4). Also
-
(3.8)
${V_\kappa }^{\mathsf {V}[{\mathbb {G}}_\kappa ]}={V_\kappa }^{\mathsf {V}[\mathfrak {G}]}$
for all
$\kappa \in {\mathcal K}$
by
$\kappa $
-directed closedness of
$\mathfrak {P}_{{>}\,\kappa }$
and Lemma 3.7, (2).
Working in
$\mathsf {V}[\mathfrak {G}]$
, suppose that
$\varphi =\varphi (\overline {x})$
is a
$\Pi _2$
-formula and
$\overline {a}\in {\mathcal {H}} (\kappa _{\mathfrak {r}\mathfrak {e}\mathfrak {f}\mathfrak {l}\,})$
(
$={\mathcal {H}}(\kappa _{\mathfrak {r}\mathfrak {e}\mathfrak {f}\mathfrak {l}\,})^{\mathsf {V}}$
).
Further in
$\mathsf {V}[\mathfrak {G}]$
, suppose that
${\mathbb {S}}\in {\mathcal P}$
is such that
-
(3.9)
$\mathsf {V}[\mathfrak {G}]\models \,\|\hspace {-.35ex}\textsf {--}_{\,{\mathbb {S}}\,}{"}\,\forall T\in {\mathcal P}\,(\,\|\hspace {-.35ex}\textsf {--}_{\,T\,}{"}\,\varphi (\overline {a})\text{"})\text{"}$
.
We want to show that
$\varphi (\overline {a})$
holds (in
$\mathsf {V}[\mathfrak {G}]$
).
By replacing
$\mathsf {V}$
by
$\mathsf {V}[{\mathbb {G}}_{\kappa _0}]$
, and
${\mathcal K}$
by
${\mathcal K}\setminus \kappa _0+1$
for a large enough
$\kappa _0\in {\mathcal K}$
with
${\mathbb {S}}\in \mathsf {V}[{\mathbb {G}}_{\kappa _0}]$
, we may assume that
${\mathbb {S}}\in {V_{\kappa _0}}^{\mathsf {V}}$
for a
$\kappa _0<\min ({\mathcal K})$
. Let
$\mathbb {g}$
be
$(\mathsf {V}[\mathfrak {G}],{\mathbb {S}})$
-generic. Since
${\mathbb {S}}\in {\mathcal P}$
and since
${\mathcal P}$
is iterable, we have
-
(3.10)
$\mathsf {V}[\mathfrak {G}][\mathbb {g}]\models \forall T\in {\mathcal P}\,(\,\|\hspace {-.35ex}\textsf {--}_{\,T\,}{"}\,\varphi (\overline {a})\text{"})$
.
By (3.8) (and Lemma 3.7, (2)), we have
-
(3.11)
${V_\kappa }^{\mathsf {V}[{\mathbb {G}}_\kappa ][\mathbb {g}]}={V_\kappa }^{\mathsf {V}[\mathfrak {G}][\mathbb {g}]},$
for all
$\kappa \in {\mathcal K}$
.
Note that each
$\kappa \in {\mathcal K}$
remains supercompact in all of
$V[{\mathbb {G}}_\kappa ]$
,
$\mathsf {V}[{\mathbb {G}}_\kappa ][\mathbb {g}]$
,
$V[\mathfrak {G}]$
, and
$\mathsf {V}[\mathfrak {G}][\mathbb {g}]$
. Thus,
-
(3.12)
${V_\kappa }^{\mathsf {V}[\mathfrak {G}]}\prec _{\Sigma _2}\mathsf {V}[\mathfrak {G}]$
, -
(3.13)
${V_\kappa }^{\mathsf {V}[\mathfrak {G}][\mathbb {g}]}\prec _{\Sigma _2}\mathsf {V}[\mathfrak {G}][\mathbb {g}]$
, -
(3.14)
${V_\kappa }^{\mathsf {V}[{\mathbb {G}}_\kappa ]}\prec _{\Sigma _2}\mathsf {V}[{\mathbb {G}}_\kappa ]$
, and -
(3.15)
${V_\kappa }^{\mathsf {V}[{\mathbb {G}}_\kappa ][\mathbb {g}]}\prec _{\Sigma _2}\mathsf {V}[{\mathbb {G}}_\kappa ][\mathbb {g}],$
for all
$\kappa \in {\mathcal K}$
. By (3.8) and (3.12), we have
-
(3.16)
${V_\kappa }^{\mathsf {V}[{\mathbb {G}}_\kappa ]}\prec _{\Sigma _2}\mathsf {V}[\mathfrak {G}],$
for all
$\kappa \in {\mathcal K}$
. Similarly
-
(3.17)
${V_\kappa }^{\mathsf {V}[{\mathbb {G}}_\kappa ][\mathbb {g}]}\prec _{\Sigma _2}\mathsf {V}[\mathfrak {G}][\mathbb {g}]$
holds for all
$\kappa \in {\mathcal K}$
by (3.11) and (3.13),
“
$\forall T\in {\mathcal P}\,(\,\|\hspace {-.35ex}\textsf {--}_{\,T\,}{"}\,\varphi (\overline {a})\text{"})$
” is
$\Pi _2$
(note that we need
$\Sigma _2$
-definability of
${\mathcal P}$
for this). Hence
${V_\kappa }^{\mathsf {V}[{\mathbb {G}}_\kappa ][\mathbb {g}]}\models \forall T\in {\mathcal P}\,(\,\|\hspace {-.35ex}\textsf {--}_{\,T\,}{"}\,\varphi (\overline {a})\text{"})$
by (3.10) and (3.17). By (3.15), it follows that
$\mathsf {V}[{\mathbb {G}}_\kappa ][\mathbb {g}]\models \forall T\in {\mathcal P}\,(\,\|\hspace {-.35ex}\textsf {--}_{\,T\,}{"}\,\varphi (\overline {a})\text{"})$
. This implies that
$\varphi (\overline {a})$
is a
${\mathcal P}$
-button in
$\mathsf {V}[{\mathbb {G}}_\kappa ]$
.
Similarly, since
$\mathsf {V}[\mathfrak {G}]\models {\mathbb {S}}\in {\mathcal P}$
, and
${\mathcal P}$
is
$\Sigma _2$
, we have
$\mathsf {V}[{\mathbb {G}}_\kappa ]\models {\mathbb {S}}\in {\mathcal P}$
by (3.16) and (3.14).
Since we have
$\mathsf {V}[{\mathbb {G}}_\kappa ]\models \textsf {MP}^+({\mathcal P},{\mathcal {H}}(\kappa _{\mathfrak {r}\mathfrak {e}\mathfrak {f}\mathfrak {l}\,}))_{\Pi _2}$
by Lemma 3.6, (3), it follows that
$V[{\mathbb {G}}_\kappa ]\models \varphi (\overline {a})$
for all
$\kappa \in {\mathcal K}$
.
Since
$\varphi $
is
$\Pi _2$
and
${\mathcal K}$
is cofinal in
$\text {On}$
, it follows that
$\mathsf {V}[\mathfrak {G}]\models \varphi (\overline {a})$
by (3.16).
This shows that
$\mathsf {V}[\mathfrak {G}]\models \textsf {MP}({\mathcal P},{\mathcal {H}}(\kappa _{\mathfrak {r}\mathfrak {e}\mathfrak {f}\mathfrak {l}\,}))_{\Pi _2}$
holds.
If we start from a ground model with a proper class
${\mathcal K}$
of
$C^{(n)}$
-supercompact cardinals (see Bagaria [Reference Bagaria4]) for sufficiently large n, we can improve the condition “
${\mathcal P}$
is
$\Sigma _2$
-definable” in Theorem 3.8 by “
${\mathcal P}$
is
$\Sigma _3$
-definable” (see the remark after the proof of Proposition 3.10).
“
$\Pi _2$
” and “
$\textsf {MP}({\mathcal P},{\mathcal {H}}(\kappa _{\mathfrak {r}\mathfrak {e}\mathfrak {f}\mathfrak {l}\,}))_{\Pi _2}$
” in Theorem 3.8 can be also replaced by “
$\Delta _3$
” and “
$\textsf {MP}^*({\mathcal P},{\mathcal {H}}(\kappa _{\mathfrak {r}\mathfrak {e}\mathfrak {f}\mathfrak {l}\,}))_{\Delta _3}$
” which is not covered by
$\textsf {MP}({\mathcal P},{\mathcal {H}}(\kappa _{\mathfrak {r}\mathfrak {e}\mathfrak {f}\mathfrak {l}\,}))_{\Pi _2}$
(Proposition 3.10).
In the following, we quickly review the definition and some needed facts about the variation
$\textsf {MP}^*({\mathcal P},A)_{\Gamma }$
of the Maximality Principle which will be further studied in Gappo and Lietz [Reference Gappo and Lietz16].
For an iterable class
${\mathcal P}$
of posets, a set A of parameters, and a set
$\Gamma $
of
${{\mathcal L}}_{\in }$
-formulas, let
$(\Gamma )^*_{\mathcal P}$
be the set of provably
${\mathcal P}$
-persistent formulas in
$\Gamma $
. That is, the collection of all formulas
$\varphi \in \Gamma $
,
$\varphi =\varphi (\overline {x})$
such that the
${{\mathcal L}}_{\in }$
-sentence
-
(3.18)
${(\varphi )^*_{\mathcal P}} :=\forall \overline {x}\,(\varphi (\overline {x})\rightarrow \forall {\underline {{\mathbb {P}}}}\in {\mathcal P}\,(\,\|\hspace {-.35ex}\textsf {--}_{\,{\underline {{\mathbb {P}}}}\,}{"}\,\varphi (\overline {x})\text{"}))$
is provable in ZFC.
Note that if
$\Gamma $
is closed with respect to equivalence (which is provable in ZFC) and has a recursive representatives (modulo the equivalence), then the same holds for
$(\Gamma )^*_{\mathcal P}$
(as far as
${\mathcal P}$
is a definable class but this is always assumed).
Now
$\textsf {MP}^*({\mathcal P},A)_\Gamma $
is defined as the axiom scheme consisting of formulas of the form
-
(3.19) φ
$(\forall {\underline {{\mathbb {P}}}}\in {\mathcal P})\,(\forall \overline {x}\in A)\,(\,\|\hspace {-.35ex}\textsf {--}_{\,{\underline {{\mathbb {P}}}}\,}{"}\,\varphi (\overline {x})\text{"}\ \rightarrow \ \varphi (\overline {x})),$
for each
$\varphi \in (\Gamma )^{*}_{\mathcal P}$
.
Similarly to the
$\textsf {MP}(\cdots )_{\Gamma }$
and
$(\cdots )_{\Gamma }$
-RcA
$^+$
hierarchies, we write
$\textsf {MP}^*({\mathcal P},A)$
for
$\textsf {MP}^*({\mathcal P},A)_{{{\mathcal L}}_{\in }}$
.
$\textsf {MP}^*({\mathcal P},{\mathcal {H}}(2^{\aleph _0}))$
of the family
${\mathcal P}$
consisting of ccc posets corresponds to the principles considered in Stavi and Väänänen [Reference Stavi and Väänänen30].
The main point of the definition of
$\textsf {MP}^*({\mathcal P},A)_\Gamma $
is that the persistence is coded in the collection
$(\Gamma )^*_{\mathcal P}$
so that each formula (3.19)
${}_{\varphi }$
in
$\textsf {MP}^*({\mathcal P},A)_\Gamma $
remains at about the same complexity of
$\varphi $
.
The following is easy to prove.
Lemma 3.9. For an iterable class
${\mathcal P}$
of posets, arbitrary set A of parameters and set
$\Gamma $
of formulas, the following are equivalent:
(a)
$\textsf {MP}({\mathcal P},A)_{(\Gamma )^*_{\mathcal P}}$
, (b)
$\textsf {MP}^+({\mathcal P},A)_{(\Gamma )^*_{\mathcal P}}$
, (c)
$({\mathcal P},A)_{(\Gamma )^*_{\mathcal P}}$
-RcA
$^+$
,
(d)
$\textsf {MP}^*({\mathcal P},A)_{\Gamma }$
.
The hierarchy of this type of restricted Maximality Principles also appears in Goodman [Reference Goodman19]. Our
$\textsf {MP}^*({\mathcal P},A)_\Gamma $
is called “
$\Gamma $
-
$\textsf {MP}_{\mathcal P}(A)$
” in [Reference Goodman19]. Though the choice of symbols in [Reference Goodman19] is so that letter
$\Gamma $
is used to denote the class of posets and
$\Phi $
to denote the class of formulas.
The hierarchy of
$\textsf {MP}^*$
is actually a special case of the hierarchy of “
$\textsf {BFA}({\mathcal P},\Gamma )_{\kappa ,\lambda }$
” in Asperó [Reference Asperó2] (see [Reference Gappo and Lietz16]).Footnote
7
The proof of Lemma 3.4, (2), shows also the implication.
-
(2′)
$\textsf {MP}^*({\mathcal P},A)_{\Sigma _n}$
$\Rightarrow $
$({\mathcal P},A)_{\Sigma _n}$
-RcA
$^+$
, for all
$n\geq \max \{m,3\},$
where
${\mathcal P}$
is
$\Sigma _m$
.
Thus, by Theorem 2.4,
$\textsf {MP}^*({\mathcal P},A)_{\Sigma _n}$
for
$n\geq \max \{m,3\}$
for m as above implies
$\neg \textsf {GA}$
. In particular, for
$\Sigma _3$
-definable
${\mathcal P}$
,
$\textsf {MP}^*({\mathcal P},A)_{\Sigma _3}$
implies
$\neg \textsf {GA}$
. This shows that the condition
$\Delta _3$
in the following proposition is (almost) optimal.
Proposition 3.10. Suppose that
${\mathcal P}$
is a
$\Sigma _3$
-definable iterable class of posets containing all
$\sigma $
-closed posets, and that
$\textsf {MP}^+({\mathcal P},{\mathcal {H}}(\kappa _{\mathfrak {r}\mathfrak {e}\mathfrak {f}\mathfrak {l}\,}))_{\Delta _3}$
holds. Suppose further that there is a proper class
${\mathcal K}$
of
$C^{(n)}$
-supercompact cardinals for a sufficiently large n and
$\mathfrak {P}$
is the class poset defined as in the proof of Theorem 3.8 for this
${\mathcal K}$
.
Then we have
-
$\,\|\hspace {-.35ex}\textsf {--}_{\,\mathfrak {P}\,}{"}\,{} \textsf {GA}\ +\ \textsf {MP}^*({\mathcal P},{\mathcal {H}}(\kappa _{\mathfrak {r}\mathfrak {e}\mathfrak {f}\mathfrak {l}\,}))_{\Delta _3}\!\text{"}$
.
Proof. Suppose that
${\mathcal K}$
and
$\mathfrak {P}$
are as above and
$\textsf {MP}^+({\mathcal P},{\mathcal {H}}(\kappa _{\mathfrak {r}\mathfrak {e}\mathfrak {f}\mathfrak {l}\,}))_{\Delta _3}$
holds.
Let
$\mathfrak {G}$
be a
$(\mathsf {V},\mathfrak {P})$
-generic filter.
As it has been already shown in the proof of Theorem 3.8, we have
$\mathsf {V}[\mathfrak {G}]\models \textsf {GA}$
.
So we prove
$\mathsf {V}[\mathfrak {G}]\models \textsf {MP}^*({\mathcal P},{\mathcal {H}}(\kappa _{\mathfrak {r}\mathfrak {e}\mathfrak {f}\mathfrak {l}\,}))_{\Delta _3}$
. Working in
$\mathsf {V}[\mathfrak {G}]$
, suppose that
$\varphi =\varphi (\overline {x})$
is a
$(\Delta _3)^*_{\mathcal P}$
-formula and
$\overline {a}\in {\mathcal {H}}(\kappa _{\mathfrak {r}\mathfrak {e}\mathfrak {f}\mathfrak {l}\,})$
(
$={\mathcal {H}}(\kappa _{\mathfrak {r}\mathfrak {e}\mathfrak {f}\mathfrak {l}\,})^{\mathsf {V}}$
).
Further in
$\mathsf {V}[\mathfrak {G}]$
, suppose that
${\mathbb {S}}\in {\mathcal P}$
is such that
-
(3.20)
$\mathsf {V}[\mathfrak {G}]\models \,\|\hspace {-.35ex}\textsf {--}_{\,{\mathbb {S}}\,}{"}\,\varphi (\overline {a})\text{"}$
.
We want to show that
$\varphi (\overline {a})$
holds (in
$\mathsf {V}[\mathfrak {G}]$
).
Similarly to the proof of Theorem 3.8, we may assume that
${\mathbb {S}}\in {V_{\kappa _0}}^{\mathsf {V}}$
for a
$\kappa _0<\min ({\mathcal K})$
. Let
$\mathbb {g}$
be
$(\mathsf {V}[\mathfrak {G}],{\mathbb {S}})$
-generic. By the choice (3.20) of
${\mathbb {S}}$
, we have
-
(3.21)
$\mathsf {V}[\mathfrak {G}][\mathbb {g}]\models \varphi (\overline {a})$
.
By the choice of the “sufficiently large” n (in terms of Lemma 3.7, (4) and (3)), and by (3.8),
-
(3.22)
${V_\kappa }^{\mathsf {V}[{\mathbb {G}}_\kappa ]}\prec _{\Sigma _3}\mathsf {V}[\mathfrak {G}]$
, -
(3.23)
${V_\kappa }^{\mathsf {V}[{\mathbb {G}}_\kappa ][\mathbb {g}]}\prec _{\Sigma _3}\mathsf {V}[\mathfrak {G}][\mathbb {g}]$
,
and, since
$\kappa $
remains supercompact in
$\mathsf {V}[{\mathbb {G}}_\kappa ]$
and
$\mathsf {V}[{\mathbb {G}}_\kappa ][\mathbb {g}]$
,
-
(3.24)
${V_\kappa }^{\mathsf {V}[{\mathbb {G}}_\kappa ]}\prec _{\Sigma _2}\mathsf {V}[{\mathbb {G}}_\kappa ]$
, -
(3.25)
${V_\kappa }^{\mathsf {V}[{\mathbb {G}}_\kappa ][\mathbb {g}]}\prec _{\Sigma _2}\mathsf {V}[{\mathbb {G}}_\kappa ][\mathbb {g}],$
for all
$\kappa \in {\mathcal K}$
.
By (3.22),
${\mathbb {S}}\in {\mathcal P}$
(in
$\mathsf {V}[\mathfrak {G}]$
), and since
${\mathcal P}$
is
$\Sigma _3$
,
${V_\kappa }^{\mathsf {V}[{\mathbb {G}}_\kappa ]}\models {\mathbb {S}}\in {\mathcal P}$
. Hence, by (3.24),
$\mathsf {V}[{\mathbb {G}}_\kappa ]\models {\mathbb {S}}\in {\mathcal P}$
.
Since
$\varphi $
is
$\Delta _3$
, (3.21) and (3.23) implies
${V_\kappa }^{\mathsf {V}[{\mathbb {G}}_\kappa ][\mathbb {g}]}\models \varphi (\overline {a})$
. This and (3.25) imply
$\mathsf {V}[{\mathbb {G}}_\kappa ][\mathbb {g}]\models \varphi (\overline {a})$
.
By
$\varphi \in (\Delta _3)^*_{\mathcal P}$
, it follows that
$\mathsf {V}[{\mathbb {G}}_\kappa ][\mathbb {g}]\models \forall \underline {{\mathbb {Q}}}\in {\mathcal P}\,(\,\|\hspace {-.35ex}\textsf {--}_{\,\underline {{\mathbb {Q}}}\,}{"}\,\varphi (\overline {a})\text{"})$
. Thus 
.
Since
$\mathsf {V}[{\mathbb {G}}_\kappa ]\models \textsf {MP}^+({\mathcal P},{\mathcal {H}}(\kappa _{\mathfrak {r}\mathfrak {e}\mathfrak {f}\mathfrak {l}\,}))_{\Delta _3}$
by Lemma 3.6, (3) (and since
$\{{\mathord {\mathbb {1}}}\}\in {\mathcal P}$
), it follows that
-
(3.26)
$\mathsf {V}[{\mathbb {G}}_\kappa ]\models \varphi (\overline {a})$
.
Since
$\varphi $
is
$\Delta _3$
, and hence
$\Pi _3$
in particular,
${V_{\kappa }}^{\mathsf {V}[{\mathbb {G}}_\kappa ]}\models \varphi (\overline {a})$
by (3.24). Thus, by (3.26), it follows that
$\mathsf {V}[\mathfrak {G}]\models \varphi (\overline {a})$
.
This shows that
$\mathsf {V}[\mathfrak {G}]\models \textsf {MP}^*({\mathcal P},{\mathcal {H}}(\kappa _{\mathfrak {r}\mathfrak {e}\mathfrak {f}\mathfrak {l}\,}))_{\Delta _3}$
holds.
The first half of the proof of Proposition 3.10 can be applied to the proof of Theorem 3.8 to obtain the following.
-
(A variant of Theorem 3.8) Suppose that
${\mathcal P}$
is a
$\Sigma _3$
-definable iterable class of posets containing all
$\sigma $
-closed posets, and that
$\textsf {MP}^+({\mathcal P},{\mathcal {H}}(\kappa _{\mathfrak {r}\mathfrak {e}\mathfrak {f}\mathfrak {l}\,}))_{\Pi _2}$
holds. Suppose further that there is a proper class
${\mathcal K}$
of
$C^{(n)}$
-supercompact cardinals for a sufficiently large n.If
$\mathfrak {P}$
is the class poset for Laver preparation for
${\mathcal K}$
, then we have-
$\,\|\hspace {-.35ex}\textsf {--}_{\,\mathfrak {P}\,}{"}\,{} \begin {array}[t]{@{}l} \textsf {GA}\ +\ \textsf {MP}({\mathcal P},{\mathcal {H}}(\kappa _{\mathfrak {r}\mathfrak {e}\mathfrak {f}\mathfrak {l}\,}))_{\Pi _2}\\ +\ \text {there are class many supercompact cardinals}\text{"}. \end {array}$
-
The following theorem is also obtained by combining the proofs of Theorem 3.8 and Proposition 3.10 taking Lemma 3.9 into account.
Theorem 3.11. (1) Suppose that
${\mathcal P}$
is a
$\Sigma _2$
-definable iterable class of posets containing all
$\sigma $
-closed posets such that
$\textsf {MP}^+({\mathcal P},{\mathcal {H}}(\kappa _{\mathfrak {r}\mathfrak {e}\mathfrak {f}\mathfrak {l}\,}))_{\Gamma }$
holds where
$\Gamma $
denotes here the set of all formulas representable as the conjunction of a
$\Sigma _2$
-formula and a
$(\Delta _3)^*_{\mathcal P}$
-formula. Suppose further that there is a proper class
${\mathcal K}$
of supercompact cardinals and
$\mathfrak {P}$
is the class poset defined as in the proof of Theorem 3.8 for this
${\mathcal K}$
.
Then we have
-
$\,\|\hspace {-.35ex}\textsf {--}_{\,\mathfrak {P}\,}{"}\,{} \textsf {GA}\ +\ \textsf {MP}^*({\mathcal P},{\mathcal {H}}(\kappa _{\mathfrak {r}\mathfrak {e}\mathfrak {f}\mathfrak {l}\,}))_{\Gamma }\text{"}$
.
(2) Suppose that
${\mathcal P}$
is a
$\Sigma _3$
-definable iterable class of posets containing all
$\sigma $
-closed posets such that
$\textsf {MP}^+({\mathcal P},{\mathcal {H}}(\kappa _{\mathfrak {r}\mathfrak {e}\mathfrak {f}\mathfrak {l}\,}))_{\Gamma }$
holds where
$\Gamma $
is the set of formulas defined as in (1). Suppose further that there is a proper class
${\mathcal K}$
of
$C^{(n)}$
-supercompact cardinals for a sufficiently large n, and
$\mathfrak {P}$
is the class poset defined as in the proof of Theorem 3.8 for this
${\mathcal K}$
.
Then we have
-
$\,\|\hspace {-.35ex}\textsf {--}_{\,\mathfrak {P}\,}{"}\,{} \textsf {GA}\ +\ \textsf {MP}^*({\mathcal P},{\mathcal {H}}(\kappa _{\mathfrak {r}\mathfrak {e}\mathfrak {f}\mathfrak {l}\,}))_{\Gamma }\text{"}$
.
The following corollary shows in particular that the implication in Lemma 3.4, (1) for
$n=2$
cannot be reversed.
Corollary 3.12. (1) Suppose that
${\mathcal P}$
is a
$\Sigma _2$
-definable iterable class of posets containing all
$\sigma $
-closed posets, and also a poset adding a real. Assume further that there is a proper class
${\mathcal K}$
of supercompact cardinals, and
$\textsf {MP}^+({\mathcal P},{\mathcal {H}}(\kappa _{\mathfrak {r}\mathfrak {e}\mathfrak {f}\mathfrak {l}\,}))_{\Gamma }$
holds where
$\Gamma $
is defined just as in Theorem 3.11. Then, there is a class poset
$\mathfrak {P}$
such that we have
-
.
. (2) Suppose that
${\mathcal P}$
is a
$\Sigma _3$
-definable iterable class of posets containing all
$\sigma $
-closed posets, and a poset adding a real. Assume further that there is a proper class
${\mathcal K}$
of
$C^{(n)}$
-supercompact cardinals for sufficiently large n, and
$\textsf {MP}^+({\mathcal P},{\mathcal {H}}(\kappa _{\mathfrak {r}\mathfrak {e}\mathfrak {f}\mathfrak {l}\,}))_{\Gamma }$
holds for the set of formulas
$\Gamma $
as defined in Theorem 3.11. Then, there is a class poset
$\mathfrak {P}$
such that we have
-
.
.Proof. Note that
$\textsf {MP}^+({\mathcal P},{\mathcal {H}}(\kappa _{\mathfrak {r}\mathfrak {e}\mathfrak {f}\mathfrak {l}\,}))_{\Sigma _1}$
for
${\mathcal P}$
as here implies
$\neg \textsf {CH}$
(see Fuchino and Usuba [Reference Fuchino and Usuba15, Theorem 3.3]).
Typical instances of
${\mathcal P}$
in Corollary 3.12 are when
${\mathcal P}$
is the class of all proper posets, the class of all semi-proper posets, or the class of all stationary preserving posets.
Problem 3.13. Do some theorems hold which would imply certain non-implications similar to those in Corollary 3.12 for
${\mathcal P}= \sigma $
-closed posets, or
${\mathcal P}=$
ccc posets?
4. Generic absoluteness under Recurrence Axioms
The conclusion of the following Theorem 4.1 generalizes that of Viale’s Theorem 1.1 ([Reference Viale32, Theorem 1.4]). Note that the assumption in our Theorem 4.1, the Recurrence Axiom
$({\mathcal P},{\mathcal {H}}(\kappa ))$
-RcA
$^+$
for an uncountable cardinal
$\kappa $
and an iterable class
${\mathcal P}$
of posets, namely, is of much lower consistency strength than the assumptions in Viale’s Theorem for some instances of
${\mathcal P}$
. Actually the assumption of Theorem 4.1 is even compatible with
$V=L$
for many “natural” classes
${\mathcal P}$
of posets including the cases “
${\mathcal P}=$
all ccc posets” or “
${\mathcal P}=$
all proper posets” (see [Reference Hamkins20, Theorems 5.6 and 5.10]). For “
${\mathcal P}=$
all stationary preserving posets”, Theorem 1.6 in Ikegami and Trang [Reference Ikegami and Trang22] proves that the existence of proper class many strongly compact cardinals plus a reflecting cardinal is an upper bound of the consistency strength of the Maximality Principle for the
${\mathcal P}$
.
Known lower bound of this Recurrence Axiom is also large. By Ikegami–Trang Theorem 2.2,
$(\text {stationary preserving},{\mathcal {H}}(2^{\aleph _0}))$
-RcA is equivalent with BMM. Schindler [Reference Schindler, Bagaria and Todorcevic29] shows that BMM implies that there is an inner model with a strong cardinal.
In contrast, the Maximality Principle for
${\mathcal P}={}$
semi-proper posets, the consistency strength is much lower than this by Asperó [Reference Asperó2]. Note that, in general, semi-proper and stationary preserving are not identical notions.
The existence of the tightly super-
$C^{(\infty )} {\mathcal P}$
-Laver-gen. hyperhuge cardinal
$\kappa $
is the known Laver-generic large cardinal axiom which implies the full Recurrence Axiom for
${\mathcal P}$
and
${\mathcal {H}}(\kappa )$
(see Fuchino and Usuba [Reference Fuchino and Usuba15]).
There is practically no (consistent) generic large cardinal axiom formalizable in a single formula which also implies
$({\mathcal P},\emptyset )$
-RcA for any sufficiently general class
${\mathcal P}$
of posets ([Reference Fuchino12]).
In [Reference Fuchino and Usuba15], it is proved that for an iterable class
${\mathcal P}$
of posets, the existence of the tightly super-
$C^{(\infty )} {\mathcal P}$
-Laver-gen. hyperhuge cardinal
$\kappa $
with
$\kappa =\kappa _{\mathfrak {r}\mathfrak {e}\mathfrak {f}\mathfrak {l}\,}$
implies
$({\mathcal P},{\mathcal {H}}(\kappa _{\mathfrak {r}\mathfrak {e}\mathfrak {f}\mathfrak {l}\,}))$
-RcA
$^+$
where
$\kappa _{\mathfrak {r}\mathfrak {e}\mathfrak {f}\mathfrak {l}\,}$
is defined as
$\kappa _{\mathfrak {r}\mathfrak {e}\mathfrak {f}\mathfrak {l}\,}:=\max \{2^{\aleph _0},\aleph _2\}$
. Note that this does not contradict what we mentioned in the last paragraph since the tightly super-
$C^{(\infty )} {\mathcal P}$
-Laver-gen. hyperhugeness of
$\kappa _{\mathfrak {r}\mathfrak {e}\mathfrak {f}\mathfrak {l}\,}$
is only expressed by an axiom schema. Note that by [Reference Fuchino and Usuba15] we know the exact consistency strength of this principle (as that of
$\kappa _{\mathfrak {r}\mathfrak {e}\mathfrak {f}\mathfrak {l}\,}$
being super-
$C^{(\infty )}$
hyperhuge in the bedrock).
In Section 5 we show that the generalization of the conclusion of Viale’s Theorem 1.1 (like that of the following Theorem 4.1) already follows from tight
${\mathcal P}$
-Laver-gen. hugeness. This assumption is still much stronger than that of Viale’s Theorem 1.1 but the upper bound of the consistency strength of this Laver-genericity is far below the consistency strength of a tight super-
$C^{(\infty )} {\mathcal P}$
-Laver-gen. hyperhuge cardinal.
Theorem 4.1. Suppose that
${\mathcal P}$
is an iterable
$\Sigma _n$
-definable class of posets for
$n\geq 2$
and
$({\mathcal P},{\mathcal {H}}(\kappa ))_{\Sigma _n\cup \Gamma }$
-RcA
$^+$
holds for an uncountable cardinal
$\kappa $
where
$\Gamma $
is the set of all formulas which are conjunction of a
$\Sigma _2$
-formula and a
$\Pi _2$
-formula. Then, for any
${\mathbb {P}}\in {\mathcal P}$
such that
$\,\|\hspace {-.35ex}\textsf {--}_{\,{\mathbb {P}}\,}{"}\,\textsf {BFA}_{{<}\,\kappa }({\mathcal P})\text{"}$
,
-
${\mathcal {H}}(\mu ^+)^{\mathsf {V}}\prec _{\Sigma _2}{\mathcal {H}}(\mu ^+)^{\mathsf {V}[{\mathbb {G}}]}$
holds for all
$\mu <\kappa $
and for
$(\mathsf {V},{\mathbb {P}})$
-generic
${\mathbb {G}}$
.
Thus, we have
${\mathcal {H}}(\kappa )^{\mathsf {V}}\prec _{\Sigma _2}{\mathcal {H}}((\kappa ^{(+)})^{\mathsf {V}[{\mathbb {G}}]})^{\mathsf {V}[{\mathbb {G}}]}$
.
Proof. Suppose that
${\mathbb {P}}\in {\mathcal P}$
is such that
$\,\|\hspace {-.35ex}\textsf {--}_{\,{\mathbb {P}}\,}{"}\,\textsf {BFA}_{{<}\,\kappa }({\mathcal P})\text{"}$
and
${\mathbb {G}}$
is a
$(\mathsf {V},{\mathbb {P}})$
-generic filter. Let
$\varphi =\varphi (x)$
be a
$\Sigma _2$
-formula in
${{\mathcal L}}_{\in }$
, and
$\varphi (x)=\exists y\,\psi (x,y)$
for a
$\Pi _1$
-formula
$\psi $
in
${{\mathcal L}}_{\in }$
. Let
$\mu <\kappa $
and
$a\in {\mathcal {H}}(\mu ^+)$
(
$\subseteq {\mathcal {H}}(\kappa )$
). We have to show that
${\mathcal {H}}(\mu ^+)^{\mathsf {V}}\models \varphi (a) \Leftrightarrow {\mathcal {H}}((\mu ^+)^{\mathsf {V}[{\mathbb {G}}]})^{\mathsf {V}[{\mathbb {G}}]}\models \varphi (a)$
.
Suppose first that
${\mathcal {H}}(\mu ^+)^{\mathsf {V}}\models \varphi (a)$
. Let
$b\in {\mathcal {H}}(\mu ^+)^{\mathsf {V}}$
be such that
${\mathcal {H}}((\mu ^+)^{\mathsf {V}})^{\mathsf {V}}\models \psi (a,b)$
. Since we have
$\mathsf {V}\models \textsf {BFA}_{{<}\,\kappa }({\mathcal P})$
by Ikegami–Trang Theorem 2.2, it follows that
${\mathcal {H}}((\mu ^+)^{\mathsf {V}[{\mathbb {G}}]})^{\mathsf {V}[{\mathbb {G}}]}\models \psi (a,b)$
by Bagaria’s Absoluteness Theorem 1.2, and thus
${\mathcal {H}}((\mu ^+)^{\mathsf {V}[{\mathbb {G}}]})^{\mathsf {V}[{\mathbb {G}}]}\models \varphi (a)$
.
Note that we did not use the assumption “
$\,\|\hspace {-.35ex}\textsf {--}_{\,{\mathbb {P}}\,}{"}\,\textsf {BFA}_{{<}\,\kappa }({\mathcal P})\text{"}$
” for this direction.
Suppose now
${\mathcal {H}}((\mu ^+)^{\mathsf {V}[{\mathbb {G}}]})^{\mathsf {V}[{\mathbb {G}}]}\models \varphi (a)$
. By
$({\mathcal P},{\mathcal {H}}(\kappa ))_{\Sigma _n\cup \Gamma }$
-RcA
$^+$
, there is a
${\mathcal P}$
-ground
$\mathsf {W}$
of
$\mathsf {V}$
such that
-
(4.1)
$\mathsf {W}\models \!{"\,}\textsf {BFA}_{{<}\,\mu ^+}({\mathcal P})\ \land \ {\mathcal {H}}(\mu ^+)\models \varphi (a)\text{"}$
.
Note that the formula in (4.1) is
$\Sigma _n$
if
$n\geq 3$
and
$\Gamma $
if
$n=2$
.
Let
$b\in {\mathcal {H}}((\mu ^+)^{\mathsf {W}})^{\mathsf {W}}$
be such that
$\mathsf {W}\models \!{"\,}{\mathcal {H}}(\mu ^+)\models \psi (a,b)\text{"}$
. By Bagaria’s Absoluteness Theorem 1.2, and since
$\mathsf {V}$
is a
${\mathcal P}$
-generic extension of
$\mathsf {W}$
, it follows that
$\mathsf {V}\models \!{"\,}{\mathcal {H}}(\mu ^+)\models \psi (a,b)\text{"}$
and hence
${\mathcal {H}}(\mu ^+)^{\mathsf {V}}\models \varphi (a)$
.
For the last statement of the present theorem, let
$\varphi $
be a
$\Sigma _2$
-formula, and
$a\in {\mathcal {H}}(\kappa )$
. If
${\mathcal {H}}(\kappa )\models \varphi (a)$
, then, by (1.4), there is
$\mu <\kappa $
such that
${\mathcal {H}}(\mu ^+)\models \varphi (a)$
. By the first part of the theorem, it follows that
${\mathcal {H}}((\mu ^+)^{\mathsf {V}[{\mathbb {G}}]})^{\mathsf {V}[{\mathbb {G}}]}\models \varphi (a)$
. Thus
${\mathcal {H}}((\kappa ^{(+)})^{\mathsf {V}[{\mathbb {G}}]})^{\mathsf {V}[{\mathbb {G}}]}\models \varphi (a)$
by (1.4).
If
${\mathcal {H}}((\kappa ^{(+)})^{\mathsf {V}[{\mathbb {G}}]})^{\mathsf {V}[{\mathbb {G}}]}\models \varphi (a)$
, then there is
$\mu <\kappa $
such that
${\mathcal {H}}((\mu ^+)^{\mathsf {V}[{\mathbb {G}}]})^{\mathsf {V}[{\mathbb {G}}]}\models \varphi (a)$
(this is also shown using (1.4)). Hence
${\mathcal {H}}((\mu ^+)^{\mathsf {V}})\models \varphi (a)$
by the first part of the theorem.
Note that by Lemma 1.6, the conclusion (4.1) of Theorem 4.1 can be yet strengthened to
-
(4.2)
$\langle {\mathcal {H}}(\mu ^+),\in , I_{\textsf {NS}}\rangle ^{\mathsf {V}} \prec _{\Sigma _2}\langle {\mathcal {H}}(\mu ^+), \in , I_{\textsf {NS}}\rangle ^{\mathsf {V}[{\mathbb {G}}]}$
holds for all
$\mu <\kappa $
and for
$(\mathsf {V},{\mathbb {P}})$
-generic
${\mathbb {G}}$
.
5. Generic absoluteness under Laver-genericity
Laver-genericity also implies a conclusion similar to that of Viale’s Theorem 1.1. Although this fact does not have an advantage in terms of consistency strength in comparison with Theorem 4.1, the Laver-generic large cardinal we need in Theorem 5.7 below is much weaker than the tight super-
$C^{(\infty )} {\mathcal P}$
-Laver-generic hyperhugeness, the generic large cardinal property which is known to imply the corresponding Recurrence Axiom used in Theorem 4.1 (see [Reference Fuchino12, Reference Fuchino and Usuba15]).
In Viale [Reference Viale32], the absoluteness statement of his Theorem 1.1 is also discussed in connection with the Resurrection Axiom (see Theorem 5.2).
Adopting the generalized setting introduced in Fuchino [Reference Fuchino12], we define the Resurrection Axiom as follows: for an iterable class
${\mathcal P}$
of posets and a definition
$\mu ^\bullet $
of an uncountable cardinal (e.g., as
$\aleph _1$
,
$\aleph _2$
,
$2^{\aleph _0}$
,
$(2^{\aleph _0})^+$
,
$\kappa _{\mathfrak {r}\mathfrak {e}\mathfrak {f}\mathfrak {l}\,}$
etc.),Footnote
8
the Resurrection Axiom for
${\mathcal P}$
and
$\mu ^\bullet $
is the statement.
-
RA(𝒫, μ •): For any
${\mathbb {P}}\in {\mathcal P}$
, there is a
${\mathbb {P}}$
-name of a poset such that and
${\mathcal {H}}(\mu ^\bullet )^{\mathsf {V}}\prec {\mathcal {H}}(\mu ^\bullet )^{\mathsf {V}[\mathbb {H}]}$
for any -generic
$\mathbb {H}$
.Footnote
9
of a poset such that 
and 
-generic 
Lemma 5.1 (Hamkins, and Johnstone [Reference Hamkins and Johnstone21]).
Assume that
${\mathcal P}$
is an iterable class of posets,
$\mu ^\bullet $
is a definition of an uncountable cardinal, and
$\textsf {RA}({\mathcal P},\mu ^\bullet )$
holds. Then
(1)
$\textsf {BFA}_{{<}\,\mu ^\bullet }({\mathcal P})$
holds.
(2) If all elements of
${\mathcal P}$
preserve stationarity of subsets of
$\omega _1$
,
$2^{\aleph _0}=2^{\aleph _1}$
, and
$\mu ^\bullet ={}$
“
$2^{\aleph _0}$
”, then
$\textsf {BFA}^{+{<}\,\mu ^\bullet }_{{<}\,\mu ^\bullet }({\mathcal P})$
holds.
Proof. (1): It is easy to check that (c) of Bagaria’s Theorem 1.2 holds.Footnote 10
(2): Similarly to (1) using (c) of Theorem 1.8.Footnote 11
Theorem 5.2 (A generalization of Theorem 5.1 in Viale [Reference Viale32]).
Suppose that
${\mathcal P}$
is an iterable class of posets,
$\mu ^\bullet $
is a definition of an uncountable cardinal and
$\textsf {RA}({\mathcal P},\mu ^\bullet )$
holds. Then we have
-
${\mathcal {H}}(\mu ^\bullet )^{\mathsf {V}}\prec _{\Sigma _2}{\mathcal {H}}(\mu ^\bullet )^{\mathsf {V}[{\mathbb {G}}]},$
for any
${\mathbb {P}}\in {\mathcal P}$
such that
$\,\|\hspace {-.35ex}\textsf {--}_{\,{\mathbb {P}}\,}{"}\,\textsf {BFA}_{{<}\,\mu ^\bullet }({\mathcal P})\text{"}$
, and
$(\mathsf {V},{\mathcal P})$
-generic
${\mathbb {G}}$
.
Proof. An argument similar to that of Lemma 5.1 will do.
In [Reference Fuchino12], the boldface version of the following is proved:
Theorem 5.3 (Fuchino [Reference Fuchino12]).
For an iterable class
${\mathcal P}$
of posets, and a definition
$\mu ^\bullet $
of a cardinal, if
$\mu ^\bullet $
is tightly
${\mathcal P}$
-Laver gen. superhuge, then
$\textsf {RA}({\mathcal P},\mu ^\bullet )$
holds.
Corollary 5.4. For an iterable class
${\mathcal P}$
of posets, and a definition
$\mu ^\bullet $
of a cardinal, if
$\mu ^\bullet $
is tightly
${\mathcal P}$
-Laver gen. superhuge, then we have
-
${\mathcal {H}}(\mu ^\bullet )^{\mathsf {V}}\prec _{\Sigma _2}{\mathcal {H}}(\mu ^\bullet )^{\mathsf {V}[{\mathbb {G}}]},$
for any
${\mathbb {P}}\in {\mathcal P}$
such that
$\,\|\hspace {-.35ex}\textsf {--}_{\,{\mathbb {P}}\,}{"}\,\textsf {BFA}_{{<}\,\mu ^\bullet }({\mathcal P})\text{"}$
and
$(\mathsf {V},{\mathbb {P}})$
-generic
${\mathbb {G}}$
.
Note that for many cases (with natural setting of
${\mathcal P}$
and the notion of large cardinal), if
$\kappa $
is
${\mathcal P}$
-Laver-gen. large cardinal, then
$\kappa =\kappa _{\mathfrak {r}\mathfrak {e}\mathfrak {f}\mathfrak {l}\,}$
(see Fuchino et al. [Reference Fuchino, Rodrigues and Sakai13]).
In the following, we show in a direct proof, that Corollary 5.4 can be yet slightly improved (see Theorem 5.7 below).
It is known that Laver-gen. large cardinal axiom proves strong forms of double-plus forcing axioms (see [Reference Fuchino, Rodrigues and Sakai13, Theorem 5.7]). In the Proposition 5.5 below we only recap a part of this result needed for the following argument.
For a class
${\mathcal P}$
of posets, and cardinals
$\kappa $
and
$\lambda $
,
-
$\textsf {FA}^{+{<}\,\lambda }_{{<}\,\kappa }({\mathcal P})$
: For any
${\mathbb {P}}\in {\mathcal P}$
, any family
${\mathcal {D}}$
of dense subsets of
${\mathcal P}$
with
$\mathopen {|\,}{\mathcal {D}}\mathclose {\,|}<\kappa $
, and any family
${\mathcal S}$
of
${\mathbb {P}}$
-names of stationary subsets of
$\omega _1$
with
$\mathopen {|\,}{\mathcal S}\mathclose {\,|}<\lambda $
, there is a
${\mathcal {D}}$
-generic filter
${\mathbb {G}}$
on
${\mathbb {P}}$
such that is a stationary subset of
$\omega _1$
for all .
is a stationary subset of 
. Note that MM
$^{++}$
is just
$\textsf {FA}^{+{<}\,\aleph _2}_{{<}\,\aleph _2}(\text {stationary preserving posets})$
.
$\textsf {FA}_{{<}\,\kappa }({\mathcal P})$
is the principle we obtain by dropping the mention about
${\mathcal S}$
from the definition of
$\textsf {FA}^{+{<}\,\lambda }_{{<}\,\kappa }({\mathcal P})$
.
Proposition 5.5. (1) Suppose that
$\kappa $
is
${\mathcal P}$
-Laver-gen. supercompact. Then
$\textsf {FA}_{{<}\,\kappa }({\mathcal P})$
holds.
(2) If all elements of the class
${\mathcal P}$
of posets are stationary preserving and
$\kappa $
is
${\mathcal P}$
-Laver-gen. supercompact, then
$\textsf {FA}^{+{<}\,\kappa }_{{<}\,\kappa }({\mathcal P})$
holds.
Proof. We prove (2). (1) can be shown by a subset of this proof.
Assume that
$\kappa $
is a
${\mathcal P}$
-Laver-gen. supercompact cardinal, and let
${\mathcal P}$
,
${\mathcal {D}}$
,
${\mathcal S}$
be as in the definition of
$\textsf {FA}^{+{<}\,\kappa }_{{<}\,\kappa }({\mathcal P})$
. Let
$D_\alpha $
,
$\alpha <\mu $
and 
,
$\alpha <\mu '$
be enumerations of
${\mathcal {D}}$
and
${\mathcal S,}$
respectively.
Let
$\lambda =\mathopen {|\,}{\mathbb {P}}\mathclose {\,|}$
. Without loss of generality, we may assume that
$\lambda>\kappa $
and the underlying set of
${\mathbb {P}}$
is
$\lambda $
. Let 
be a
${\mathbb {P}}$
-name with 
and such that for any 
-generic
$\mathbb {H}$
, there are j,
$M\subseteq \mathsf {V}[{\mathbb {G}}]$
such that
$j:\mathsf {V}\stackrel {\prec \hspace {0.8ex}}{\rightarrow }_{\kappa }M$
,
$j(\kappa )>\lambda $
,
$j{}^{\,{\prime }{\prime }}{\lambda }$
,
${\mathbb {P}}$
, 
,
$\mathbb {H}\in M$
.
Let
${\mathbb {G}}$
be the
${\mathbb {P}}$
part of
$\mathbb {H}$
. Then, since
$j(\mu )=\mu $
,
$j(\mu ')=\mu '$
,
$j({\mathcal {D}})=\{j(D_\alpha )\,:\,\alpha <\mu \}$
, and 
, we have
-
(5.1)
$M\models \!{"\,}\, \begin {array}[t]{@{}l} j{}^{\,{\prime }{\prime }}{{\mathbb {G}}}\text { generates a filter on }j({\mathbb {P}})\text { which is}\\ j({\mathcal {D}})\text {-generic, and realizes elements of }j({\mathcal S})\text { to be stationary}\text{"}. \end {array}$
Note that we need here the condition that
${\mathcal P}$
is stationary preserving since otherwise the stationary set 
in
$\mathsf {V}[{\mathbb {G}}]$
might be no more stationary in
$\mathsf {V}[\mathbb {H}]$
.
(5.1) implies that
-
$M\models \!{"\,}\, \begin {array}[t]{@{}l} \text {there is a }j({\mathcal {D}})\text {-generic filter on }j({\mathbb {P}})\\ \text {which realizes all elements of }j({\mathcal S})\text { to be stationary}\text{"}. \end {array}$
By elementarity, it follows that
-
$\mathsf {V}\models \!{"\,}\, \begin {array}[t]{@{}l} \text {there is a }{\mathcal {D}}\text {-generic filter on }{\mathbb {P}}\\ \text {which realizes all elements of }{\mathcal S}\text { to be stationary}\text{"}. \end {array}$
Lemma 5.6. Suppose that
$\kappa $
is
${\mathcal P}$
-Laver-gen. supercompact for an iterable
${\mathcal P}$
. Then we have
${\mathcal {H}}(\kappa )^{\mathsf {V}}\prec _{\Sigma _1}{\mathcal {H}}((\kappa ^{(+)})^{\mathsf {V}[{\mathbb {G}}]})^{\mathsf {V}[{\mathbb {G}}]}$
for any
${\mathbb {P}}\in {\mathcal P}$
and
$(\mathsf {V},{\mathbb {P}})$
-generic
${\mathbb {G}}$
.
The following theorem improves Corollary 5.4.
Theorem 5.7. For an iterable class
${\mathcal P}$
of posets, suppose that
$\textsf {BFA}_{{<}\,\kappa }({\mathcal P})$
holds, and
$\kappa $
is tightly
${\mathcal P}$
-Laver-gen. huge.Footnote
12
Then, for any
${\mathbb {P}}\in {\mathcal P}$
such that
$\,\|\hspace {-.35ex}\textsf {--}_{\,{\mathbb {P}}\,}{"}\,\textsf {BFA}_{{<}\,\kappa }({\mathcal P})\text{"}$
,
-
${\mathcal {H}}(\mu ^+)^{\mathsf {V}}\prec _{\Sigma _2}{\mathcal {H}}(\mu ^+)^{\mathsf {V}[{\mathbb {G}}]}$
holds for all
$\mu <\kappa $
and for
$(\mathsf {V},{\mathbb {P}})$
-generic
${\mathbb {G}}$
.
Thus, we have
${\mathcal {H}}(\kappa )^{\mathsf {V}}\prec _{\Sigma _2}{\mathcal {H}}((\kappa ^{(+)})^{\mathsf {V}[{\mathbb {G}}]})^{\mathsf {V}[{\mathbb {G}}]}$
.
Proof. Suppose that
$\,\|\hspace {-.35ex}\textsf {--}_{\,{\mathbb {P}}\,}{"}\,{\mathcal {H}}(\mu ^+)\models \varphi (\overline {a})\text{"}$
for
${\mathbb {P}}\in {\mathcal P}$
with
$\,\|\hspace {-.35ex}\textsf {--}_{\,{\mathbb {P}}\,}{"}\,\textsf {BFA}_{{<}\,\kappa }({\mathcal P})\text{"}$
,
$\mu <\kappa $
,
$\Sigma _2$
-formula
$\varphi $
and for
$\overline {a}\in {\mathcal {H}}(\mu ^+)$
. Let
${\mathbb {G}}$
be a
$(\mathsf {V},{\mathbb {P}})$
-generic filter. Then we have
-
(5.2)
$\mathsf {V}[{\mathbb {G}}]\models \!{"\,}\textsf {BFA}_{{<}\,\kappa }({\mathcal P})\land {\mathcal {H}}(\mu ^+)\models \varphi (\overline {a})\text{"}$
.
Let
$\varphi =\exists y\psi (\overline {x},y)$
where
$\psi $
is a
$\Pi _1$
-formula in
${{\mathcal L}}_{\in }$
. Let
$b\in {\mathcal {H}}((\mu ^+)^{\mathsf {V}[{\mathbb {G}}]})^{\mathsf {V}[{\mathbb {G}}]}$
be such that
${\mathcal {H}}((\mu ^+)^{\mathsf {V}[{\mathbb {G}}]})^{\mathsf {V}[{\mathbb {G}}]}\models \psi (\overline {a},b)$
.
Let 
be a
${\mathbb {P}}$
-name with 
such that, for 
-generic
$\mathbb {H}$
with
-
(5.3)
${\mathbb {G}}\subseteq \mathbb {H}$
(under the identification ),
),there are j,
$M\subseteq \mathsf {V}[\mathbb {H}]$
such that
$j:\mathsf {V}\stackrel {\prec \hspace {0.8ex}}{\rightarrow }_{\kappa }M$
,
-
(5.4)
(by tightness), -
(5.5)
${\mathbb {P}}$
, ,
$\mathbb {H}\in M,$
and -
(5.6)
$j{}^{\,{\prime }{\prime }}{j(\kappa )}\in M$
.
(by tightness),
, 
By (5.2), (5.3), and Bagaria’s Absoluteness Theorem 1.2 (applied to
$V[{\mathbb {G}}]$
), we have
$\mathsf {V}[\mathbb {H}]\models \!{"\,}\psi (\overline {a},b)\text{"}$
and hence
$\mathsf {V}[\mathbb {H}]\models \!{"\,}{\mathcal {H}}(\mu ^+)\models \psi (\overline {a},b)\text{"}$
.
By (5.4), and (5.6), there is a
${\mathbb {P}}$
-name of b in M. By (5.5), it follows that
$b\in M$
. By similar argument, we have
${\mathcal {H}}((\mu ^+)^{\mathsf {V}[\mathbb {H}]})^{\mathsf {V}[\mathbb {H}]}\subseteq M$
and hence
${\mathcal {H}}((\mu ^+)^{\mathsf {V}[\mathbb {H}]})^{\mathsf {V}[\mathbb {H}]}={\mathcal {H}}((\mu ^+)^M)^M\in M$
. Thus we have
$M\models \!{"\,}{\mathcal {H}}(\mu ^+)\models \psi (\overline {a},b)\text{"}$
.
By elementarity, it follows that
$\mathsf {V}\models \!{"\,}(\exists \underline {b}\in {\mathcal {H}}(\mu ^+))\ {\mathcal {H}}(\mu ^+)\models \psi (\overline {a},\underline {b})\text{"}$
, and hence
$\mathsf {V}\models \!{"\,}{\mathcal {H}}(\mu ^+)\models \varphi (\overline {a})\text{"}$
as desired.
Suppose now that
${\mathbb {P}}$
,
$\mu $
,
$\varphi $
,
$\overline {a}$
are as above and assume that
$\mathsf {V}\models \!{"\,}{\mathcal {H}}(\mu ^+)\models \varphi (\overline {a})\text{"}$
holds. For a
$\Pi _1$
-formula
$\psi $
as above, let
$b\in {\mathcal {H}}(\mu ^+)^{\mathsf {V}}$
be such that
$V\models \!{"\,}{\mathcal {H}}(\mu ^+)\models \psi (\overline {a},b)\text{"}$
.
Since
$\mathsf {V}\models \textsf {BFA}_{{<}\,\kappa }({\mathcal P})$
by assumption, it follows that
$\mathsf {V}[{\mathbb {G}}]\models \psi (\overline {a},b)$
by Bagaria’s Absoluteness Theorem 1.2, and hence
$\mathsf {V}[{\mathbb {G}}]\models \!{"\,}{\mathcal {H}}(\mu ^+)\models \varphi (\overline {a})\text{"}$
.
The last assertion of the theorem follows by the same argument as that given at the end of the proof of Theorem 4.1.
6. Some more remarks and open questions
In this final section we collect some observations we could not put in the appropriate places in previous sections, and mention some open questions.
Since most of the claims in this section are easy consequences of known results, some of them may be already known.
6.1. Restricted Recurrence Axioms under Laver-genericity
As we already mentioned at the end of Section 2, the existence of a tightly
${\mathcal P}$
-Laver gen. ultrahuge cardinal
$\kappa $
implies
$({\mathcal P},{\mathcal {H}}(\kappa ))_{\Sigma _2}$
-RcA
$^+$
([Reference Fuchino11, Theorem 21]). This result can be slightly improved so that its conclusion stands in line with the assumptions of Theorem 4.1 for the case of
$n=2$
.
Theorem 6.1 (A slightly improved version of Theorem 21 in Fuchino [Reference Fuchino11]).
Suppose that
$\kappa $
is tightly
${\mathcal P}$
-Laver-generically ultrahuge for an iterable class
${\mathcal P}$
of posets. Then
$({\mathcal P},{\mathcal {H}}(\kappa ))_{\Gamma }$
-RcA
$^+$
holds where
$\Gamma $
is the set of all formulas which are conjunctions of a
$\Sigma _2$
-formula and a
$\Pi _2$
-formula.
Proof. A slight modification of the proof given in [Reference Fuchino11] will do. Nevertheless, we present the proof here because of the subtlety of the modification of the proof around (6.8) below.
Assume that
$\kappa $
is tightly
${\mathcal P}$
-Laver generically ultrahuge for an iterable class
${\mathcal P}$
of posets.
Suppose that
$\varphi =\varphi (\overline {x})$
is
$\Sigma _2$
formula (in
${{\mathcal L}}_{\in }$
),
$\psi =\psi (\overline {x})$
is
$\Pi _2$
formula (in
${{\mathcal L}}_{\in }$
),
$\overline {a}\in {\mathcal {H}}(\kappa )$
, and
${\mathbb {P}}\in {\mathcal P}$
is such that
-
(6.1)
$\mathsf {V}\models \,\|\hspace {-.35ex}\textsf {--}_{\,{\mathbb {P}}\,}{"}\,\varphi (\overline {a})\land \psi (\overline {a})\text{"}$
.
Let
$\lambda>\kappa $
be such that
${\mathbb {P}}\in \mathsf {V}_\lambda $
and
-
(6.2)
$V_\lambda \prec ^{}_{\Sigma _n}\mathsf {V}\text { for a sufficiently large }n$
.
In particular, we may assume that we have chosen the n above so that a sufficiently large fragment of ZFC holds in
$V_\lambda $
(“sufficiently large” means here, in particular, in terms of Lemma 3.7, (1) and that the argument at the end of this proof is possible).
Let 
be a
${\mathbb {P}}$
-name such that 
, and for 
-generic
$\mathbb {H}$
, there are j,
$M\subseteq \mathsf {V}[\mathbb {H}]$
with
-
(6.3)
$j:\mathsf {V}\stackrel {\prec \hspace {0.8ex}}{\rightarrow }_{\kappa }M$
,
-
(6.4)
$j(\kappa )>\lambda $
,
-
(6.5)
-
(6.6)
.
.By (6.6), we may assume that the underlying set of 
is
$j(\kappa )$
and 
.
Let
${\mathbb {G}}:=\mathbb {H}\cap {\mathbb {P}}$
. Note that
${\mathbb {G}}\in M$
by (6.5). We have
-
(6.7)
Thus, by (6.5) and by the definability of grounds, we have
${V_{j(\lambda )}}^{\mathsf {V}}\in M$
and
${V_{j(\lambda )}}^{\mathsf {V}}[{\mathbb {G}}]\in M$
. We may assume that
$V_{j(\lambda )}^{\mathsf {V}}$
as a ground of
$V_{j(\lambda )}^M$
satisfies a large enough fragment of ZFC.
Claim 6.1.1.
${V_{j(\lambda )}}^{\mathsf {V}}[{\mathbb {G}}]\models \varphi (\overline {a})\land \psi (\overline {a})$
.
$\vdash $
By Lemma 3.7, (1),
${V_\lambda }^{\mathsf {V}}[{\mathbb {G}}]={V_\lambda }^{\mathsf {V}[{\mathbb {G}}]}$
, and
${V_{j(\lambda )}}^{\mathsf {V}}[{\mathbb {G}}]={V_{j(\lambda )}}^{\mathsf {V}[{\mathbb {G}}]}$
. By (6.2), both
${V_\lambda }^{\mathsf {V}}[{\mathbb {G}}]$
and
$V_{j(\lambda )}^{\mathsf {V}}[{\mathbb {G}}]$
satisfy still large enough fragment of ZFC. Thus, by Lemma 6.2 below, it follows that
-
(6.8)
${V_\lambda }^{\mathsf {V}}[{\mathbb {G}}]\prec _{\Sigma _1}{V_{j(\lambda )}}^{\mathsf {V}}[{\mathbb {G}}]\prec _{\Sigma _1}V[{\mathbb {G}}]$
.
By (6.1) and (6.2), we have
${V_\lambda }^{\mathsf {V}}[{\mathbb {G}}]\models \varphi (\overline {a})$
and
$\mathsf {V}[{\mathbb {G}}]\models \psi (\overline {a})$
. By (6.8) and since
$\varphi $
is
$\Sigma _2$
, and
$\psi $
is
$\Pi _2$
, it follows that
${V_{j(\lambda )}}^{\mathsf {V}}[{\mathbb {G}}]\models \varphi (\overline {a})\land \psi (\overline {a})$
.
$\dashv $
Thus we have
-
(6.9)
$M\models \!{"\,}\text {there is a } {\mathcal P}\text {-ground }N\text { of }V_{j(\lambda )}\text { with }N\models \varphi (\overline {a})\land \psi (\overline {a})\text{"}$
.
By the elementarity (6.3), it follows that
-
(6.10)
$\mathsf {V}\models \!{"\,}\text {there is a } {\mathcal P}\text {-ground }N\text { of }V_{\lambda }\text { with }N\models \varphi (\overline {a})\land \psi (\overline {a})\text{"}$
.
Now by (6.2), it follows that there is a
${\mathcal P}$
-ground
$\mathsf {W}$
of
$\mathsf {V}$
such that
$\mathsf {W}\models \varphi (\overline {a})\land \psi (\overline {a})$
.
We used the following variation of (1.4) in the proof of Theorem 6.1 to obtain (6.8).
Lemma 6.2. Suppose that
$\delta $
,
$\delta '\in \text {On}$
,
$\delta <\delta '$
and both
$V_\delta $
and
$V_{\delta '}$
satisfy a sufficiently large fragment of ZFC. Then we have
$V_\delta \prec _{\Sigma _1}V_{\delta '}\prec _{\Sigma _1}\mathsf {V}$
.
Proof. Suppose that
$\overline {a}\in V_\delta $
and
$\psi (\overline {x},\overline {y})$
is a bounded formula in
${{\mathcal L}}_{\in }$
.
If
$V_\delta \models \exists \overline {y}\psi (\overline {a},\overline {y})$
, then there are
$\overline {b}\in V_\delta $
such that
$V_\delta \models \psi (\overline {a},\overline {b})$
. It follows that
$V_{\delta '}\models \psi (\overline {a},\overline {b})$
and hence
$V_{\delta '}\models \exists \overline {y}\psi (\overline {a},\overline {y})$
.
Suppose now that
$V_{\delta '}\models \exists \overline {y}\psi (\overline {a},\overline {y})$
. Since
$V_{\delta '}$
satisfies a sufficiently large fragment of ZFC, there is
$M\in V_{\delta '}$
such that
But then such M as above must be an element of
$V_\delta $
and thus
It follows that
$V_\delta \models \exists \overline {y}\,\psi (\overline {a},\overline {y})$
.
The argument above shows that
$V_\delta \prec _{\Sigma _1}V_{\delta '}$
.
$V_{\delta '}\prec _{\Sigma _1}\mathsf {V}$
can be shown with practically the same argument.
6.2. Separation of some other axioms and assertions
In Section 3, we separated some instances of
$({\mathcal P},{\mathcal {H}}(\kappa ))_\Gamma $
-RcA and
$\textsf {MP}({\mathcal P},{\mathcal {H}}(\kappa ))_\Gamma $
by compatibility with the GA. The same idea can be also used to separate some other principles and axioms.
Theorem 6.3. “
$\textsf {MM}^{++} +$
there are class many supercompact cardinals” (or even class many extendible cardinals) is consistent with GA.
Proof. Sean Cox [Reference Cox7] proved that
$\textsf {MM}^{++}$
is preserved by
$\omega _2$
-directed closed forcing ([Reference Cox7,Theorem 4.7]). Starting from a model with cofinally many supercompact cardinals, use the first supercompact to force
$\textsf {MM}^{++}$
. Then the class forcing just like that in the proof of Theorem 3.8 (or like the one in [Reference Goldberg17]) will produce a desired model.
Corollary 6.4.
$\textsf {MM}^{++}$
or even
$\textsf {MM}^{++} +$
“there are class many super compact cardinals” does not imply that the continuum is a tightly
${\mathcal P}$
-Laver gen. ultrahuge cardinal for any of the large enough subclass
${\mathcal P}$
of the class of all semiproper posets.
Proof. Let
${\mathcal P}=$
semiproper posets. Note that, if
$\kappa $
is
${\mathcal P}$
-Laver generically supercompact, then
$\kappa =2^{\aleph _0}$
follows (see, e.g., Fuchino [Reference Fuchino11, Theorem 5 and Lemma 6]).
If
$\kappa $
is the tightly
${\mathcal P}$
-Laver generically ultrahuge continuum, then Theorem 6.1 together with each one of the Propositions 2.7, 2.8, and 2.10 implies that GA does not hold. Thus the model of
$\textsf {MM}^{++} +$
“there are class many super compact cardinals”
$+$
GA of Theorem 6.3 witnesses the desired non-implication.
Note that Corollary 6.4 with “tightly
${\mathcal P}$
-Laver gen. ultrahuge” replaced by “tightly
${\mathcal P}$
-Laver gen. hyperhuge” is trivial. This is because consistency strength of the existence of the tightly
${\mathcal P}$
-Laver gen. hyperhuge cardinal is known to be that of the existence of a (genuinely) hyperhuge cardinal (see the remark right after Proposition 2.11).
Our Theorems 4.1 and 5.7 generalize Viale’s Theorem 1.1 in terms of possible instances of the class
${\mathcal P}$
not covered by Theorem 1.1 and also in terms of the cardinal
$\kappa $
in the conclusion of the theorems which can be strictly bigger than
$\aleph _2$
(which can really happen if e.g.,
${\mathcal P}$
is the class of ccc posets).
On the other hand, the premise of Viale’s Theorem 1.1 is consistent with GA by Theorem 6.3 while this is not the case with Theorem 4.1 for many natural instances of
${\mathcal P}$
by Propositions 2.7, 2.8, and 2.10 and unclear in case of
${\mathcal P}=$
stationary preserving posets with Theorem 5.7.
Viale’s Theorem 1.1 in particular, implies the following.
Corollary 6.5 (to Viale’s Theorems 1.1 and 6.3).
The assertion
-
${\mathcal {H}}(\aleph _2)^{\mathsf {V}}\prec _{\Sigma _2}{\mathcal {H}}(\aleph _2)^{\mathsf {V}[{\mathbb {G}}]}$
for any stationary preserving poset
${\mathbb {P}}$
with
$\,\|\hspace {-.35ex}\textsf {--}_{\,{\mathbb {P}}\,}{"}\,\textsf {BMM}\text{"}$
, and
$(\mathsf {V},{\mathbb {P}})$
-generic
${\mathbb {G}}$
.
is consistent with GA.
Concerning Theorem 5.7, it is open at the moment if the existence of a tightly
${\mathcal P}$
-Laver-gen. huge cardinal is inconsistent with GA. However some of its strengthenings do contradict GA for many instances of the class
${\mathcal P}$
of posets as we saw in Proposition 2.13 and Theorem 2.14.
The positive answer to the following question would give a clear separation of Laver-genericity from the corresponding forcing axiom with double plus.
Problem 6.6. Does the (tightly)
${\mathcal P}$
-Laver gen. supercompact cardinal axiom (i.e., the existential statement of such a cardinal, e.g. for
${\mathcal P}$
as in Corollary 3.12) imply the negation of GA?
Though Corollary 6.4 makes the positive answer to the following problem rather unpromising, Theorem 2.53 of Woodin [Reference Woodin33] and its variants (e.g., [Reference Cox7, Theorem 4.5]) seem to suggest a positive answer.
Problem 6.7. Is there any reasonable assumption under which
$\textsf {MM}^{++}$
and (tightly)
${\mathcal P}$
-Laver gen. supercompact cardinal axiom are equivalent?
Acknowledgments
The authors would like to thank Gabriel Goldberg, Daisuke Ikegami, and Hiroshi Sakai for helpful remarks and comments. The authors also would like to thank Andreas Lietz for pointing out a flaw in the proof of an earlier version of Theorem 3.8. A part of the statement of the original version of this theorem is now recovered in Theorem 3.10 and in the subsequent remark. They would like to thank as well the anonymous referee for pointing out numerous slips.
Funding statement
The research of the first author was supported by Kakenhi Grant-in-Aid for Scientific Research (C) 20K03717. For the second author, this research was funded in whole, or in part, by the Austrian Science Fund (FWF) (Grant No. I6087). The third author is an International Research Fellow of the Japan Society for the Promotion of Science.
may be anything.
Open access
