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<!--
<P><I>Intuitionistic Logic</I> (<A
HREF="https://en.wikipedia.org/wiki/Intuitionistic_logic">Wikipedia</A>
[accessed 19-Jul-2015], <A
HREF="http://plato.stanford.edu/entries/logic-intuitionistic/"> Stanford
Encyclopedia of Philosophy</A> [accessed 19-Jul-2015]) is a logic weaker
than classical logic that can be thought of as a weakening of classical
logic such that the law of excluded middle, (<FONT
COLOR="#0000FF"><I>&phi;</I></FONT> <FONT FACE=sans-serif> &or;</FONT>
&not; <FONT COLOR="#0000FF"><I>&phi;</I></FONT>), doesn't always hold.
Specifically, it holds if we have a proof for <FONT
COLOR="#0000FF"><I>&phi;</I></FONT> or we have a proof for &not; <FONT
COLOR="#0000FF"><I>&phi;</I></FONT>, but it doesn't necessarily hold if
we don't have a proof of either one.  Intuitionistic logic can be
thought of as a constructive logic in which we must build and exhibit
concrete examples of objects before we can accept their existence.  A
proof by contradiction, where denial of an assertion to be proved leads
to asserting a falsehood, will generally not be valid in intuitionistic
logic.
-->

<!-- the above was replaced by David A. Wheeler: -->

<P><I>Intuitionistic Logic</I> (<A
HREF="https://en.wikipedia.org/wiki/Intuitionistic_logic">Wikipedia</A>
[accessed 19-Jul-2015], <A
HREF="http://plato.stanford.edu/entries/logic-intuitionistic/"> Stanford
Encyclopedia of Philosophy</A> [accessed 19-Jul-2015]) can be
thought of as a constructive logic in which we must build and exhibit
concrete examples of objects before we can accept their existence.
Unproved statements in intuitionistic logic are not given an intermediate truth value,
instead, they remain of unknown truth value until they are either proved or disproved.
Intuitionist logic can also be thought of as a weakening of classical
logic such that the law of excluded middle (LEM), (<FONT
COLOR="#0000FF"><I>&phi;</I></FONT> <FONT FACE=sans-serif> &or;</FONT>
&not; <FONT COLOR="#0000FF"><I>&phi;</I></FONT>), doesn't always hold.
Specifically, it holds if we have a proof for <FONT
COLOR="#0000FF"><I>&phi;</I></FONT> or we have a proof for &not; <FONT
COLOR="#0000FF"><I>&phi;</I></FONT>, but it doesn't necessarily hold if
we don't have a proof of either one.
There is also no rule for double negation elimination.
Brouwer observed in 1908 that LEM was abstracted from finite situations,
then extended without justification to statements about infinite collections.

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<B><FONT COLOR="#006633">Contents of this page</FONT></B>
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  <LI> <A HREF="#overview">Overview of intuitionistic logic</A></LI>
  <LI> <A HREF="#overview2">Overview of this work</A></LI>
  <LI> <A HREF="#axioms">The axioms</A></LI>
  <LI> <A HREF="#theorems">Some theorems</A></LI>
  <LI> <A HREF="#intuitionize">How to intuitionize classical proofs</A></LI>
  <LI> <A HREF="#setmm">Metamath Proof Explorer cross reference</A></LI>
  <LI> <A HREF="#bib">Bibliography</A></LI>
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<B><FONT COLOR="#006633">Related pages</FONT></B>

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<LI> <A HREF="mmtheorems.html">Table of Contents and Theorem List</A></LI>

<LI>
 <A HREF="mmrecent.html">Most Recent Proofs
 (this mirror)</A>
  (<A HREF="http://us2.metamath.org:88/ileuni/mmrecent.html">latest</A>)
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<LI> <A HREF="mmbiblio.html">Bibliographic Cross-Reference</A></LI>
<LI> <A HREF="mmdefinitions.html">Definition List</A></LI>
<LI> <A HREF="mmascii.html">ASCII Equivalents for Text-Only Browsers</A></LI>
<LI>
<A HREF="../metamath/iset.mm">Metamath database iset.mm (ASCII file)</A>
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<B><FONT COLOR="#006633">External links</FONT></B>
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<LI>
<A HREF=" https://github.com/metamath/set.mm">GitHub repository</A>
[accessed 06-Jan-2018]
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<HR NOSHADE SIZE=1><A NAME="overview"></A><B><FONT COLOR="#006633">
Overview of intuitionistic logic</FONT></B>

<P>(Placeholder for future use)


<HR NOSHADE SIZE=1><A NAME="overview2"></A><B><FONT COLOR="#006633">
Overview of this work</FONT></B>

<P>(By G&eacute;rard Lang, 7-May-2018)

<P>Mario Carneiro's work (Metamath database) "iset.mm" provides in Metamath a
development of "set.mm" whose eventual
aim is to show how many of the theorems of set theory and
mathematics that can be derived from classical first order logic can
also be derived from a weaker system called "intuitionistic logic."  To
achieve this task, iset.mm adds (or substitutes) intuitionistic
axioms for a number of the classical logical axioms of set.mm.

<P>Among these new axioms, the first six
( ~ ax-ia1 ,
~ ax-ia2 ,
~ ax-ia3 ,
~ ax-io ,
~ ax-in1 ,
and
~ ax-in2 ), when added to
~ ax-1 ,
~ ax-2 ,
and
~ ax-mp ,
allow for the development of intuitionistic propositional logic.
We omit the classical axiom
<SPAN CLASS=math>((&not;
<SPAN CLASS=wff STYLE="color:blue">&#x1D711;</SPAN> &rarr; &not; <SPAN
CLASS=wff STYLE="color:blue">&#x1D713;</SPAN>) &rarr; (<SPAN CLASS=wff
STYLE="color:blue">&#x1D713;</SPAN> &rarr; <SPAN CLASS=wff
STYLE="color:blue">&#x1D711;</SPAN>))</SPAN> (which is ax-3 in
set.mm).  Each of our new axioms is a theorem of classical
propositional logic, but ax-3 cannot be derived from them.  Similarly,
other basic classical theorems, like the third middle excluded or the
equivalence of a proposition with its double negation, cannot be derived
in intuitionistic propositional calculus.  Glivenko showed that a
proposition <FONT COLOR="#0000FF"><I>&phi;</I></FONT>
 is a theorem of classical propositional calculus if and only
if &not;&not;<FONT COLOR="#0000FF"><I>&phi;</I></FONT>
 is a theorem of intuitionistic propositional calculus.

<P>The next 4 new axioms
( ~ ax-ial ,
~ ax-i5r ,
~ ax-ie1 ,
and
~ ax-ie2 )
together with the set.mm axioms
~ ax-4 ,
~ ax-5 ,
~ ax-7 ,
and
~ ax-gen
do not mention equality or distinct variables.

<P>The ~ ax-i9 axiom is just a slight variation of the classical ~ ax-9 .
The classical axiom ~ ax-12 is strengthened into first ~ ax-i12 and then
~ ax-bndl (two results which would be fairly readily equivalent to ~ ax-12
classically but which do not follow from ~ ax-12 , at least not in an obvious
way, in intuitionistic logic).

The substitution of ~ ax-i9 , ~ ax-i12 , and ~ ax-bndl for ~ ax-9 and ~ ax-12
and the inclusion of
~ ax-8 ,
~ ax-10 ,
~ ax-11 ,
~ ax-13 ,
~ ax-14 ,
and
~ ax-17
allow for the development of the intuitionistic predicate calculus.

<P>Each of the new axioms is a theorem of classical first order
logic with equality.  But some axioms of classical first order logic
with equality, like ax-3, cannot be derived in the intuitionistic
predicate calculus.</P>

<P>One of the major interests of the intuitionistic predicate calculus
is that its use can be considered as a realization of the program of the
constructivist philosophical view of mathematics.


<HR NOSHADE SIZE=1><A NAME="axioms"></A><B><FONT COLOR="#006633">
The axioms</FONT></B>

<P>As with the <A HREF="mmset.html#axioms">classical axioms</A>
we have propositional logic and predicate logic.

<P>The axioms of intuitionistic propositional logic consist of some of the axioms from
classical propositional logic, plus additional axioms for the operation of the 'and',
'or' and 'not' connectives.

<CENTER>
<TABLE BORDER CELLSPACING=0 BGCOLOR="#EEFFFA"
SUMMARY="Axioms of intuitionistic propositional calculus">
<CAPTION><B>Axioms of intuitionistic propositional calculus</B></CAPTION>

<TR ALIGN=LEFT><TD> <A HREF="ax-1.html"> Axiom <I>Simp</I></A></TD>
<TD><FONT COLOR="#006633"><B>ax-1</B></FONT></TD>
<TD><FONT COLOR="#808080" FACE=sans-serif>&#8866; </FONT>(<FONT
COLOR="#0000FF"><I>&phi;</I></FONT> &rarr; (<FONT
COLOR="#0000FF"><I>&psi;</I></FONT> &rarr; <FONT
COLOR="#0000FF"><I>&phi;</I></FONT>))</TD>
</TR>

<TR ALIGN=LEFT><TD><A HREF="ax-2.html">Axiom <I>Frege</I></A></TD> <TD
NOWRAP><FONT COLOR="#006633"><B>ax-2</B></FONT></TD>
<TD>
<FONT COLOR="#808080" FACE=sans-serif>&#8866; </FONT>((<FONT
COLOR="#0000FF"><I>&phi;</I></FONT> &rarr; (<FONT
COLOR="#0000FF"><I>&psi;</I></FONT> &rarr; <FONT
COLOR="#0000FF"><I>&chi;</I></FONT>)) &rarr; ((<FONT
COLOR="#0000FF"><I>&phi;</I></FONT> &rarr; <FONT
COLOR="#0000FF"><I>&psi;</I></FONT>) &rarr; (<FONT
COLOR="#0000FF"><I>&phi;</I></FONT> &rarr; <FONT
COLOR="#0000FF"><I>&chi;</I></FONT>)))</TD>
</TR>

<TR ALIGN=LEFT><TD><A
HREF="ax-mp.html">Rule of Modus Ponens</A></TD> <TD NOWRAP><FONT
COLOR="#006633"><B>ax-mp</B></FONT></TD>
<TD>` |- ph `  &nbsp;&nbsp;&amp; &nbsp;
` |- ph -> ps `  &nbsp; &#x21D2; &nbsp; ` |- ps `</TD>
</TR>

<TR ALIGN=LEFT><TD><A
HREF="ax-ia1.html">Left 'and' elimination</A></TD><TD><FONT
COLOR="#006633"><B>ax-ia1</B></FONT></TD><TD>
` |- ( ( ph /\ ps ) -> ph ) `</TD></TR>

<TR ALIGN=LEFT><TD><A
HREF="ax-ia2.html">Right 'and' elimination</A></TD><TD><FONT
COLOR="#006633"><B>ax-ia2</B></FONT></TD><TD>
<FONT COLOR="#808080" FACE="sans-serif">&#8866; </FONT>((<FONT COLOR="#0000FF"><I>&phi;</I></FONT>
<FONT FACE="sans-serif">&and;</FONT> <FONT COLOR="#0000FF"><I>&psi;</I></FONT>) &rarr;
<FONT COLOR="#0000FF"><I>&psi;</I></FONT>)</TD></TR>

<TR ALIGN=LEFT><TD><A
HREF="ax-ia3.html">'And' introduction</A></TD><TD><FONT
COLOR="#006633"><B>ax-ia3</B></FONT></TD><TD>
<FONT COLOR="#808080" FACE="sans-serif">&#8866; </FONT>(<FONT COLOR="#0000FF"><I>&phi;</I></FONT>
&rarr; (<FONT COLOR="#0000FF"><I>&psi;</I></FONT> &rarr; (<FONT COLOR="#0000FF"><I>&phi;</I></FONT>
<FONT FACE="sans-serif">&and;</FONT> <FONT COLOR="#0000FF"><I>&psi;</I></FONT>)))</TD></TR>

<TR ALIGN="LEFT"><TD><A
HREF="ax-io.html">Definition of 'or'</A></TD><TD><FONT COLOR="#006633"><B>ax-io</B></FONT></TD><TD>
<FONT COLOR="#808080" FACE="sans-serif">&#8866; </FONT>(((<FONT COLOR="#0000FF"><I>&phi;</I></FONT>
<FONT FACE="sans-serif"> &or;</FONT> <FONT COLOR="#0000FF"><I>&chi;</I></FONT>)
&rarr; <FONT COLOR="#0000FF"><I>&psi;</I></FONT>)
&#x2194; ((<FONT COLOR="#0000FF"><I>&phi;</I></FONT> &rarr;
<FONT COLOR="#0000FF"><I>&psi;</I></FONT>) <FONT FACE="sans-serif">&and;</FONT>
(<FONT COLOR="#0000FF"><I>&chi;</I></FONT> &rarr; <FONT COLOR="#0000FF"><I>&psi;</I></FONT>)))

<TR ALIGN="LEFT"><TD><A
HREF="ax-in1.html">'Not' introduction</A></TD><TD><FONT COLOR="#006633"><b>ax-in1</B></FONT></TD><TD>
<FONT COLOR="#808080" FACE="sans-serif">&#8866;
</FONT>((<FONT COLOR="#0000FF"><I>&phi;</I></FONT> &rarr; &not; <FONT COLOR="#0000FF"><I>&phi;</I></FONT>)
&rarr; &not; <FONT COLOR="#0000FF"><I>&phi;</I></FONT>)</TD></TR>

<TR ALIGN="LEFT"><TD><A
HREF="ax-in2.html">'Not' elimination</A></TD><TD><FONT COLOR="#006633"><B>ax-in2</B></FONT></TD><TD>
<FONT COLOR="#808080" FACE="sans-serif">&#8866; </FONT>(&not; <FONT COLOR="#0000FF"><I>&phi;</I></FONT>
&rarr; (<FONT COLOR="#0000FF"><I>&phi;</I></FONT> &rarr; <FONT COLOR="#0000FF"><I>&psi;</I></FONT>))</TD></TR>

</TABLE>

</CENTER>

<P>Unlike in classical propositional logic, 'and' and 'or' are not readily defined in terms of
implication and 'not'. In particular, <FONT COLOR="#0000FF"><I>&phi;</I></FONT> &or;
<FONT COLOR="#0000FF"><I>&psi;</I></FONT> is not equivalent to &not; <FONT COLOR="#0000FF"><I>&phi;</I></FONT> &rarr;
<FONT COLOR="#0000FF"><I>&psi;</I></FONT>,
nor is <FONT COLOR="#0000FF"><I>&phi;</I></FONT> &rarr;
<FONT COLOR="#0000FF"><I>&psi;</I></FONT> equivalent to &not; <FONT COLOR="#0000FF"><I>&phi;</I></FONT> &or;
<FONT COLOR="#0000FF"><I>&psi;</I></FONT>, nor is <FONT COLOR="#0000FF"><I>&phi;</I></FONT> &and;
<FONT COLOR="#0000FF"><I>&psi;</I></FONT> equivalent to &not; (<FONT COLOR="#0000FF"><I>&phi;</I></FONT> &rarr; &not;
<FONT COLOR="#0000FF"><I>&psi;</I></FONT>).</P>

<P>The ax-in1 axiom is a form of proof by contradiction which does hold intuitionistically. That is, if
<FONT COLOR="#0000FF"><I>&phi;</I></FONT> implies a contradiction (such as its own negation),
then one can conclude &not; <FONT COLOR="#0000FF"><I>&phi;</I></FONT>. By contrast, assuming
&not; <FONT COLOR="#0000FF"><I>&phi;</I></FONT>
and then deriving a contradiction only serves to prove &not; &not; <FONT COLOR="#0000FF"><I>&phi;</I></FONT>,
which in intuitionistic logic is not the same as <FONT COLOR="#0000FF"><I>&phi;</I></FONT>.</P>

<P>The biconditional can be defined as the conjunction of two implications, as in
<A HREF="dfbi2.html">dfbi2</a> and <A HREF="df-bi.html">df-bi</a>.</P>

<P><A NAME="pcaxioms"></A><B><FONT COLOR="#006633">Predicate
logic</FONT></B> adds set variables (individual variables) and the ability to quantify
them with &#x2200; (for-all) and &#x2203; (there-exists). Unlike in classical logic, &#x2203;
cannot be defined in terms of &#x2200;. As in classical logic, we also add = for equality
(which is key to how we handle substitution in metamath) and &#x2208; (which for current
purposes can just be thought of as an arbitrary predicate, but which will later come to
mean set membership).</P>

<p>Our axioms are based on the classical set.mm predicate logic axioms, but adapted for
intuitionistic logic, chiefly by adding additional axioms for &#x2203; and also changing
some aspects of how we handle negations.</p>

<CENTER>
<TABLE BORDER CELLSPACING=0 BGCOLOR="#EEFFFA"
SUMMARY="Axioms of intuitionistic predicate logic">
<CAPTION><B>Axioms of intuitionistic predicate logic</B></CAPTION>

<TR ALIGN=LEFT><TD><A HREF="ax-4.html">Axiom of Specialization</A></TD>
<TD><FONT COLOR="#006633"><B>ax-4</B></FONT></TD><TD>
<SPAN ><FONT COLOR="#808080" FACE=sans-serif>&#8866; </FONT>(<FONT
FACE=sans-serif>&forall;</FONT><I><FONT COLOR="#FF0000">x</FONT></I><FONT
COLOR="#0000FF"><I>&phi;</I></FONT> &rarr; <FONT
COLOR="#0000FF"><I>&phi;</I></FONT>)</SPAN></TD></TR>

<TR ALIGN=LEFT><TD> <A HREF="ax-5.html">Axiom of Quantified Implication</A></TD>
<TD><FONT COLOR="#006633"><B>ax-5</B></FONT></TD><TD>
<SPAN ><FONT COLOR="#808080" FACE=sans-serif>&#8866; </FONT>(<FONT
FACE=sans-serif>&forall;</FONT><I><FONT COLOR="#FF0000">x</FONT></I>(<FONT
COLOR="#0000FF"><I>&phi;</I></FONT> &rarr; <FONT
COLOR="#0000FF"><I>&psi;</I></FONT>) &rarr; (<FONT
FACE=sans-serif>&forall;</FONT><I><FONT COLOR="#FF0000">x</FONT></I><FONT
COLOR="#0000FF"><I>&phi;</I></FONT> &rarr; <FONT
FACE=sans-serif>&forall;</FONT><I><FONT COLOR="#FF0000">x</FONT></I><FONT
COLOR="#0000FF"><I>&psi;</I></FONT>))</SPAN></TD></TR>

<TR ALIGN=LEFT><TD><A HREF="ax-i5r.html">The converse of ax-5o</A></TD>
<TD><FONT COLOR="#006633"><B>ax-i5r</B></FONT></TD><TD>
<SPAN ><FONT COLOR="#808080" FACE=sans-serif>&#8866; </FONT>((<FONT
FACE=sans-serif>&forall;</FONT><I><FONT COLOR="#FF0000">x</FONT></I><FONT
COLOR="#0000FF"><I>&phi;</I></FONT> &rarr; <FONT
FACE=sans-serif>&forall;</FONT><I><FONT COLOR="#FF0000">x</FONT></I><FONT
COLOR="#0000FF"><I>&psi;</I></FONT>) &rarr; <FONT
FACE=sans-serif>&forall;</FONT><I><FONT COLOR="#FF0000">x</FONT></I>(<FONT
FACE=sans-serif>&forall;</FONT><I><FONT COLOR="#FF0000">x</FONT></I><FONT
COLOR="#0000FF"><I>&phi;</I></FONT> &rarr; <FONT
COLOR="#0000FF"><I>&psi;</I></FONT>))</SPAN></TD></TR>

<TR ALIGN=LEFT><TD><A HREF="ax-7.html">Axiom of Quantifier Commutation</A></TD>
<TD><FONT COLOR="#006633"><B>ax-7</B></FONT></TD><TD>
<SPAN ><FONT COLOR="#808080" FACE=sans-serif>&#8866; </FONT>(<FONT
FACE=sans-serif>&forall;</FONT><I><FONT COLOR="#FF0000">x</FONT></I><FONT
FACE=sans-serif>&forall;</FONT><I><FONT COLOR="#FF0000">y</FONT></I><FONT
COLOR="#0000FF"><I>&phi;</I></FONT> &rarr; <FONT
FACE=sans-serif>&forall;</FONT><I><FONT COLOR="#FF0000">y</FONT></I><FONT
FACE=sans-serif>&forall;</FONT><I><FONT COLOR="#FF0000">x</FONT></I><FONT
COLOR="#0000FF"><I>&phi;</I></FONT>)</SPAN></TD></TR>

<TR ALIGN=LEFT><TD><A HREF="ax-gen.html">Rule of Generalization</A></TD>
<TD><FONT COLOR="#006633"><B>ax-gen</B></FONT></TD><TD>
<FONT COLOR="#808080" FACE=sans-serif>&#8866; </FONT><FONT
COLOR="#0000FF"><I>&phi;</I></FONT> &nbsp;&nbsp;=&gt; &nbsp;&nbsp;<SPAN >
<FONT COLOR="#808080" FACE=sans-serif>&#8866; </FONT><FONT
FACE=sans-serif>&forall;</FONT><I><FONT COLOR="#FF0000">x</FONT></I><FONT
COLOR="#0000FF"><I>&phi;</I></FONT></SPAN></TD></TR>

<TR ALIGN=LEFT><TD><A HREF="ax-ial.html"><SPAN ><I><FONT
COLOR="#FF0000">x</FONT></I></SPAN> is bound in <SPAN ><FONT
FACE=sans-serif>&forall;</FONT><I><FONT COLOR="#FF0000">x</FONT></I><FONT
COLOR="#0000FF"><I>&phi;</I></FONT></SPAN></A></TD>
<TD><FONT COLOR="#006633"><B>ax-ial</B></FONT></TD><TD>
<SPAN ><FONT COLOR="#808080" FACE=sans-serif>&#8866; </FONT>(<FONT
FACE=sans-serif>&forall;</FONT><I><FONT COLOR="#FF0000">x</FONT></I><FONT
COLOR="#0000FF"><I>&phi;</I></FONT> &rarr; <FONT
FACE=sans-serif>&forall;</FONT><I><FONT COLOR="#FF0000">x</FONT></I><FONT
FACE=sans-serif>&forall;</FONT><I><FONT COLOR="#FF0000">x</FONT></I><FONT
COLOR="#0000FF"><I>&phi;</I></FONT>)</SPAN></TD></TR>

<TR ALIGN=LEFT><TD><A HREF="ax-ie1.html"><SPAN ><I><FONT
COLOR="#FF0000">x</FONT></I></SPAN> is bound in <SPAN ><FONT
FACE=sans-serif>&exist;</FONT><I><FONT COLOR="#FF0000">x</FONT></I><FONT
COLOR="#0000FF"><I>&phi;</I></FONT></SPAN></A></TD>
<TD><FONT COLOR="#006633"><B>ax-ie1</B></FONT></TD><TD>
<SPAN ><FONT COLOR="#808080" FACE=sans-serif>&#8866; </FONT>(<FONT
FACE=sans-serif>&exist;</FONT><I><FONT COLOR="#FF0000">x</FONT></I><FONT
COLOR="#0000FF"><I>&phi;</I></FONT> &rarr; <FONT
FACE=sans-serif>&forall;</FONT><I><FONT COLOR="#FF0000">x</FONT></I><FONT
FACE=sans-serif>&exist;</FONT><I><FONT COLOR="#FF0000">x</FONT></I><FONT
COLOR="#0000FF"><I>&phi;</I></FONT>)</SPAN></TD></TR>

<TR ALIGN=LEFT><TD><A HREF="ax-ie2.html">Define existential
quantification</A></TD>
<TD><FONT COLOR="#006633"><B>ax-ie2</B></FONT></TD><TD>
<SPAN ><FONT COLOR="#808080" FACE=sans-serif>&#8866; </FONT>(<FONT
FACE=sans-serif>&forall;</FONT><I><FONT COLOR="#FF0000">x</FONT></I>(<FONT
COLOR="#0000FF"><I>&psi;</I></FONT> &rarr; <FONT
FACE=sans-serif>&forall;</FONT><I><FONT COLOR="#FF0000">x</FONT></I><FONT
COLOR="#0000FF"><I>&psi;</I></FONT>) &rarr; (<FONT
FACE=sans-serif>&forall;</FONT><I><FONT COLOR="#FF0000">x</FONT></I>(<FONT
COLOR="#0000FF"><I>&phi;</I></FONT> &rarr; <FONT
COLOR="#0000FF"><I>&psi;</I></FONT>) &harr; (<FONT
FACE=sans-serif>&exist;</FONT><I><FONT COLOR="#FF0000">x</FONT></I><FONT
COLOR="#0000FF"><I>&phi;</I></FONT> &rarr; <FONT
COLOR="#0000FF"><I>&psi;</I></FONT>)))</SPAN></TD></TR>

<TR ALIGN=LEFT><TD><A HREF="ax-8.html">Axiom of Equality</A></TD>
<TD><FONT COLOR="#006633"><B>ax-8</B></FONT></TD><TD>
<SPAN ><FONT COLOR="#808080" FACE=sans-serif>&#8866; </FONT>(<I><FONT
COLOR="#FF0000">x</FONT></I> = <I><FONT COLOR="#FF0000">y</FONT></I> &rarr;
(<I><FONT COLOR="#FF0000">x</FONT></I> = <I><FONT COLOR="#FF0000">z</FONT></I>
&rarr; <I><FONT COLOR="#FF0000">y</FONT></I> = <I><FONT
COLOR="#FF0000">z</FONT></I>))</SPAN></TD></TR>

<TR ALIGN=LEFT><TD><A HREF="ax-i9.html">Axiom of Existence</A></TD>
<TD><FONT COLOR="#006633"><B>ax-i9</B></FONT></TD><TD>
<SPAN ><FONT COLOR="#808080" FACE=sans-serif>&#8866; </FONT><FONT
FACE=sans-serif>&exist;</FONT><I><FONT COLOR="#FF0000">x</FONT></I> <I><FONT
COLOR="#FF0000">x</FONT></I> = <I><FONT
COLOR="#FF0000">y</FONT></I></SPAN></TD></TR>

<TR ALIGN=LEFT><TD><A HREF="ax-10.html">Axiom of Quantifier
Substitution</A></TD>
<TD><FONT COLOR="#006633"><B>ax-10</B></FONT></TD><TD>
<SPAN ><FONT COLOR="#808080" FACE=sans-serif>&#8866; </FONT>(<FONT
FACE=sans-serif>&forall;</FONT><I><FONT COLOR="#FF0000">x</FONT></I> <I><FONT
COLOR="#FF0000">x</FONT></I> = <I><FONT COLOR="#FF0000">y</FONT></I> &rarr;
<FONT FACE=sans-serif>&forall;</FONT><I><FONT COLOR="#FF0000">y</FONT></I>
<I><FONT COLOR="#FF0000">y</FONT></I> = <I><FONT
COLOR="#FF0000">x</FONT></I>)</SPAN></TD></TR>

<TR ALIGN=LEFT><TD><A HREF="ax-11.html">Axiom of Variable
Substitution</A></TD>
<TD><FONT COLOR="#006633"><B>ax-11</B></FONT></TD><TD>
<SPAN ><FONT COLOR="#808080" FACE=sans-serif>&#8866; </FONT>(<I><FONT
COLOR="#FF0000">x</FONT></I> = <I><FONT COLOR="#FF0000">y</FONT></I> &rarr;
(<FONT FACE=sans-serif>&forall;</FONT><I><FONT
COLOR="#FF0000">y</FONT></I><FONT COLOR="#0000FF"><I>&phi;</I></FONT> &rarr;
<FONT FACE=sans-serif>&forall;</FONT><I><FONT
COLOR="#FF0000">x</FONT></I>(<I><FONT COLOR="#FF0000">x</FONT></I> = <I><FONT
COLOR="#FF0000">y</FONT></I> &rarr; <FONT
COLOR="#0000FF"><I>&phi;</I></FONT>)))</SPAN></TD></TR>

<TR ALIGN=LEFT><TD><A HREF="ax-i12.html">Axiom of Quantifier
Introduction</A></TD>
<TD><FONT COLOR="#006633"><B>ax-i12</B></FONT></TD><TD>
<SPAN ><FONT COLOR="#808080" FACE=sans-serif>&#8866; </FONT>(<FONT
FACE=sans-serif>&forall;</FONT><I><FONT COLOR="#FF0000">z</FONT></I> <I><FONT
COLOR="#FF0000">z</FONT></I> = <I><FONT COLOR="#FF0000">x</FONT></I> <FONT
FACE=sans-serif> &or;</FONT> (<FONT FACE=sans-serif>&forall;</FONT><I><FONT
COLOR="#FF0000">z</FONT></I> <I><FONT COLOR="#FF0000">z</FONT></I> = <I><FONT
COLOR="#FF0000">y</FONT></I> <FONT FACE=sans-serif> &or;</FONT> <FONT
FACE=sans-serif>&forall;</FONT><I><FONT COLOR="#FF0000">z</FONT></I>(<I><FONT
COLOR="#FF0000">x</FONT></I> = <I><FONT COLOR="#FF0000">y</FONT></I> &rarr;
<FONT FACE=sans-serif>&forall;</FONT><I><FONT COLOR="#FF0000">z</FONT></I>
<I><FONT COLOR="#FF0000">x</FONT></I> = <I><FONT
COLOR="#FF0000">y</FONT></I>)))</SPAN></TD></TR>

<TR ALIGN=LEFT>
<TD><A HREF="ax-bndl.html">Axiom of Bundling</A></TD>
<TD><FONT COLOR="#006633"><B>ax-bndl</B></FONT></TD><TD>
<SPAN ><FONT COLOR="#808080" FACE=sans-serif>&#8866; </FONT>(<FONT
FACE=sans-serif>&forall;</FONT><I><FONT COLOR="#FF0000">z</FONT></I> <I><FONT
COLOR="#FF0000">z</FONT></I> = <I><FONT COLOR="#FF0000">x</FONT></I> <FONT
FACE=sans-serif> &or;</FONT> (<FONT FACE=sans-serif>&forall;</FONT><I><FONT
COLOR="#FF0000">z</FONT></I> <I><FONT COLOR="#FF0000">z</FONT></I> = <I><FONT
COLOR="#FF0000">y</FONT></I> <FONT FACE=sans-serif> &or;</FONT> <FONT
FACE=sans-serif>&forall;</FONT><I><FONT COLOR="#FF0000">x</FONT></I><FONT
FACE=sans-serif>&forall;</FONT><I><FONT COLOR="#FF0000">z</FONT></I>(<I><FONT
COLOR="#FF0000">x</FONT></I> = <I><FONT COLOR="#FF0000">y</FONT></I> &rarr;
<FONT FACE=sans-serif>&forall;</FONT><I><FONT COLOR="#FF0000">z</FONT></I>
<I><FONT COLOR="#FF0000">x</FONT></I> = <I><FONT
COLOR="#FF0000">y</FONT></I>)))</SPAN></TD></TR>

<TR ALIGN=LEFT><TD><A HREF="ax-13.html">Left Membership Equality</A></TD>
<TD><FONT COLOR="#006633"><B>ax-13</B></FONT></TD><TD>
<SPAN ><FONT COLOR="#808080" FACE=sans-serif>&#8866; </FONT>(<I><FONT
COLOR="#FF0000">x</FONT></I> = <I><FONT COLOR="#FF0000">y</FONT></I> &rarr;
(<I><FONT COLOR="#FF0000">x</FONT></I> <FONT FACE=sans-serif>&isin;</FONT>
<I><FONT COLOR="#FF0000">z</FONT></I> &rarr; <I><FONT
COLOR="#FF0000">y</FONT></I> <FONT FACE=sans-serif>&isin;</FONT> <I><FONT
COLOR="#FF0000">z</FONT></I>))</SPAN></TD></TR>

<TR ALIGN=LEFT><TD><A HREF="ax-14.html">Right Membership Equality</A></TD>
<TD><FONT COLOR="#006633"><B>ax-14</B></FONT></TD><TD>
<SPAN ><FONT COLOR="#808080" FACE=sans-serif>&#8866; </FONT>(<I><FONT
COLOR="#FF0000">x</FONT></I> = <I><FONT COLOR="#FF0000">y</FONT></I> &rarr;
(<I><FONT COLOR="#FF0000">z</FONT></I> <FONT FACE=sans-serif>&isin;</FONT>
<I><FONT COLOR="#FF0000">x</FONT></I> &rarr; <I><FONT
COLOR="#FF0000">z</FONT></I> <FONT FACE=sans-serif>&isin;</FONT> <I><FONT
COLOR="#FF0000">y</FONT></I>))</SPAN></TD></TR>

<TR ALIGN=LEFT><TD><A HREF="ax-17.html">Distinctness</A></TD>
<TD><FONT COLOR="#006633"><B>ax-17</B></FONT></TD><TD>
<SPAN ><FONT COLOR="#808080" FACE=sans-serif>&#8866; </FONT>(<FONT
COLOR="#0000FF"><I>&phi;</I></FONT> &rarr; <FONT
FACE=sans-serif>&forall;</FONT><I><FONT COLOR="#FF0000">x</FONT></I><FONT
COLOR="#0000FF"><I>&phi;</I></FONT>)</SPAN>,
where <FONT COLOR="#FF0000">x</FONT> does not occur in <FONT
COLOR="#0000FF"><I>&phi;</I></FONT></TD></TR>

</TABLE>
</CENTER>

<P><A NAME="staxioms"></A><B><FONT COLOR="#006633">Set theory</FONT></B>
uses the formalism of propositional and predicate calculus to assert
properties of arbitrary mathematical objects called "sets."  A set can
be an element of another set, and this relationship is indicated by the
<IMG SRC='in.gif' WIDTH=10 HEIGHT=19 ALT='e.'> symbol.
Starting with the simplest mathematical object, called the empty set,
set theory builds up more and more complex structures whose existence
follows from the axioms, eventually resulting in extremely complicated
sets that we identify with the real numbers and other familiar
mathematical objects.  These axioms were developed in response to <A
HREF="ru.html">Russell's Paradox</A>, a discovery that revolutionized
the foundations of mathematics and logic.</P>

<P><A NAME="izfaxioms"></A> In the IZF axioms that follow, <I>all set
variables are assumed to be</I> <A HREF="#distinct">distinct</A>.  If
you click on their links you will see the explicit distinct variable
conditions.</P>

<CENTER><TABLE BORDER CELLSPACING=0 BGCOLOR="#EEFFFA"
SUMMARY="Intuitionistic Zermelo-Fraenkel Set Theory (IZF)">
<CAPTION><B>Intuitionistic Zermelo-Fraenkel Set Theory (IZF)</B></CAPTION>

<TR ALIGN=LEFT><TD><A HREF="ax-ext.html">Axiom of Extensionality</A></TD>
<TD NOWRAP><FONT COLOR="#006633"><B>ax-ext</B></FONT></TD>
<TD>
<SPAN ><FONT COLOR="#808080" FACE=sans-serif>&#8866; </FONT>(<FONT
FACE=sans-serif>&forall;</FONT><I><FONT COLOR="#FF0000">z</FONT></I>(<I><FONT
COLOR="#FF0000">z</FONT></I> <FONT FACE=sans-serif>&isin;</FONT> <I><FONT
COLOR="#FF0000">x</FONT></I> &harr; <I><FONT COLOR="#FF0000">z</FONT></I> <FONT
FACE=sans-serif>&isin;</FONT> <I><FONT COLOR="#FF0000">y</FONT></I>) &rarr;
<I><FONT COLOR="#FF0000">x</FONT></I> = <I><FONT
COLOR="#FF0000">y</FONT></I>)</SPAN></TD></TR>

<TR ALIGN=LEFT>
<TD><A HREF="ax-coll.html">Axiom of Collection</A></TD>
<TD><FONT COLOR="#006633"><B>ax-coll</B></FONT></TD><TD>
<SPAN CLASS=math><FONT COLOR="#808080" FACE=sans-serif>&#8866; </FONT>(<FONT
FACE=sans-serif>&forall;</FONT><I><FONT COLOR="#FF0000">x</FONT></I> <FONT
FACE=sans-serif>&isin;</FONT> <SPAN CLASS=set
STYLE="color:red">&#x1D44E;</SPAN> <FONT FACE=sans-serif>&exist;</FONT><I><FONT
COLOR="#FF0000">y</FONT></I><FONT COLOR="#0000FF"><I>&phi;</I></FONT> &rarr;
<FONT FACE=sans-serif>&exist;</FONT><SPAN CLASS=set
STYLE="color:red">&#x1D44F;</SPAN><FONT FACE=sans-serif>&forall;</FONT><I><FONT
COLOR="#FF0000">x</FONT></I> <FONT FACE=sans-serif>&isin;</FONT> <SPAN
CLASS=set STYLE="color:red">&#x1D44E;</SPAN> <FONT
FACE=sans-serif>&exist;</FONT><I><FONT COLOR="#FF0000">y</FONT></I> <FONT
FACE=sans-serif>&isin;</FONT> <SPAN CLASS=set
STYLE="color:red">&#x1D44F;</SPAN> <FONT
COLOR="#0000FF"><I>&phi;</I></FONT>)</SPAN></TD></TR>

<TR ALIGN=LEFT>
<TD><A HREF="ax-sep.html">Axiom of Separation</A></TD>
<TD><FONT COLOR="#006633"><B>ax-sep</B></FONT></TD><TD>
<SPAN CLASS=math><FONT COLOR="#808080" FACE=sans-serif>&#8866; </FONT><FONT
FACE=sans-serif>&exist;</FONT><I><FONT COLOR="#FF0000">y</FONT></I><FONT
FACE=sans-serif>&forall;</FONT><I><FONT COLOR="#FF0000">x</FONT></I>(<I><FONT
COLOR="#FF0000">x</FONT></I> <FONT FACE=sans-serif>&isin;</FONT> <I><FONT
COLOR="#FF0000">y</FONT></I> &harr; (<I><FONT COLOR="#FF0000">x</FONT></I>
<FONT FACE=sans-serif>&isin;</FONT> <I><FONT COLOR="#FF0000">z</FONT></I> <FONT
FACE=sans-serif>&and;</FONT> <FONT
COLOR="#0000FF"><I>&phi;</I></FONT>))</SPAN></TD></TR>

<TR ALIGN=LEFT>
<TD><A HREF="ax-pow.html">Axiom of Power Sets</A></TD>
<TD><FONT COLOR="#006633"><B>ax-pow</B></FONT></TD><TD>
<SPAN CLASS=math><FONT COLOR="#808080" FACE=sans-serif>&#8866; </FONT><FONT
FACE=sans-serif>&exist;</FONT><I><FONT COLOR="#FF0000">y</FONT></I><FONT
FACE=sans-serif>&forall;</FONT><I><FONT COLOR="#FF0000">z</FONT></I>(<FONT
FACE=sans-serif>&forall;</FONT><I><FONT COLOR="#FF0000">w</FONT></I>(<I><FONT
COLOR="#FF0000">w</FONT></I> <FONT FACE=sans-serif>&isin;</FONT> <I><FONT
COLOR="#FF0000">z</FONT></I> &rarr; <I><FONT COLOR="#FF0000">w</FONT></I> <FONT
FACE=sans-serif>&isin;</FONT> <I><FONT COLOR="#FF0000">x</FONT></I>) &rarr;
<I><FONT COLOR="#FF0000">z</FONT></I> <FONT FACE=sans-serif>&isin;</FONT>
<I><FONT COLOR="#FF0000">y</FONT></I>)</SPAN></TD></TR>

<TR ALIGN=LEFT>
<TD><A HREF="ax-pr.html">Axiom of Pairing</A></TD>
<TD><FONT COLOR="#006633"><B>ax-pr</B></FONT></TD><TD>
<SPAN CLASS=math><FONT COLOR="#808080" FACE=sans-serif>&#8866; </FONT><FONT
FACE=sans-serif>&exist;</FONT><I><FONT COLOR="#FF0000">z</FONT></I><FONT
FACE=sans-serif>&forall;</FONT><I><FONT COLOR="#FF0000">w</FONT></I>((<I><FONT
COLOR="#FF0000">w</FONT></I> = <I><FONT COLOR="#FF0000">x</FONT></I> <FONT
FACE=sans-serif> &or;</FONT> <I><FONT COLOR="#FF0000">w</FONT></I> = <I><FONT
COLOR="#FF0000">y</FONT></I>) &rarr; <I><FONT COLOR="#FF0000">w</FONT></I>
<FONT FACE=sans-serif>&isin;</FONT> <I><FONT
COLOR="#FF0000">z</FONT></I>)</SPAN></TD></TR>

<TR ALIGN=LEFT>
<TD><A HREF="ax-un.html">Axiom of Union</A></TD>
<TD><FONT COLOR="#006633"><B>ax-un</B></FONT></TD><TD>
<SPAN CLASS=math><FONT COLOR="#808080" FACE=sans-serif>&#8866; </FONT><FONT
FACE=sans-serif>&exist;</FONT><I><FONT COLOR="#FF0000">y</FONT></I><FONT
FACE=sans-serif>&forall;</FONT><I><FONT COLOR="#FF0000">z</FONT></I>(<FONT
FACE=sans-serif>&exist;</FONT><I><FONT COLOR="#FF0000">w</FONT></I>(<I><FONT
COLOR="#FF0000">z</FONT></I> <FONT FACE=sans-serif>&isin;</FONT> <I><FONT
COLOR="#FF0000">w</FONT></I> <FONT FACE=sans-serif>&and;</FONT> <I><FONT
COLOR="#FF0000">w</FONT></I> <FONT FACE=sans-serif>&isin;</FONT> <I><FONT
COLOR="#FF0000">x</FONT></I>) &rarr; <I><FONT COLOR="#FF0000">z</FONT></I>
<FONT FACE=sans-serif>&isin;</FONT> <I><FONT
COLOR="#FF0000">y</FONT></I>)</SPAN></TD></TR>

<TR ALIGN=LEFT>
<TD><A HREF="ax-setind.html">Axiom of Set Induction</A></TD>
<TD><FONT COLOR="#006633"><B>ax-setind</B></FONT></TD><TD>
<SPAN CLASS=math><FONT COLOR="#808080" FACE=sans-serif>&#8866; </FONT>(<FONT
FACE=sans-serif>&forall;</FONT><SPAN CLASS=set
STYLE="color:red">&#x1D44E;</SPAN>(<FONT
FACE=sans-serif>&forall;</FONT><I><FONT COLOR="#FF0000">y</FONT></I> <FONT
FACE=sans-serif>&isin;</FONT> <SPAN CLASS=set
STYLE="color:red">&#x1D44E;</SPAN> [<I><FONT COLOR="#FF0000">y</FONT></I> /
<SPAN CLASS=set STYLE="color:red">&#x1D44E;</SPAN>]<FONT
COLOR="#0000FF"><I>&phi;</I></FONT> &rarr; <FONT
COLOR="#0000FF"><I>&phi;</I></FONT>) &rarr; <FONT
FACE=sans-serif>&forall;</FONT><SPAN CLASS=set
STYLE="color:red">&#x1D44E;</SPAN><FONT
COLOR="#0000FF"><I>&phi;</I></FONT>)</SPAN></TD>
</TR>

<TR ALIGN=LEFT>
<TD><A HREF="ax-iinf.html">Axiom of Infinity</A></TD>
<TD><FONT COLOR="#006633"><B>ax-iinf</B></FONT></TD><TD>
<SPAN CLASS=math><FONT COLOR="#808080" FACE=sans-serif>&#8866; </FONT><FONT
FACE=sans-serif>&exist;</FONT><I><FONT COLOR="#FF0000">x</FONT></I>(&empty;
<FONT FACE=sans-serif>&isin;</FONT> <I><FONT COLOR="#FF0000">x</FONT></I> <FONT
FACE=sans-serif>&and;</FONT> <FONT FACE=sans-serif>&forall;</FONT><I><FONT
COLOR="#FF0000">y</FONT></I>(<I><FONT COLOR="#FF0000">y</FONT></I> <FONT
FACE=sans-serif>&isin;</FONT> <I><FONT COLOR="#FF0000">x</FONT></I> &rarr; suc
<I><FONT COLOR="#FF0000">y</FONT></I> <FONT FACE=sans-serif>&isin;</FONT>
<I><FONT COLOR="#FF0000">x</FONT></I>))</SPAN>
</TD></TR>

</TABLE></CENTER>

<P>We develop set theory based on the Intuitionistic Zermelo-Fraenkel
(IZF) system, mostly following the IZF axioms as laid out in [Crosilla].
Constructive Zermelo-Fraenkel (CZF), also described in Crosilla, is not
as easy to formalize in metamath because the Axiom of Restricted Separation
would require us to develop the ability to classify formulas as bounded
formulas, similar to the machinery we have built up for asserting on
whether variables are free in formulas.</P>

<P></P><HR NOSHADE SIZE=1><A NAME="theorems"></A><B><FONT COLOR="#006633">A
Theorem Sampler</FONT></B>&nbsp;&nbsp;&nbsp;

<P></P><CENTER><FONT COLOR="#006633"><I>From a psychological point of view,
learning constructive mathematics is agonizing, for it requires one to
first unlearn certain deeply ingrained intuitions and
habits acquired during classical mathematical training.</I>
<BR> &mdash;Andrej Bauer</FONT></CENTER>

<P>Listed here are some examples of starting points for your journey
through the maze.  Some are stated just as they would be in a
non-constructive context; others are here to highlight areas which
look different constructively.
You should study some simple proofs from
propositional calculus until you get the hang of it.  Then try some
predicate calculus and finally set theory.</P>

<P>The <A HREF="mmtheorems.html">Theorem List</A> shows the complete set of
theorems in the database.  You may also find the <A
HREF="mmbiblio.html">Bibliographic Cross-Reference</A> useful.</P>


<P><TABLE BORDER=0><TR><TD VALIGN=TOP WIDTH="50%"><TR><TD VALIGN=TOP WIDTH="50%">
<B>Propositional calculus</B>
<MENU>
<LI>
<A HREF="id1.html">Law of identity</A></LI>

<LI>
<A HREF="prth.html">Praeclarum theorema</A></LI>

<LI>
<A HREF="con3.html">Contraposition introduction</A></LI>

<LI>
<A HREF="notnot.html">Double negation introduction</A></LI>

<LI>
<A HREF="notnotnot.html">Triple negation</A></LI>

<LI>
<A HREF="df-xor.html">Definition of exclusive or</A></LI>

<LI>
<A HREF="dfnot.html">Negation and the false constant</A></LI>
</MENU>
<B>Predicate calculus</B>
<MENU>
<LI>
<A HREF="19.12.html">Existential and universal quantifier swap</A></LI>

<LI>
<A HREF="19.35-1.html">Existentially quantified implication</A></LI>

<LI>
<A HREF="equid.html"><I>x</I> = <I>x</I></A></LI>

<LI>
<A HREF="df-sb.html">Definition of proper substitution</A></LI>

<LI>
<A HREF="2eu7.html">Double existential uniqueness</A></LI>

</MENU>
<B>Set theory</B>
<MENU>
<LI>
<A HREF="uncom.html">Commutative law for union</A></LI>

<LI>
<A HREF="abeq2.html">A basic relationship between class and wff
variables</A></LI>

<LI>
<A HREF="isset.html">Two ways of saying &quot;is a set&quot;</A></LI>

<LI>
<A HREF="regexmid.html">The ZF axiom of foundation implies excluded middle</A></LI>

<LI>
<A HREF="ru.html">Russell's paradox</A></LI>

<LI>
<A HREF="ordtriexmid.html">Ordinal trichotomy implies excluded middle</A></LI>

<LI>
<A HREF="findes.html">Mathematical (finite) induction</A></LI>

<LI>Peano's postulates for arithmetic:
<A HREF="peano1.html">1</A>
<A HREF="peano2.html">2</A>
<A HREF="peano3.html">3</A>
<A HREF="peano4.html">4</A>
<A HREF="peano5.html">5</A></LI>

<LI><A HREF="nndceq.html">Two natural numbers are either equal or not equal</A> (a special case of the law of the excluded middle which we can prove).</LI>

<LI><A HREF="nn0suc.html">A natural number is either zero or a successor</A></LI>

<LI>
<A HREF="acexmid.html">The axiom of choice implies excluded middle</A></LI>

<LI>
<A HREF="onprc.html">Burali-Forti paradox</A></LI>

<LI>
<A HREF="tfis3.html">Transfinite induction</A></LI>

<LI>
<A HREF="oacl.html">Closure law for ordinal addition</A></LI>

</MENU>
<B>Real and complex numbers</B>

<MENU>
<LI>Properties of apartness:
<A HREF="apirr.html">1</A>
<A HREF="apsym.html">2</A>
<A HREF="apcotr.html">3</A>
<A HREF="apti.html">4</A></LI>

</MENU>
</TD></TR></TABLE>

<HR NOSHADE SIZE=1><A NAME="intuitionize"></A><B><FONT
COLOR="#006633">How to intuitionize classical proofs</FONT></B>&nbsp;&nbsp;&nbsp;

<P>For the student or master of classical mathematics, constructive mathematics
can be baffling. One can get over some of the intial hurdles of understanding
how constructive mathematics works and why it might be interesting by reading
<A HREF="#Bauer">[Bauer]</A> but that work does little to explain in concrete terms how to write
proofs in intuitionistic logic. Fortunately, metamath helps with one of the
biggest hurdles: noticing when one is even using the law of the excluded
middle or the axiom of choice. But suppose you have a classical proof from
the Metamath Proof Explorer and it fails to verify when you copy it over to
the Intuitionistic Logic Explorer. What then? Here are some rules of thumb
in converting classical proofs to intuitionistic ones.</P>

<UL>

<LI>If you see case elimination ( pm2.61 or its variants) you'll probably end up with two theorems for the two cases. In particular, if the cases were ` A e. _V ` and ` -. A e. _V ` you probably just care about the ` A e. _V ` case.
On the other hand, if the proposition being eliminated is decidable
(for example due to ~ nndceq , ~ zdceq , ~ zdcle , ~ zdclt , ~ eluzdc , or ~ fzdcel ),
then case elimination will work using theorems such as ~ df-dc and ~ mpjaodan .</LI>

<LI>
Non-empty almost always needs to be changed to inhabited (those terms are defined at ~ n0rf ).
</LI>

<LI>If the original proof relied on propositional/predicate logic which isn't a theorem of intuitionistic logic, maybe there is a way of expressing the logic more directly. This is perhaps the hardest one to put in cookbook form: you might need to try some things and see if anything works.</LI>

<LI>If the original proof relied on df-ex so that it could prove a theorem for ` A. ` and then get ` E. ` for free (or vice versa), instead go look at the original proof and try to come up the analogues to each step for the other quantifier (for example, ~ cbvrexcsf , ~ sbcrext , ~ rexxpf ). Similarly, if you have a theorem for ` <_ ` and are trying to prove the corresponding theorem for ` < ` you'll probably need to use analogous steps rather than negation (examples: ~ leaddsub , ~ ltsub1 , ~ ltsub2 ).</LI>

<LI>If you are dealing with a definition, try to find the best constructive definition from the literature ([HoTT] book, Stanford Encyclopedia of Philosophy, [Bauer], etc). Once you pick a definition, that'll affect the proofs which rely on that definition.</LI>

<LI>If there is case elimination on whether variables are distinct, most of the time you just need the variant with distinct variables. Sometimes you can then remove the constraint with a temporary variable (e.g. the various sbco2* variants, ~ nfralya , ~ r19.3rm ).</LI>

<LI>Sometimes one direction of a biconditional holds, or subset holds instead of equality. You might be able to keep the easy direction and worry about the other one later.</LI>

<LI>
If there is case elimination sometimes only one of the two cases is possible.
For example, in ~ mosubopt the rest of the formula being proved constrains
which case matters.
</LI>

<LI>
If you need an additional condition (for example, because the original proof
used case elimination) and you are proving a biconditional, consider whether
both sides of the biconditional imply the condition. If so, you'll be able to
prove the biconditional with that condition as an antecedent, and then use
~ pm5.21nii or one of its variants to remove the antecedent (example:
~ elxp4 ).
</LI>

<LI>
If your proof relies on dveeq2 try ~ dveeq2or and likewise for the other things
downstream of ~ ax-i12 or ~ ax-bndl .
</LI>

<LI>
If you have a disjunction, be reluctant to turn it into an implication using
~ ord and the like. Instead, show that each disjunct implies what you are
trying to prove and use ~ jaoi to join those two implications into something
which can hook up to the disjunction.
</LI>

<LI>
Disjunctive syllogism holds in intuitionistic logic and we state it a few ways
(for example ~ orel1 and ~ ecased ) but we don't have a wide variety of
convenience theorems. Unless we add those, you'll use ~ ord or something
similar followed by ~ mpd or something similar. This may add a few steps but
they are straightforward ones.
</LI>

<LI>
If your proof is doing tricky things perhaps in the interest of shortness, try
just expanding the definitions and applying logic in a straightforward way. See
if this gets you a working (although perhaps longer) proof.
</LI>

<LI>
If your proof relies on a biconditional in set.mm which isn't in iset.mm, see
if one direction is in iset.mm and see which direction your proof is using. For
example ~ 19.35-1 or ~ exnalim .
</LI>

<LI>
If you are doing things with inhabited classes (beyond just applying existing
inhabited class theorems), you may be able to dig up some predicate logic you
haven't used in a while (e.g. ~ raaan ).
</LI>

<LI>
Consider the possibility of giving up. Some things just won't have
intuitionistic proofs. The more it looks like excluded middle or other
non-intuitionistic statements, the more likely you are dealing with one of
these. But it can be hard to have good intuition about this. In some cases it
may be possible to ask "can I use this statement to prove ` ph \/ -. ph ` for an
arbitrary proposition" (see ~ ordtriexmid for example ), but this is not always
an easy technique to apply.
</LI>

<LI>
Switching between ~ 2th and ~ 2false might help (e.g. ~ dfnul2 , ~ dfnul3 ,
~ rab0 ).
</LI>

<LI>
In many cases statements which are equivalent in classical logic become several
non-equivalent statements (e.g. exclusive or, ordinals, non-empty versus
inhabited, apartness versus negated equality). This is usually a good place to
look for a literature reference, but don't be afraid to change the statement
being proved to "what you really meant is X" as appropriate.
</LI>

<LI>
If a statement has multiple equivalences in set.mm (e.g. mo2 and mo3 , or
dffun2 and dffun3 ) and only some of them in iset.mm, sometimes a pretty
similar proof will work (that is, which one to use in the original proof may
have been a fairly arbitrary choice).
</LI>

<LI>
A number of theorems related to functions (especially ovex and fvex ) in
set.mm perform case elimination based on whether we are evaluating the function
within its domain or outside it. The most straightforward solution is to
use ~ fnovex or ~ funfvex which only work within the domain. Using these
may involve rearranging logic, for example by changing ~ rexlimivw to
~ rexlimdva (example: ~ ovelrn or indeed most uses of ~ fnovex and ~ funfvex ).
If a function value is inhabited, we know we are evaluating it within
its domain by ~ relelfvdm .
</LI>

<LI>
With excluded middle, ` (/) e. A ` and ` A =/= (/) ` are equivalent (where
` A ` is an ordinal). In such theorems, ` (/) e. A ` is generally the more
interesting condition constructively.</LI>

<LI>
Reverse closure in set.mm uses excluded middle (for example ovrcl or ndmfvrcl
). The most general way to handle this is to add more conditions that we are
evaluating operations within
their domains (for example set.mm's addasspi versus iset.mm's ~ addasspig in
which conditions such as ` A e. N. ` are added, or set.mm's ltbtwnnq versus
iset.mm's ~ ltbtwnnqq , in which ` E. x ` is changed to ` E. x e. Q. ` ).
If the result of applying a function is inhabited, then we know we applied
it within its domain - that is ~ relelfvdm or ~ elmpt2cl may be useful.
(These thoughts apply to operations - in at least one place, ~ dvdszrcl ,
set.mm uses the term "reverse closure" for binary relations - but this is
a lot more like ~ brel than like the reverse closure theorems described
above).
</LI>

<LI>
With excluded middle not equal (` =/= `) and apart (` # `) are equivalent.
When working with real and complex numbers, apartness is almost always what
you want. See ~ df-ap for more on apartness.
</LI>

<LI>Exclusive or ( ` ph \/_ ps ` ) is equivalent to ` ph <-> -. ps `
given excluded middle but we just have one direction ( ~ xorbin ).
Consider intuitionizing ` ph <-> -. ps ` as ` ph \/_ ps `
(example: ~ rpnegap ).</LI>

<LI>
If you get stuck, ask! (for example in a GitHub issue or on the mailing list).
We have a number of contributors who have experience in constructive
mathematics in general, or iset.mm in particular, and one of the best things
about doing/learning mathematics in metamath is the collaborative nature of how
we develop it.
</UL>

<HR NOSHADE SIZE=1><A NAME="setmm"></A>
<B><FONT COLOR="#006633">Metamath Proof Explorer cross
reference</FONT></B>&nbsp;&nbsp;&nbsp;

<P>This is a list of theorems from the Metamath Proof Explorer (which
assumes the law of the excluded middle throughout) which we do not
have in the Intuitionistic Logic Explorer (generally because they
are not provable without the law of the excluded middle, although some
could be proved but aren't for a variety of reasons), together
with the closest replacements.</P>

<TABLE BORDER CELLSPACING=0 BGCOLOR="#EEFFFA">
<TR>
<TH>set.mm</TH>
<TH>iset.mm</TH>
<TH>notes</TH>
</TR>

<TR>
<TD>ax-3 , con4d , con34b , necon4bd</TD>
<TD>~ con3 </TD>
<TD>The form of contraposition which removes negation does not hold
in intutionistic logic.</TD>
</TR>

<TR>
<TD>pm2.18</TD>
<TD>~ pm2.01 </TD>
<TD>See for example [Bauer] who uses the terminology "proof of negation"
versus "proof by contradiction" to distinguish these.</TD>
</TR>

<TR>
<TD>pm2.18d , pm2.18i</TD>
<TD>~ pm2.01d</TD>
<TD>See for example [Bauer] who uses the terminology "proof of negation"
versus "proof by contradiction" to distinguish these.</TD>
</TR>

<TR>
<TD>notnotrd , notnotri , notnotr , notnotb</TD>
<TD>~ notnot </TD>
<TD>Double negation introduction holds but not double negation
elimination.</TD>
</TR>

<TR>
<TD>mt3d</TD>
<TD>~ mtod </TD>
</TR>

<TR>
<TD>nsyl2</TD>
<TD>~ nsyl </TD>
</TR>

<TR>
  <TD>mt4d</TD>
  <TD>~ mt2d</TD>
</TR>

<TR>
<TD>pm2.61 , pm2.61d , pm2.61d1 , pm2.61d2 , pm2.61i , pm2.61ii , pm2.61nii ,
pm2.61iii , pm2.61ian , pm2.61dan , pm2.61ddan , pm2.61dda , pm2.61ine , pm2.61ne ,
pm2.61dne , pm2.61dane , pm2.61da2ne , pm2.61da3ne , pm2.61iine
</TD>
<TD><I>none</I></TD>
<TD>If the proposition being eliminated is decidable
(for example due to ~ nndceq , ~ zdceq , ~ zdcle , ~ zdclt , ~ eluzdc , or ~ fzdcel ),
then case elimination will work using theorems such as ~ exmiddc and ~ mpjaodan</TD>
</TR>

<TR>
  <TD>dfbi1 , dfbi3</TD>
  <TD>~ df-bi , ~ dfbi2</TD>
</TR>

<TR>
<TD>impcon4bid, con4bid, notbi, con1bii, con4bii, con2bii</TD>
<TD>~ con3 , ~ condc</TD>
</TR>

<TR>
<TD>xor3 , nbbn</TD>
<TD>~ xorbin , ~ xornbi , ~ xor3dc , ~ nbbndc </TD>
</TR>

<TR>
<TD>biass</TD>
<TD>~ biassdc </TD>
</TR>

<TR>
<TD>df-or , pm4.64 , pm2.54 , orri , orrd</TD>
<TD>~ pm2.53 , ~ ori , ~ ord , ~ dfordc</TD>
</TR>

<TR>
<TD>imor , imori</TD>
<TD>~ imorr , ~ imorri , ~ imordc</TD>
</TR>

<TR>
<TD>pm4.63</TD>
<TD>~ pm3.2im </TD>
</TR>

<TR>
<TD>iman</TD>
<TD>~ imanim </TD>
</TR>

<TR>
<TD>annim</TD>
<TD>~ annimim </TD>
</TR>

<TR>
<TD>oran , pm4.57</TD>
<TD>~ oranim , ~ orandc</TD>
</TR>

<TR>
<TD>ianor</TD>
<TD>~ pm3.14 , ~ ianordc</TD>
</TR>

<TR>
  <TD>pm4.14</TD>
  <TD>~ pm4.14dc , ~ pm3.37</TD>
</TR>

<TR>
  <TD>pm5.17</TD>
  <TD>~ xorbin</TD>
  <TD>The combination of ~ df-xor and ~ xorbin is the forward direction
  of pm5.17</TD>
</TR>

<TR>
<TD>biluk</TD>
<TD>~ bilukdc </TD>
</TR>

<TR>
<TD>ecase3d</TD>
<TD><I>none</I></TD>
<TD>This is a form of case elimination.<TD>
</TR>

<TR>
<TD>dedlem0b</TD>
<TD>~ dedlemb </TD>
</TR>

<TR>
  <TD>pm4.42</TD>
  <TD>~ pm4.42r</TD>
</TR>

<TR>
<TD>3ianor</TD>
<TD>~ 3ianorr </TD>
</TR>

<TR>
<TD>df-nan and other theorems using NAND (Sheffer stroke) notation</TD>
<TD><I>none</I></TD>
<TD>A quick glance at the internet shows this mostly being used in
the presence of excluded middle; in any case it is not currently
present in iset.mm</TD>
</TR>

<TR>
<TD>df-xor</TD>
<TD>~ df-xor </TD>
<TD>Although the definition of exclusive or is called df-xor in both
set.mm and iset.mm (at least currently), the definitions are not
equivalent (in the absence of excluded middle).</TD>
</TR>

<TR>
<TD>xnor</TD>
<TD><I>none</I></TD>
<TD>The set.mm proof uses theorems not in iset.mm.</TD>
</TR>

<TR>
<TD>xorass</TD>
<TD><I>none</I></TD>
<TD>The set.mm proof uses theorems not in iset.mm.</TD>
</TR>

<TR>
<TD>xor2</TD>
<TD>~ xoranor , ~ xor2dc</TD>
</TR>

<TR>
<TD>xornan</TD>
<TD>~ xor2dc</TD>
</TR>

<TR>
<TD>xornan2</TD>
<TD><I>none</I></TD>
<TD>See discussion under df-nan</TD>
</TR>

<TR>
<TD>xorneg2 , xorneg1 , xorneg</TD>
<TD><I>none</I></TD>
<TD>The set.mm proofs use theorems not in iset.mm.</TD>
</TR>

<TR>
<TD>xorexmid</TD>
<TD><I>none</I></TD>
<TD>A form of excluded middle</TD>
</TR>

<TR>
<TD>df-ex</TD>
<TD>~ exalim </TD>
</TR>

<TR>
<TD>alex</TD>
<TD>~ alexim </TD>
</TR>

<TR>
<TD>exnal</TD>
<TD>~ exnalim </TD>
</TR>

<TR>
<TD>alexn</TD>
<TD>~ alexnim </TD>
</TR>

<TR>
<TD>exanali</TD>
<TD>~ exanaliim </TD>
</TR>

<TR>
<TD>19.35 , 19.35ri</TD>
<TD>~ 19.35-1 </TD>
</TR>

<TR>
<TD>19.30</TD>
<TD><I>none</I>
</TR>

<TR>
  <TD>19.39</TD>
  <TD>~ i19.39</TD>
</TR>

<TR>
  <TD>19.24</TD>
  <TD>~ i19.24</TD>
</TR>

<TR>
<TD>19.36 , 19.36v</TD>
<TD>~ 19.36-1 </TD>
</TR>

<TR>
<TD>19.37 , 19.37v</TD>
<TD>~ 19.37-1 </TD>
</TR>

<TR>
<TD>19.32</TD>
<TD>~ 19.32r </TD>
</TR>

<TR>
<TD>19.31</TD>
<TD>~ 19.31r </TD>
</TR>

<TR>
<TD>exdistrf</TD>
<TD>~ exdistrfor </TD>
</TR>

<TR>
<TD>exmo</TD>
<TD>~ exmonim </TD>
</TR>

<TR>
<TD>mo2</TD>
<TD>~ mo2r , ~ mo3 </TD>
</TR>

<TR>
<TD>nne</TD>
<TD>~ nner , ~ nnedc</TD>
</TR>

<TR>
<TD>exmidne</TD>
<TD>~ dcne </TD>
</TR>

<TR>
<TD>neor</TD>
<TD>~ pm2.53 , ~ ori , ~ ord </TD>
</TR>

<TR>
<TD>neorian</TD>
<TD>~ pm3.14 </TD>
</TR>

<TR>
<TD>nnel</TD>
<TD><I>none</I></TD>
<TD>The reverse direction could be proved; the forward direction
is double negation elimination.</TD>
</TR>

<TR>
<TD>nfrald</TD>
<TD>~ nfraldxy , ~ nfraldya </TD>
</TR>

<TR>
<TD>rexnal</TD>
<TD>~ rexnalim </TD>
</TR>

<TR>
<TD>rexanali</TD>
<TD><I>none</I></TD>
</TR>

<TR>
<TD>nrexralim</TD>
<TD><I>none</I></TD>
</TR>

<TR>
<TD>dfral2</TD>
<TD>~ ralexim </TD>
</TR>

<TR>
<TD>dfrex2</TD>
<TD>~ rexalim </TD>
</TR>

<TR>
<TD>nfrexd</TD>
<TD>~ nfrexdxy , ~ nfrexdya </TD>
</TR>

<TR>
<TD>nfral</TD>
<TD>~ nfralxy , ~ nfralya </TD>
</TR>

<TR>
<TD>nfra2</TD>
<TD>~ nfra1 , ~ nfralya </TD>
</TR>

<TR>
<TD>nfrex</TD>
<TD>~ nfrexxy , ~ nfrexya </TD>
</TR>

<TR>
<TD>r19.30</TD>
<TD><I>none</I></TD>
</TR>

<TR>
<TD>r19.35</TD>
<TD>~ r19.35-1</TD>
</TR>

<TR>
<TD>ralcom2</TD>
<TD>~ ralcom </TD>
</TR>

<TR>
  <TD>2reuswap</TD>
  <TD>~ 2reuswapdc</TD>
</TR>

<TR>
  <TD>df-pss and all proper subclass theorems</TD>
  <TD><I>none</I></TD>
  <TD>In set.mm, "A is a proper subclass of B" is defined to be
  ` ( A C_ B /\ A =/= B ) ` and this definition is almost always used in
  conjunction with excluded middle. A more natural definition
  might be ` ( A C_ B /\ E. x x e. ( B \ A ) )` , if we need proper subclass
  at all.</TD>
</TR>

<TR>
  <TD>nss</TD>
  <TD>~ nssr</TD>
</TR>

<TR>
  <TD>ddif</TD>
  <TD>~ ddifnel , ~ ddifss</TD>
</TR>

<TR>
  <TD>dfss4</TD>
  <TD>~ ssddif</TD>
</TR>

<TR>
<TD>n0f</TD>
<TD>~ n0rf</TD>
</TR>

<TR>
<TD>n0</TD>
<TD>~ n0r , ~ fin0 , ~ fin0or</TD>
</TR>

<TR>
<TD>neq0</TD>
<TD>~ neq0r </TD>
</TR>

<TR>
<TD>reximdva0</TD>
<TD>~ reximdva0m </TD>
</TR>

<TR>
<TD>rabn0</TD>
<TD>~ rabn0m , ~ rabn0r </TD>
</TR>

<TR>
<TD>ssdif0</TD>
<TD>~ ssdif0im </TD>
</TR>

<TR>
<TD>inssdif0</TD>
<TD>~ inssdif0im </TD>
</TR>

<TR>
  <TD>undif1</TD>
  <TD>~ undif1ss</TD>
</TR>

<TR>
<TD>undif2</TD>
<TD>~ undif2ss </TD>
</TR>

<TR>
  <TD>inundif</TD>
  <TD>~ inundifss</TD>
</TR>

<TR>
  <TD>undif</TD>
  <TD>~ undifss</TD>
</TR>

<TR>
  <TD>ssundif</TD>
  <TD>~ ssundifim</TD>
</TR>

<TR>
<TD>uneqdifeq</TD>
<TD>~ uneqdifeqim </TD>
</TR>

<TR>
  <TD>r19.2z</TD>
  <TD>~ r19.2m</TD>
</TR>

<TR>
  <TD>r19.9rzv</TD>
  <TD>~ r19.9rmv</TD>
</TR>

<TR>
<TD>r19.45zv</TD>
<TD>~ r19.45mv </TD>
</TR>

<TR>
<TD>dfif2</TD>
<TD>~ df-if </TD>
</TR>

<TR>
<TD>ifsb</TD>
<TD>~ ifsbdc</TD>
</TR>

<TR>
<TD>dfif4</TD>
<TD><I>none</I></TD>
<TD>Unused in set.mm</TD>
</TR>

<TR>
<TD>dfif5</TD>
<TD><I>none</I></TD>
<TD>Unused in set.mm</TD>
</TR>

<TR>
  <TD>ifeq1da</TD>
  <TD>~ ifeq1dadc</TD>
</TR>

<TR>
<TD>ifnot</TD>
<TD><I>none</I></TD>
</TR>

<TR>
<TD>ifan</TD>
<TD><I>none</I></TD>
</TR>

<TR>
<TD>ifor</TD>
<TD><I>none</I></TD>
</TR>

<TR>
<TD>ifeq2da</TD>
<TD><I>none</I></TD>
</TR>

<TR>
<TD>ifclda</TD>
<TD>~ ifcldadc</TD>
</TR>

<TR>
<TD>ifeqda</TD>
<TD><I>none</I></TD>
</TR>

<TR>
<TD>elimif , ifbothda , ifid , eqif , ifval , elif ,
ifel , ifeqor , 2if2 , ifcomnan , csbif ,
csbifgOLD</TD>
<TD><I>none</I></TD>
</TR>

<TR>
  <TD>ifboth</TD>
  <TD>~ ifbothdc</TD>
</TR>

<TR>
  <TD>ifcl , ifcld</TD>
  <TD>~ ifcldcd , ~ ifcldadc</TD>
</TR>

<TR>
<TD>dedth , dedth2h , dedth3h , dedth4h , dedth2v , dedth3v ,
dedth4v , elimhyp , elimhyp2v , elimhyp3v , elimhyp4v ,
elimel , elimdhyp , keephyp , keephyp2v , keephyp3v , keepel</TD>
<TD><I>none</I></TD>
<TD>Even in set.mm, the weak deduction theorem is discouraged in
favor of theorems in deduction form.</TD>
</TR>

<TR>
  <TD>ifex , ifexg</TD>
  <TD>~ ifcldcd , ~ ifcldadc</TD>
</TR>

<TR>
  <TD>ifpr</TD>
  <TD><I>none</I></TD>
  <TD>Should be provable if the condition is decidable.</TD>
</TR>

<TR>
  <TD ROWSPAN="3">difsnid</TD>
  <TD>~ difsnss</TD>
  <TD>One direction, for any set</TD>
</TR>

<TR>
  <TD>~ nndifsnid</TD>
  <TD>for a natural number</TD>
</TR>

<TR>
  <TD>~ fidifsnid</TD>
  <TD>for a finite set</TD>
</TR>

<TR>
<TD>iundif2</TD>
<TD>~ iundif2ss </TD>
</TR>

<TR>
  <TD>iindif2</TD>
  <TD>~ iindif2m</TD>
</TR>

<TR>
  <TD>iinin2</TD>
  <TD>~ iinin2m</TD>
</TR>

<TR>
  <TD>iinin1</TD>
  <TD>~ iinin1m</TD>
</TR>

<TR>
  <TD>iinvdif</TD>
  <TD>~ iindif2m</TD>
  <TD>Unused in set.mm</TD>
</TR>

<TR>
  <TD>riinn0</TD>
  <TD>~ riinm</TD>
</TR>

<TR>
  <TD>riinrab</TD>
  <TD>~ iinrabm</TD>
</TR>

<TR>
  <TD>iinuni</TD>
  <TD>~ iinuniss</TD>
</TR>

<TR>
  <TD>iununi</TD>
  <TD>~ iununir</TD>
</TR>

<TR>
  <TD>rintn0</TD>
  <TD>~ rintm</TD>
</TR>

<TR>
<TD>trintss</TD>
<TD>~ trintssm </TD>
</TR>

<TR>
  <TD>ax-rep</TD>
  <TD>~ ax-coll</TD>
  <TD>There are a lot of ways to state replacement and most/all
  of them hold, for example ~ zfrep6 or ~ funimaexg .</TD>
</TR>

<TR>
<TD>csbexg , csbex</TD>
<TD>~ csbexga , ~ csbexa </TD>
<TD>set.mm uses case elimination to remove the ` A e. _V ` condition.</TD>
</TR>

<TR>
  <TD>intex</TD>
  <TD>~ inteximm , ~ intexr</TD>
  <TD>inteximm is the forward direction
  (but for inhabited rather than non-empty classes) and intexr
  is the reverse direction.</TD>
</TR>

<TR>
  <TD>intexab</TD>
  <TD>~ intexabim</TD>
</TR>

<TR>
  <TD>intexrab</TD>
  <TD>~ intexrabim</TD>
</TR>

<TR>
  <TD>iinexg</TD>
  <TD>~ iinexgm</TD>
  <TD>Changes not empty to inhabited</TD>
</TR>

<TR>
<TD>intabs</TD>
<TD><I>none</I></TD>
<TD>Lightly used in set.mm, and the set.mm proof is not intuitionistic</TD>
</TR>

<TR>
  <TD>reuxfr2d , reuxfr2 , reuxfrd , reuxfr</TD>
  <TD><I>none</I></TD>
  <TD>The set.mm proof of reuxfr2d relies on 2reuswap</TD>
</TR>

<TR>
<TD>moabex</TD>
<TD>~ euabex </TD>
<TD>In general, most of the set.mm ` E! ` theorems still hold, but a
decent number of the ` E* ` ones get caught up on "there are two cases: the
set exists or it does not"</TD>
</TR>

<TR>
<TD>snex</TD>
<TD>~ snexg , ~ snex </TD>
<TD>The iset.mm version of ~ snex has an additional hypothesis</TD>
</TR>

<TR>
  <TD>nssss</TD>
  <TD>~ nssssr</TD>
</TR>

<TR>
  <TD>rmorabex</TD>
  <TD>~ euabex</TD>
  <TD>See discussion under moabex</TD>
</TR>

<TR>
  <TD>nnullss</TD>
  <TD>~ mss</TD>
</TR>

<TR>
<TD>opex</TD>
<TD>~ opexg , ~ opex </TD>
<TD>The iset.mm version of ~ opex has additional hypotheses</TD>
</TR>

<TR>
  <TD>otex</TD>
  <TD>~ otexg</TD>
</TR>

<TR>
<TD>df-so</TD>
<TD>~ df-iso </TD>
<TD>Although we define ` Or ` to describe a weakly linear order (such
as real numbers), there are some orders which are also trichotomous, for
example ~ nntri3or , ~ pitri3or , and ~ nqtri3or .
</TR>

<TR>
<TD ROWSPAN="5">sotric</TD>
<TD>~ sotricim </TD>
<TD>One direction, for any weak linear order.</TD>
</TR>

<TR>
<TD>~ sotritric </TD>
<TD>For a trichotomous order.</TD>
</TR>

<TR>
<TD>~ nntri2 </TD>
<TD>For the specific order ` _E Or _om `</TD>
</TR>

<TR>
<TD>~ pitric </TD>
<TD>For the specific order ` <N Or N. `</TD>
</TR>

<TR>
<TD>~ nqtric </TD>
<TD>For the specific order ` <Q Or Q. `</TD>
</TR>

<TR>
<TD>sotrieq</TD>
<TD>~ sotritrieq </TD>
<TD>For a trichotomous order</TD>
</TR>

<TR>
<TD>sotrieq2</TD>
<TD>see sotrieq and then apply ~ ioran </TD>
</TR>

<TR>
<TD>issoi</TD>
<TD>~ issod , ~ ispod </TD>
<TD>Many of the set.mm usages of issoi don't carry over, so
there is less need for this convenience theorem.</TD>
</TR>

<TR>
<TD>isso2i</TD>
<TD>~ issod </TD>
<TD>Presumably this could be proved if we need it.</TD>
</TR>

<TR>
  <TD>df-fr</TD>
  <TD>~ df-frind</TD>
</TR>

<TR>
  <TD>fri , dffr2 , frc</TD>
  <TD><I>none</I></TD>
  <TD>That any subset of the base set has an element which is
  minimal accordng to a well-founded relation presumably
  implies excluded middle (or is otherwise unprovable).</TD>
</TR>

<TR>
  <TD>frss</TD>
  <TD>~ freq2</TD>
  <TD>Because the definition of ` Fr ` is different than set.mm, the
  proof would need to be different.</TD>
</TR>

<TR>
  <TD>frirr</TD>
  <TD>~ frirrg</TD>
  <TD>We do not yet have a lot of theorems for the case where ` A ` is
  a proper class.</TD>
</TR>

<TR>
  <TD>fr2nr</TD>
  <TD><I>none</I></TD>
  <TD>Shouldn't be hard to prove if we need it (using a proof similar
  to ~frirrg and ~ en2lp ).</TD>
</TR>

<TR>
  <TD>frminex</TD>
  <TD><I>none</I></TD>
  <TD>Presumably unprovable.</TD>
</TR>

<TR>
  <TD>efrn2lp</TD>
  <TD><I>none</I></TD>
  <TD>Should be easy but lightly used in set.mm</TD>
</TR>

<TR>
  <TD>dfepfr , epfrc</TD>
  <TD><I>none</I></TD>
  <TD>Presumably unprovable.</TD>
</TR>

<TR>
<TD>df-we</TD>
<TD>~ df-wetr</TD>
</TR>

<TR>
  <TD>wess</TD>
  <TD><I>none</I></TD>
  <TD>See frss entry. Holds for ` _E ` (see for example ~ wessep ).</TD>
</TR>

<TR>
  <TD>weso</TD>
  <TD>~ wepo</TD>
</TR>

<TR>
  <TD>wecmpep</TD>
  <TD><I>none</I></TD>
  <TD>` We ` does not imply trichotomy in iset.mm</TD>
</TR>

<TR>
  <TD>wefrc , wereu , wereu2</TD>
  <TD><I>none</I></TD>
  <TD>Presumably not provable</TD>
</TR>

<TR>
<TD>dmxpid</TD>
<TD>~ dmxpm </TD>
</TR>

<TR>
<TD>relimasn</TD>
<TD>~ imasng </TD>
</TR>

<TR>
<TD>opswap</TD>
<TD>~ opswapg </TD>
</TR>

<TR>
<TD>cnvso</TD>
<TD>~ cnvsom </TD>
</TR>

<TR>
<TD>tz7.7</TD>
<TD><I>none</I></TD>
</TR>

<TR>
<TD>ordelssne</TD>
<TD><I>none</I></TD>
</TR>

<TR>
<TD>ordelpss</TD>
<TD><I>none</I></TD>
</TR>

<TR>
<TD>ordsseleq , onsseleq</TD>
<TD>~ onelss , ~ eqimss , ~ nnsseleq</TD>
<TD>Taken together, ~ onelss and ~ eqimss represent the reverse direction of
the biconditional from ordsseleq . For natural numbers the biconditional
is provable.</TD>
</TR>

<TR>
<TD>ordtri3or</TD>
<TD>~ nntri3or </TD>
<TD>Ordinal trichotomy implies the law of the excluded middle as shown
in ~ ordtriexmid .
</TR>

<TR>
<TD>ordtri2</TD>
<TD>~ nntri2 </TD>
<TD>ordtri2 for all ordinals presumably implies excluded middle although
we don't have a specific proof analogous to ~ ordtriexmid .</TD>
</TR>

<TR>
<TD>ordtri3 , ordtri4 , ordtri2or3 , dford2
</TD>
<TD><I>none</I></TD>
<TD>Ordinal trichotomy implies the law of the excluded middle as shown
in ~ ordtriexmid . We don't have similar proofs for every variation of
of trichotomy but most of them are presumably powerful enough to imply
excluded middle.</TD>
</TR>

<TR>
<TD>ordtri1 , ontri1 , onssneli , onssnel2i</TD>
<TD>~ ssnel , ~ nntri1 </TD>
<TD>~ ssnel is a trichotomy-like theorem which does hold, although
it is an implication whereas ordtri1 is a biconditional. ~ nntri1
is biconditional, but just for natural numbers.</TD>
</TR>

<TR>
<TD>ordtr2 , ontr2</TD>
<TD><I>none</I></TD>
<TD>Implies excluded middle as shown at ~ ontr2exmid</TD>
</TR>

<TR>
<TD>ordtr3</TD>
<TD><I>none</I></TD>
<TD>This is weak linearity of ordinals, which presumably
implies excluded middle by ~ ordsoexmid .</TD>
</TR>

<TR>
<TD>ord0eln0 , on0eln0</TD>
<TD>~ ne0i , ~ nn0eln0 </TD>
</TR>

<TR>
<TD>nsuceq0</TD>
<TD>~ nsuceq0g </TD>
</TR>

<TR>
<TD>ordsssuc</TD>
<TD>~ trsucss </TD>
</TR>

<TR>
<TD>ordequn</TD>
<TD><I>none</I></TD>
<TD>If you know which ordinal is larger, you can achieve
a similar result via theorems such as ~ oneluni or ~ ssequn1 .</TD>
</TR>

<TR>
<TD>ordun</TD>
<TD>~ onun2 </TD>
</TR>

<TR>
<TD>ordtri2or</TD>
<TD><I>none</I></TD>
<TD>Implies excluded middle as shown at ~ ordtri2orexmid .</TD>
</TR>

<TR>
  <TD>ordtri2or2</TD>
  <TD>~ nntri2or2</TD>
  <TD>ordtri2or2 implies excluded middle as shown at ~ ordtri2or2exmid .</TD>
</TR>

<TR>
  <TD>onsseli</TD>
  <TD><I>none</I></TD>
  <TD>See entry for ordsseleq</TD>
</TR>

<TR>
  <TD>unizlim</TD>
  <TD><I>none</I></TD>
  <TD>The reverse direction is basically ~ uni0 plus ~ limuni</TD>
</TR>

<TR>
  <TD>on0eqel</TD>
  <TD>~ 0elnn</TD>
  <TD>The full on0eqel is conjectured to imply excluded middle by
  an argument similar to ~ ordtriexmid</TD>
</TR>

<TR>
  <TD>snsn0non</TD>
  <TD><I>none</I></TD>
  <TD>Presumably would be provable (by first proving ` -. (/) e. { { (/) } } `
  as in the set.mm proof, and then using that to show that ` { { (/) } } `
  is not a transitive set).</TD>
</TR>

<TR>
  <TD>onxpdisj</TD>
  <TD><I>none</I></TD>
  <TD>Unused in set.mm</TD>
</TR>

<TR>
  <TD>onnev</TD>
  <TD><I>none</I></TD>
  <TD>Presumably provable (see snsn0non entry)</TD>
</TR>

<TR>
<TD>iotaex</TD>
<TD>~iotacl , ~ euiotaex </TD>
</TR>

<TR>
<TD>dffun3</TD>
<TD>~ dffun5r</TD>
</TR>

<TR>
<TD>dffun5</TD>
<TD>~ dffun5r</TD>
</TR>

<TR>
  <TD>dffv3</TD>
  <TD>~ dffv3g</TD>
</TR>

<TR>
<TD ROWSPAN="5">fvex</TD>
<TD>~ funfvex </TD>
<TD>when evaluating a function within its domain</TD>
</TR>

<TR>
<TD>~ fvexg , ~ fvex </TD>
<TD>when the function is a set and is evaluated at a set</TD>
</TR>

<TR>
<TD>~ relrnfvex </TD>
<TD>when evaluating a relation whose range is a set</TD>
</TR>

<TR>
<TD>~ mptfvex </TD>
<TD>when the function is defined via maps-to, yields a set for all inputs,
and is evaluated at a set</TD>
</TR>

<TR>
<TD>~ 1stexg , ~ 2ndexg </TD>
<TD>for the functions ` 1st ` and ` 2nd `</TD>
</TR>

<TR>
  <TD>fvif</TD>
  <TD>~ fvifdc</TD>
</TR>

<TR>
<TD>ndmfv</TD>
<TD>~ ndmfvg </TD>
<TD>The ` -. A e. _V ` case is ~ fvprc .</TD>
</TR>

<TR>
<TD>elfvdm</TD>
<TD>~ relelfvdm </TD>
</TR>

<TR>
<TD>elfvex</TD>
<TD>~ relelfvdm </TD>
</TR>

<TR>
  <TD>fvmptss</TD>
  <TD>~ fvmptssdm</TD>
</TR>

<TR>
  <TD>fvmptex</TD>
  <TD><I>none</I></TD>
  <TD>The set.mm proof relies on case elimination</TD>
</TR>

<TR>
  <TD>fvmptnf</TD>
  <TD><I>none</I></TD>
  <TD>The set.mm proof relies on case elimination</TD>
</TR>

<TR>
  <TD>fvmptn</TD>
  <TD><I>none</I></TD>
  <TD>The set.mm proof relies on case elimination</TD>
</TR>

<TR>
  <TD>fvmptss2</TD>
  <TD>~ fvmpt</TD>
  <TD>What fvmptss2 adds is the cases where this is a proper class,
  or we are out of the domain.</TD>
</TR>

<TR>
  <TD>fvopab4ndm</TD>
  <TD><I>none</I></TD>
</TR>

<TR>
  <TD>fndmdifeq0</TD>
  <TD><I>none</I></TD>
  <TD>Although it seems like this might be intuitionizable, it is
  lightly used in set.mm.</TD>
</TR>

<TR>
<TD>f0cli</TD>
<TD>~ ffvelrn </TD>
</TR>

<TR>
  <TD>dff3</TD>
  <TD>~ dff3im</TD>
</TR>

<TR>
  <TD>dff4</TD>
  <TD>~ dff4im</TD>
</TR>

<TR>
  <TD>fvunsn</TD>
  <TD>~ fvunsng</TD>
</TR>

<TR>
<TD>funiunfv</TD>
<TD>~ fniunfv , ~ funiunfvdm </TD>
</TR>

<TR>
<TD>funiunfvf</TD>
<TD>~ funiunfvdmf </TD>
</TR>

<TR>
<TD>eluniima</TD>
<TD>~ eluniimadm </TD>
</TR>

<TR>
<TD>riotaex</TD>
<TD>~ riotacl , ~ riotaexg</TD>
</TR>

<TR>
<TD>nfriotad</TD>
<TD>~ nfriotadxy </TD>
</TR>

<TR>
<TD>csbriota , csbriotagOLD</TD>
<TD>~ csbriotag </TD>
</TR>

<TR>
<TD>riotaxfrd</TD>
<TD><I>none</I></TD>
<TD>Although it may be intuitionizable, it is lightly used in set.mm.
The set.mm proof relies on reuxfrd .</TD>
</TR>

<TR>
<TD ROWSPAN="4">ovex</TD>
<TD>~ fnovex </TD>
<TD>when the operation is a function evaluated within its domain.</TD>
</TR>

<TR>
<TD>~ ovexg</TD>
<TD>when the operation is a set and is evaluated at a set</TD>
</TR>

<TR>
<TD>~ relrnfvex</TD>
<TD>when the operation is a relation whose range is a set</TD>
</TR>

<TR>
<TD>~ mpt2fvex </TD>
<TD>When the operation is defined via maps-to, yields a set on
any inputs, and is being evaluated at two sets.</TD>
</TR>

<TR>
<TD>fnov</TD>
<TD>~ fnovim </TD>
</TR>

<TR>
<TD>ov3</TD>
<TD>~ ovi3 </TD>
<TD>Although set.mm's ov3 could be proved, it is only used a few places
in set.mm, and in iset.mm those places need the modified form
found in ~ ovi3 .</TD>
</TR>

<TR>
<TD>oprssdm</TD>
<TD><I>none</I></TD>
</TR>

<TR>
<TD>ndmovg , ndmov</TD>
<TD>~ ndmfvg </TD>
<TD>These theorems are generally used in set.mm for case elimination
which is why we just have the general ~ ndmfvg rather than an
operation-specific version.
</TR>

<TR>
<TD>ndmovcl , ndmovcom , ndmovass , ndmovdistr , ndmovord ,
    and ndmovordi</TD>
<TD><I>none</I></TD>
<TD>These theorems are generally used in set.mm for case elimination
and the most straightforward way to avoid them is to add conditions
that we are evaluating functions within their domains.
</TR>

<TR>
<TD>ndmovrcl</TD>
<TD>~ elmpt2cl , ~ relelfvdm</TD>
</TR>

<TR>
<TD>caov4</TD>
<TD>~ caov4d </TD>
<TD>Note that ~ caov4d has a closure hypothesis.</TD>
</TR>

<TR>
<TD>caov411</TD>
<TD>~ caov411d </TD>
<TD>Note that ~ caov411d has a closure hypothesis.</TD>
</TR>

<TR>
<TD>caov42</TD>
<TD>~ caov42d </TD>
<TD>Note that ~ caov42d has a closure hypothesis.</TD>
</TR>

<TR>
<TD>caovdir</TD>
<TD>~ caovdird </TD>
<TD>~ caovdird adds some constraints about where the operations are evaluated.</TD>
</TR>

<TR>
<TD>caovdilem</TD>
<TD>~ caovdilemd </TD>
</TR>

<TR>
<TD>caovlem2</TD>
<TD>~ caovlem2d </TD>
</TR>

<TR>
<TD>caovmo</TD>
<TD>~ caovimo </TD>
</TR>

<TR>
<TD>ofval</TD>
<TD>~ fnofval </TD>
</TR>

<TR>
<TD>offn , offveq , caofid0l , caofid0r , caofid1 , caofid2</TD>
<TD><I>none</I></TD>
<TD>Assuming we really need to add conditions that the operations
are functions being evaluated within their domains, there would be a
fair bit of intuitionizing.</TD>
</TR>

<TR>
<TD>ordeleqon</TD>
<TD><I>none</I></TD>
</TR>

<TR>
<TD>ssonprc</TD>
<TD><I>none</I></TD>
<TD>not provable (we conjecture), but interesting enough to intuitionize
anyway. ` U. A = On -> A e/ V ` is provable, and
` ( B e. On /\ U. A C_ B ) -> A e. V ` is provable.
(One thing we presumably could prove is
` ( U. A C_ On /\ E. x x e. ( On \ U. A ) ) -> A e. V `
which might be easier to understand if we define (or think of) proper subset
as meaning that the set difference is inhabited.)</TD>
</TR>

<TR>
<TD>onint</TD>
<TD>~ onintss</TD>
<TD>onint implies excluded middle as shown in ~ onintexmid .</TD>
</TR>

<TR>
<TD>onint0</TD>
<TD><I>none</I></TD>
<TD>Thought to be "trivially not intuitionistic", and it is not clear if there is an alternate way to state it that is true. If the empty set is in A then of course |^| A = (/), but the converse seems difficult. I don't know so much about the structure of the ordinals without linearity,</TD>
</TR>

<TR>
<TD>onssmin, onminesb, onminsb</TD>
<TD><I>none</I></TD>
<TD>Conjectured to not be provable without excluded middle, for the same reason as onint.</TD>
</TR>

<TR>
<TD>oninton</TD>
<TD>~ onintonm</TD>
</TR>

<TR>
<TD>onintrab</TD>
<TD><I>none</I></TD>
<TD>The set.mm proof relies on the converse of ~ inteximm .</TD>
</TR>

<TR>
<TD>onintrab2</TD>
<TD>~ onintrab2im</TD>
<TD>The converse would appear to need the converse of ~ inteximm .</TD>
</TR>

<TR>
<TD>oneqmin</TD>
<TD><I>none</I></TD>
<TD>Falls as written because it implies onint, but it might be useful to keep the reverse direction for subsets that do have a minimum.</TD>
</TR>

<TR>
<TD>onminex</TD>
<TD><I>none</I></TD>
</TR>

<TR>
<TD>onmindif2</TD>
<TD><I>none</I></TD>
<TD>Conjectured to not be provable without excluded middle.</TD>
</TR>

<TR>
<TD>onmindif2</TD>
<TD><I>none</I></TD>
<TD>Conjectured to not be provable without excluded middle.</TD>
</TR>

<TR>
<TD>ordpwsuc</TD>
<TD>~ ordpwsucss </TD>
<TD>See the ~ ordpwsucss comment for discussion of the succcessor-like
properites of ` ( ~P A i^i On ) ` .  Full ordpwsuc implies excluded
middle as seen at ~ ordpwsucexmid .</TD>
</TR>

<TR>
<TD>ordsucelsuc</TD>
<TD>~ onsucelsucr , ~ nnsucelsuc </TD>
<TD>The converse of ~ onsucelsucr implies excluded middle, as shown at ~ onsucelsucexmid .</TD>
</TR>

<TR>
<TD>ordsucsssuc</TD>
<TD>~ onsucsssucr , ~ nnsucsssuc </TD>
<TD>The converse of ~ onsucsssucr implies excluded middle, as shown at ~ onsucsssucexmid .</TD>
</TR>

<TR>
<TD>ordsucuniel</TD>
<TD>~ sucunielr</TD>
<TD>Full ordsucuniel implies excluded middle, as shown at ~ ordsucunielexmid .</TD>
</TR>

<TR>
<TD>ordsucun</TD>
<TD><I>none yet</I></TD>
<TD>Conjectured to be provable in the reverse direction, but not the forward direction (implies some order totality).</TD>
</TR>

<TR>
<TD>ordunpr</TD>
<TD><I>none</I></TD>
<TD>Presumably not provable without excluded middle.</TD>
</TR>

<TR>
<TD>ordunel</TD>
<TD><I>none</I></TD>
<TD>Conjectured to not be provable (ordunel implies ordsucun).</TD>
</TR>

<TR>
<TD>onsucuni, ordsucuni</TD>
<TD><I>none</I></TD>
<TD>Conjectured to not be provable without excluded middle.</TD>
</TR>

<TR>
<TD>orduniorsuc</TD>
<TD><I>none</I></TD>
<TD>Presumably not provable.</TD>
</TR>

<TR>
<TD>ordunisuc</TD>
<TD>~ onunisuci , ~ unisuc , ~ unisucg </TD>
</TR>

<TR>
<TD>orduniss2</TD>
<TD>~ onuniss2 </TD>
</TR>

<TR>
<TD>0elsuc</TD>
<TD><I>none</I></TD>
<TD>This theorem may appear to be innocuous but it implies excluded
middle as shown at ~ 0elsucexmid .</TD>
</TR>

<TR>
<TD>onuniorsuci</TD>
<TD><I>none</I></TD>
<TD>Conjectured to not be provable without excluded middle.</TD>
</TR>

<TR>
<TD>onuninsuci, orduninsuc</TD>
<TD><I>none</I></TD>
<TD>Conjectured to be provable in the forward direction but not the reverse one.</TD>
</TR>

<TR>
<TD>ordunisuc2</TD>
<TD>~ ordunisuc2r </TD>
<TD><P>The forward direction is conjectured to imply excluded middle. Here is a sketch of the proposed proof.</P>

<P>Let om' be the set of all finite iterations of suc' A = ` ( ~P A i^i On ) ` on ` (/) `. (We can formalize this proof but not until we have om and at least finite induction.) Then om' = U. om' because if x e. om' then x = suc'^n (/) for some n, and then x C_ suc'^n (/) implies x e. suc'^(n+1) (/) e. om' so x e. U. om'.<p>

<P>Now supposing the theorem, we know that A. x e. om' suc x e. om', so in particular 2o e. om', that is, 2o = suc'^n (/) for some n. (Note that 1o = suc' (/) - see ~ pw0 .) For n = 0 and n = 1 this is clearly false, and for n = m+3 we have 1o e. suc' suc' (/) , so 2o C_ suc' suc' (/), so 2o e. suc' suc' suc' (/) C_ suc' suc' suc' suc'^m (/) = 2o, contradicting ordirr.</P>

<P>Thus 2o = suc' suc' (/) = suc' 1o. Applying this to X = ` { x e. { (/) } | ph } ` we have X C_ 1o implies X e. suc' 1o = 2o and hence X = (/) \/ X = 1o, and LEM follows (by ~ ordtriexmidlem2 for ` X = (/) ` and ~ rabsnt as seen in the ~ onsucsssucexmid proof for ` X = 1o ` ).</P>
</TD>
</TR>

<TR>
<TD>ordzsl, onzsl, dflim3, nlimon</TD>
<TD><I>none</I></TD>
</TR>

<TR>
<TD>dflim4</TD>
<TD>~ df-ilim </TD>
<TD>We conjecture that dflim4 is not equivalent to ~ df-ilim .</TD>
</TR>

<TR>
<TD>limsuc</TD>
<TD><I>none yet</I></TD>
<TD>Conjectured to be provable.</TD>
</TR>

<TR>
<TD>limsssuc</TD>
<TD><I>none yet</I></TD>
<TD>Conjectured to be provable.</TD>
</TR>

<TR>
<TD>tfinds</TD>
<TD>~ tfis3 </TD>
</TR>

<TR>
<TD>findsg</TD>
<TD>~ uzind4 </TD>
<TD>findsg presumably could be proved, but there
hasn't been a need for it.</TD>
</TR>

<TR>
<TD>xpexr2</TD>
<TD>~ xpexr2m </TD>
</TR>

<TR>
<TD>1stval</TD>
<TD>~ 1stvalg </TD>
</TR>

<TR>
<TD>2ndval</TD>
<TD>~ 2ndvalg </TD>
</TR>

<TR>
<TD>1stnpr</TD>
<TD><I>none</I></TD>
<TD>May be intuitionizable, but very lightly used in set.mm.</TD>
</TR>

<TR>
<TD>2ndnpr</TD>
<TD><I>none</I></TD>
<TD>May be intuitionizable, but very lightly used in set.mm.</TD>
</TR>

<TR>
<TD>brtpos</TD>
<TD>~ brtposg </TD>
</TR>

<TR>
<TD>ottpos</TD>
<TD>~ ottposg </TD>
</TR>

<TR>
<TD>ovtpos</TD>
<TD>~ ovtposg </TD>
</TR>

<TR>
<TD>pwuninel</TD>
<TD>~ pwuninel2 </TD>
<TD>The set.mm proof of pwuninel uses case elimination.</TD>
</TR>

<TR>
<TD>iunonOLD</TD>
<TD>~ iunon </TD>
</TR>

<TR>
<TD>smofvon2</TD>
<TD>~ smofvon2dm </TD>
</TR>

<TR>
<TD>tfr1</TD>
<TD>~ tfri1 </TD>
</TR>

<TR>
<TD>tfr2</TD>
<TD>~ tfri2 </TD>
</TR>

<TR>
<TD>tfr3</TD>
<TD>~ tfri3 </TD>
</TR>

<TR>
<TD>tfr2b , recsfnon , recsval</TD>
<TD><I>none</I></TD>
<TD>These transfinite recursion theorems are lightly used in set.mm.</TD>
</TR>

<TR>
<TD>df-rdg</TD>
<TD>~ df-irdg</TD>
<TD>This definition combines the successor and limit cases (rather than specifying them as separate cases in a way which relies on excluded middle). In the words of [Crosilla], p. "Set-theoretic principles incompatible with intuitionistic logic", "we can still define many of the familiar set-theoretic operations by transfinite recursion on ordinals (see Aczel and Rathjen 2001, Section 4.2). This is fine as long as the definitions by transfinite recursion do not make case distinctions such as in the classical ordinal cases of successor and limit."</TD>
</TR>

<TR>
<TD>rdgfnon</TD>
<TD>~ rdgifnon </TD>
</TR>

<TR>
<TD>ordge1n0</TD>
<TD>~ ordge1n0im , ~ ordgt0ge1 </TD>
</TR>

<TR>
<TD>ondif1</TD>
<TD>~ dif1o </TD>
<TD>In set.mm, ondif1 is used for Cantor Normal Form</TD>
</TR>

<TR>
<TD>ondif2 , dif20el</TD>
<TD><I>none</I></TD>
<TD>The set.mm proof is not intuitionistic</TD>
</TR>

<TR>
<TD>brwitnlem</TD>
<TD><I>none</I></TD>
<TD>The set.mm proof is not intuitionistic</TD>
</TR>

<TR>
<TD>om0r</TD>
<TD>~ om0 , ~ nnm0r </TD>
</TR>

<TR>
<TD>om00</TD>
<TD>~ nnm00 </TD>
</TR>

<TR>
<TD>om00el</TD>
<TD><I>none</I></TD>
</TR>

<TR>
<TD>suc11reg</TD>
<TD>~ suc11g </TD>
</TR>

<TR>
<TD>frfnom</TD>
<TD>~ frecfnom </TD>
<TD>frecfnom adopts the ` frec ` notation and adds conditions on the
characteristic function and initial value.</TD>
</TR>

<TR>
<TD>fr0g</TD>
<TD>~ frec0g </TD>
<TD>frec0g adopts the ` frec ` notation and adds a condition on the
characteristic function.</TD>
</TR>

<TR>
<TD>frsuc</TD>
<TD>~ frecsuc </TD>
<TD>frecsuc adopts the ` frec ` notation and adds conditions on the
characteristic function and initial value.</TD>
</TR>

<TR>
<TD>om0x</TD>
<TD>~ om0 </TD>
</TR>

<TR>
<TD>oaord1</TD>
<TD><I>none yet</I></TD>
</TR>

<TR>
<TD>oaword</TD>
<TD>~ oawordi </TD>
<TD>The other direction presumably could be proven but isn't yet.</TD>
</TR>

<TR>
<TD>omwordi</TD>
<TD>~ nnmword</TD>
<TD>The set.mm proof of omwordi relies on case elimination.</TD>
</TR>

<TR>
<TD>omword1</TD>
<TD>~ nnmword</TD>
</TR>

<TR>
<TD>nnawordex</TD>
<TD>~ nnaordex </TD>
<TD>nnawordex is only used a few places in set.mm</TD>
</TR>

<TR>
<TD>swoso</TD>
<TD><I>none</I></TD>
<TD>Unused in set.mm.</TD>
</TR>

<TR>
<TD>ecdmn0</TD>
<TD>~ ecdmn0m </TD>
</TR>

<TR>
<TD>erdisj, qsdisj, qsdisj2, uniinqs</TD>
<TD><I>none</I></TD>
<TD>These could presumably be restated to be provable, but they are lightly
used in set.mm</TD>
</TR>

<TR>
<TD>xpider</TD>
<TD>~ xpiderm </TD>
</TR>

<TR>
<TD>iiner</TD>
<TD>~ iinerm </TD>
</TR>

<TR>
<TD>riiner</TD>
<TD>~ riinerm </TD>
</TR>

<TR>
<TD>brecop2</TD>
<TD><I>none</I></TD>
<TD>This is a form of reverse closure and uses excluded
middle in its proof.</TD>
</TR>

<TR>
<TD>erov , erov2</TD>
<TD><I>none</I></TD>
<TD>Unused in set.mm.</TD>
</TR>

<TR>
<TD>eceqoveq</TD>
<TD><I>none</I></TD>
<TD>Unused in set.mm.</TD>
</TR>

<TR>
<TD>df-sdom , relsdom , brsdom , dfdom2 , sdomdom , sdomnen ,
brdom2 , bren2 , domdifsn</TD>
<TD><I>none</I></TD>
<TD>Many aspects of strict dominance as developed in set.mm rely
on excluded middle and a different definition would be needed if
we wanted strict dominance to have the expected properties.</TD>
</TR>

<TR>
<TD>en1b</TD>
<TD>~ en1bg </TD>
</TR>

<TR>
<TD>mapsnen , map1 , pw2f1olem , pw2f1o , pw2eng , pw2en</TD>
<TD><I>none</I></TD>
<TD>We have not added set exponentiation to iset.mm yet.</TD>
</TR>

<TR>
<TD>snfi</TD>
<TD>~ snfig</TD>
</TR>

<TR>
<TD>difsnen</TD>
<TD>~ fidifsnen</TD>
</TR>

<TR>
<TD>undom</TD>
<TD><I>none</I></TD>
<TD>The set.mm proof uses undif2 and we just have ~ undif2ss </TD>
</TR>

<TR>
<TD>xpdom3</TD>
<TD>~ xpdom3m </TD>
</TR>

<TR>
<TD>domunsncan</TD>
<TD><I>none</I></TD>
<TD>The set.mm proof relies on difsnen</TD>
</TR>

<TR>
<TD>omxpenlem , omxpen , omf1o</TD>
<TD><I>none</I></TD>
<TD>The set.mm proof relies on omwordi</TD>
</TR>

<TR>
<TD>enfixsn</TD>
<TD><I>none</I></TD>
<TD>The set.mm proof relies on difsnen</TD>
</TR>

<TR>
<TD>sbth and its lemmas, sbthb , sbthcl</TD>
<TD>~ fisbth</TD>
<TD>The Schroeder-Bernstein Theorem implies excluded middle</TD>
</TR>

<TR>
<TD>2pwuninel</TD>
<TD>~ 2pwuninelg</TD>
</TR>

<TR>
  <TD>php</TD>
  <TD>~ phpm</TD>
</TR>

<TR>
  <TD>snnen2o</TD>
  <TD>~ snnen2og , ~ snnen2oprc</TD>
</TR>

<TR>
<TD>onomeneq , onfin , onfin2</TD>
<TD><I>none</I></TD>
<TD>The set.mm proofs rely on excluded middle</TD>
</TR>

<TR>
<TD>nnsdomo , sucdom2 , sucdom , 0sdom1dom , sdom1</TD>
<TD><I>none</I></TD>
<TD>iset.mm doesn't yet have strict dominance</TD>
</TR>

<TR>
  <TD>1sdom2</TD>
  <TD>~ 1nen2</TD>
  <TD>Although the presence of ~ 1nen2 might make it look
  like a natural definition for strict dominance would be
  ` A ~<_ B /\ -. A ~~ B ` , that definition may be more suitable
  for finite sets than all sets, so at least for now we only
  define ` ~~ ` and express certain theorems (such as this one)
  in terms of equinumerosity which in set.mm are expressed in terms
  of strict dominance.</TD>
</TR>

<TR>
<TD>modom , modom2</TD>
<TD><I>none</I></TD>
<TD>The set.mm proofs rely on excluded middle</TD>
</TR>

<TR>
<TD>1sdom , unxpdom , unxpdom2 , sucxpdom</TD>
<TD><I>none</I></TD>
<TD>iset.mm doesn't yet have strict dominance</TD>
</TR>

<TR>
<TD>pssinf</TD>
<TD><I>none</I></TD>
<TD>The set.mm proof relies on sdomnen</TD>
</TR>

<TR>
<TD>fisseneq</TD>
<TD><I>none</I></TD>
<TD>Perhaps it would work to generalize ~ en2eqpr from two element
sets to any finite sets (presumably by induction)
and thus prove fisseneq or something which easily implies it.</TD>
</TR>

<TR>
<TD>ominf</TD>
<TD><I>none</I></TD>
<TD>Although this theorem presumably could be proved, it would
probably need a very different proof than the set.mm one</TD>
</TR>

<TR>
<TD>isinf</TD>
<TD><I>none</I></TD>
<TD>The set.mm proof uses the converse of ~ ssdif0im</TD>
</TR>

<TR>
<TD>fineqv</TD>
<TD><I>none</I></TD>
<TD>The set.mm proof relies on theorems we don't have, and even
for the theorems we do have, we'd need to carefully look at
what axioms they rely on.</TD>
</TR>

<TR>
<TD>pssnn</TD>
<TD><I>none</I></TD>
<TD>The set.mm proof uses excluded middle.</TD>
</TR>

<TR>
<TD>ssnnfi</TD>
<TD><I>none</I></TD>
<TD>The proof in ~ ssfiexmid would apply to this as well as to
ssfi , since ` { (/) } e. _om `</TD>
</TR>

<TR>
<TD>ssfi</TD>
<TD><I>none</I></TD>
<TD>Implies excluded middle as shown at ~ ssfiexmid</TD>
</TR>

<TR>
<TD>domfi</TD>
<TD><I>none</I></TD>
<TD>Implies excluded middle as shown at ~ domfiexmid</TD>
</TR>

<TR>
<TD>xpfir</TD>
<TD><I>none</I></TD>
<TD>Nonempty would need to be changed to inhabited, but the
set.mm proof also uses domfi</TD>
</TR>

<TR>
<TD>infi</TD>
<TD><I>none</I></TD>
<TD>Implies excluded middle as shown at ~ infiexmid</TD>
</TR>

<TR>
<TD>rabfi</TD>
<TD><I>none</I></TD>
<TD>Presumably the proof of ~ ssfiexmid could be adapted to show
this implies excluded middle</TD>
</TR>

<TR>
<TD>finresfin</TD>
<TD><I>none</I></TD>
<TD>The set.mm proof is in terms of ssfi</TD>
</TR>

<TR>
<TD>f1finf1o</TD>
<TD><I>none</I></TD>
<TD>The set.mm proof is not intuitionistic</TD>
</TR>

<TR>
<TD>nfielex</TD>
<TD><I>none</I></TD>
<TD>The set.mm proof relies on neq0</TD>
</TR>

<TR>
<TD>en1eqsn , en1eqsnbi</TD>
<TD><I>none</I></TD>
<TD>The set.mm proof relies on fisseneq</TD>
</TR>

<TR>
<TD>diffi</TD>
<TD>~ diffisn , ~ diffifi</TD>
<TD>diffi is not provable, as shown at ~ diffitest</TD>
</TR>

<TR>
  <TD>enp1ilem , enp1i , en2 , en3 , en4</TD>
  <TD><I>none</I></TD>
  <TD>The set.mm proof relies on excluded middle and undif1</TD>
</TR>

<TR>
  <TD>findcard3</TD>
  <TD><I>none</I></TD>
  <TD>The set.mm proof is in terms of strict dominance.</TD>
</TR>

<TR>
  <TD>frfi</TD>
  <TD><I>none</I></TD>
  <TD>Not known whether this can be proved (either with the current
  ~ df-frind or any other possible concept analogous to ` Fr ` ).</TD>
</TR>

<TR>
  <TD>fimax2g , fimaxg</TD>
  <TD><I>none</I></TD>
  <TD>The set.mm proof relies on frfi and fri</TD>
</TR>

<TR>
  <TD ROWSPAN="3">unfi</TD>
  <TD>~ unsnfi</TD>
  <TD>For the union of a set and a singleton whose element is not
  a member of that set</TD>
</TR>

<TR>
  <TD><I>for the union of two disjoint sets</I></TD>
  <TD>presumably provable</TD>
</TR>

<TR>
  <TD><I>for any two finite sets</I></TD>
  <TD>Not provable according to Remark 8.1.17 of [AczelRathjen].</TD>
</TR>

<TR>
  <TD>prfi</TD>
  <TD><I>none</I></TD>
  <TD>The set.mm proof depends on unfi and it would appear that
  mapping ` { A , B } ` to a natural number would decide whether
  ` A ` and ` B ` are equal and thus imply excluded middle.</TD>
</TR>

<TR>
  <TD>dmfi</TD>
  <TD>~ fundmfi</TD>
</TR>

<TR>
  <TD>resfnfinfin</TD>
  <TD><I>none</I></TD>
  <TD>Presumably would need to have a ` B C_ A ` condition added,
  but lightly used in set.mm</TD>
</TR>

<TR>
  <TD>residfi</TD>
  <TD><I>none</I></TD>
  <TD>Presumably provable, but lightly used in set.mm</TD>
</TR>

<TR>
  <TD>cnvfi</TD>
  <TD>~ relcnvfi</TD>
</TR>

<TR>
  <TD>rnfi</TD>
  <TD>~ funrnfi</TD>
</TR>

<TR>
  <TD>abrexfi</TD>
  <TD><I>none</I></TD>
  <TD>At first glance it would appear that the mapping would need to
  be one to one or some other condition.</TD>
</TR>

<TR>
  <TD>dfsup2</TD>
  <TD><I>none</I></TD>
  <TD>The set.mm proof uses excluded middle in several places and the
  theorem is lightly used in set.mm.</TD>
</TR>

<TR>
  <TD>supmo</TD>
  <TD>~ supmoti</TD>
  <TD>The conditions on the order are different.</TD>
</TR>

<TR>
  <TD>supexd , supex</TD>
  <TD><I>none</I></TD>
  <TD>The set.mm proof uses rmorabex</TD>
</TR>

<TR>
  <TD>supeu</TD>
  <TD>~ supeuti</TD>
</TR>

<TR>
  <TD>supval2</TD>
  <TD>~ supval2ti</TD>
</TR>

<TR>
  <TD>eqsup</TD>
  <TD>~ eqsupti</TD>
</TR>

<TR>
  <TD>eqsupd</TD>
  <TD>~ eqsuptid</TD>
</TR>

<TR>
  <TD>supcl</TD>
  <TD>~ supclti</TD>
</TR>

<TR>
  <TD>supub</TD>
  <TD>~ supubti</TD>
</TR>

<TR>
  <TD>suplub</TD>
  <TD>~ suplubti</TD>
</TR>

<TR>
  <TD>suplub2</TD>
  <TD>~ suplub2ti</TD>
</TR>

<TR>
  <TD>supnub</TD>
  <TD><I>none</I></TD>
  <TD>Presumably provable, although the set.mm proof relies on
  excluded middle and it is not used until later in set.mm.</TD>
</TR>

<TR>
  <TD>sup0riota , sup0 , infempty</TD>
  <TD><I>none</I></TD>
  <TD>Suitably modified verions may be provable, but they
  are unused in set.mm.</TD>
</TR>

<TR>
  <TD>supmax</TD>
  <TD>~ supmaxti</TD>
</TR>

<TR>
  <TD>fisup2g , fisupcl</TD>
  <TD><I>none</I></TD>
  <TD>Other variations may be possible, but the set.mm proof will not
  work as-is or with small modifications.</TD>
</TR>

<TR>
  <TD>supgtoreq</TD>
  <TD><I>none</I></TD>
  <TD>The set.mm proof uses fisup2g and also trichotomy.</TD>
</TR>

<TR>
  <TD>suppr</TD>
  <TD><I>none</I></TD>
  <TD>The formulation using ` if ` would seem to require a trichotomous
  order. For real numbers, supremum on a pair does yield the maximum of
  two numbers: see ~ maxcl , ~ maxle1 , ~ maxle2 , ~ maxleast ,
  and ~ maxleb .</TD>
</TR>

<TR>
  <TD>supiso</TD>
  <TD>~ supisoti</TD>
</TR>

<TR>
  <TD>infexd , infex</TD>
  <TD><I>none</I></TD>
  <TD>See supexd</TD>
</TR>

<TR>
  <TD>eqinf , eqinfd</TD>
  <TD>~ eqinfti , ~ eqinftid</TD>
</TR>

<TR>
  <TD>infval</TD>
  <TD>~ infvalti</TD>
</TR>

<TR>
  <TD>infcllem</TD>
  <TD>~ cnvinfex</TD>
  <TD>infcllem has an unnecessary hypothesis; other than that
  these are the same</TD>
</TR>

<TR>
  <TD>infcl</TD>
  <TD>infclti</TD>
</TR>

<TR>
  <TD>inflb</TD>
  <TD>~ inflbti</TD>
</TR>

<TR>
  <TD>infglb</TD>
  <TD>~ infglbti</TD>
</TR>

<TR>
  <TD>infglbb</TD>
  <TD><I>none</I></TD>
  <TD>Presumably provable with additional conditions (see suplub2)</TD>
</TR>

<TR>
  <TD>infnlb</TD>
  <TD>~ infnlbti</TD>
</TR>

<TR>
  <TD>infmin</TD>
  <TD>~ infminti</TD>
</TR>

<TR>
  <TD>infmo</TD>
  <TD>~ infmoti</TD>
</TR>

<TR>
  <TD>infeu</TD>
  <TD>~ infeuti</TD>
</TR>

<TR>
  <TD>fimin2g , fiming</TD>
  <TD><I>none</I></TD>
  <TD>The set.mm proof relies on frfi and fri</TD>
</TR>

<TR>
  <TD>fiinfg , fiinf2g</TD>
  <TD><I>none</I></TD>
  <TD>The set.mm proof relies on fiming</TD>
</TR>

<TR>
  <TD>fiinfcl</TD>
  <TD><I>none</I></TD>
  <TD>See fisupcl</TD>
</TR>

<TR>
  <TD>infltoreq</TD>
  <TD><I>none</I></TD>
  <TD>The set.mm proof depends on supgtoreq and fiinfcl</TD>
</TR>

<TR>
  <TD>infpr</TD>
  <TD><I>none</I></TD>
  <TD>See suppr</TD>
</TR>

<TR>
  <TD>infsn</TD>
  <TD>~ infsnti</TD>
</TR>

<TR>
  <TD>infiso</TD>
  <TD>~ infisoti</TD>
</TR>

<TR>
<TD>ax-reg , axreg2 , zfregcl</TD>
<TD>~ ax-setind </TD>
<TD>ax-reg implies excluded middle as seen at ~ regexmid</TD>
</TR>

<TR>
  <TD>df-rank and all theorems related to the rank function</TD>
  <TD><I>none</I></TD>
  <TD>One possible definition is Definition 9.3.4
  of [AczelRathjen], p. 91</TD>
</TR>

<TR>
  <TD>df-aleph and all theorems involving aleph</TD>
  <TD><I>none</I></TD>
</TR>

<TR>
  <TD>df-cf and all theorems involving cofinality</TD>
  <TD><I>none</I></TD>
</TR>

<TR>
  <TD>df-acn and all theorems using this definition</TD>
  <TD><I>none</I></TD>
</TR>

<TR>
  <TD>cardf2 , cardon , isnum2</TD>
  <TD>~ cardcl , ~ isnumi</TD>
  <TD>It would also be easy to prove ` Fun card `
  if there is a need.</TD>
</TR>

<TR>
  <TD>ennum</TD>
  <TD><I>none</I></TD>
  <TD>The set.mm proof relies on isnum2</TD>
</TR>

<TR>
  <TD>tskwe</TD>
  <TD><I>none</I></TD>
  <TD>Relies on df-sdom</TD>
</TR>

<TR>
  <TD>xpnum</TD>
  <TD><I>none</I></TD>
  <TD>The set.mm proof relies on isnum2</TD>
</TR>

<TR>
  <TD>cardval3</TD>
  <TD>~ cardval3ex</TD>
</TR>

<TR>
  <TD>cardid2</TD>
  <TD><I>none</I></TD>
  <TD>The set.mm proof relies on onint</TD>
</TR>

<TR>
  <TD>isnum3</TD>
  <TD><I>none</I></TD>
</TR>

<TR>
  <TD>oncardid</TD>
  <TD><I>none</I></TD>
  <TD>The set.mm proof relies on cardid2</TD>
</TR>

<TR>
  <TD>cardidm</TD>
  <TD><I>none</I></TD>
  <TD>Presumably this would need a condition on ` A `
  but even with that, the set.mm proof relies on
  cardid2</TD>
</TR>

<TR>
  <TD>oncard</TD>
  <TD><I>none</I></TD>
  <TD>The set.mm proof relies on theorems we don't have,
  and this theorem is unused in set.mm.</TD>
</TR>

<TR>
  <TD>ficardom</TD>
  <TD><I>none</I></TD>
  <TD>Both the set.mm proof, and perhaps some possible alternative
  proofs, rely on onomeneq and perhaps other theorems we don't have
  currently.</TD>
</TR>

<TR>
  <TD>ficardid</TD>
  <TD><I>none</I></TD>
  <TD>The set.mm proof relies on cardid2</TD>
</TR>

<TR>
  <TD>cardnn</TD>
  <TD><I>none</I></TD>
  <TD>The set.mm proof relies on a variety of theorems we don't have
  currently.</TD>
</TR>

<TR>
  <TD>cardnueq0</TD>
  <TD><I>none</I></TD>
  <TD>The set.mm proof relies on cardid2</TD>
</TR>

<TR>
  <TD>cardne</TD>
  <TD><I>none</I></TD>
  <TD>The set.mm proof relies on ordinal trichotomy (and if that can be
  solved there might be some more minor problems which require revisions
  to the theorem)</TD>
</TR>

<TR>
  <TD>carden2a</TD>
  <TD><I>none</I></TD>
  <TD>The set.mm proof relies on excluded middle.</TD>
</TR>

<TR>
  <TD>carden2b</TD>
  <TD>~ carden2bex</TD>
</TR>

<TR>
  <TD>card1 , cardsn</TD>
  <TD><I>none</I></TD>
  <TD>Rely on a variety of theorems we don't currently have.
  Lightly used in set.mm.</TD>
</TR>

<TR>
  <TD>carddomi2</TD>
  <TD><I>none</I></TD>
  <TD>The set.mm proof relies on excluded middle.</TD>
</TR>

<TR>
  <TD>sdomsdomcardi</TD>
  <TD><I>none</I></TD>
  <TD>Relies on a variety of theorems we don't currently have.</TD>
</TR>

<TR>
  <TD>entri3</TD>
  <TD>~ fientri3</TD>
  <TD>Because full entri3 is equivalent to the axiom of choice,
  it implies excluded middle.</TD>
</TR>

<TR>
  <TD>df-wina , df-ina , df-tsk , df-gru , ax-groth and all theorems
  related to inaccessibles and large cardinals</TD>
  <TD><I>none</I></TD>
  <TD>For an introduction to inaccessibles and large set properties
  see Chapter 18 of [AczelRathjen], p. 165 (including why "large set
  properties" is more apt terminology than "large cardinal
  properties" in the absence of excluded middle).</TD>
</TR>

<TR>
<TD>addcompi</TD>
<TD>~ addcompig </TD>
</TR>

<TR>
<TD>addasspi</TD>
<TD>~ addasspig </TD>
</TR>

<TR>
<TD>mulcompi</TD>
<TD>~ mulcompig </TD>
</TR>

<TR>
<TD>mulasspi</TD>
<TD>~ mulasspig </TD>
</TR>

<TR>
<TD>distrpi</TD>
<TD>~ distrpig </TD>
</TR>

<TR>
<TD>addcanpi</TD>
<TD>~ addcanpig </TD>
</TR>

<TR>
<TD>mulcanpi</TD>
<TD>~ mulcanpig </TD>
</TR>

<TR>
<TD>addnidpi</TD>
<TD>~ addnidpig </TD>
</TR>

<TR>
<TD>ltapi</TD>
<TD>~ ltapig </TD>
</TR>

<TR>
<TD>ltmpi</TD>
<TD>~ ltmpig </TD>
</TR>

<TR>
<TD>nlt1pi</TD>
<TD>~ nlt1pig </TD>
</TR>

<TR>
<TD>df-nq</TD>
<TD>~ df-nqqs </TD>
</TR>

<TR>
<TD>df-nq</TD>
<TD>~ df-nqqs </TD>
</TR>

<TR>
<TD>df-erq</TD>
<TD><I>none</I></TD>
<TD>Not needed given ~ df-nqqs </TD>
</TR>

<TR>
<TD>df-plq</TD>
<TD>~ df-plqqs </TD>
</TR>

<TR>
<TD>df-mq</TD>
<TD>~ df-mqqs </TD>
</TR>

<TR>
<TD>df-1nq</TD>
<TD>~ df-1nqqs </TD>
</TR>

<TR>
<TD>df-ltnq</TD>
<TD>~ df-ltnqqs </TD>
</TR>

<TR>
<TD>elpqn</TD>
<TD><I>none</I></TD>
<TD>Not needed given ~ df-nqqs </TD>
</TR>

<TR>
<TD>ordpipq</TD>
<TD>~ ordpipqqs </TD>
</TR>

<TR>
<TD>addnqf</TD>
<TD>~ dmaddpq , ~ addclnq </TD>
<TD>It should be possible to prove that ` +Q ` is a function, but
so far there hasn't been a need to do so.</TD>
</TR>

<TR>
<TD>addcomnq</TD>
<TD>~ addcomnqg </TD>
</TR>

<TR>
<TD>mulcomnq</TD>
<TD>~ mulcomnqg </TD>
</TR>

<TR>
<TD>mulassnq</TD>
<TD>~ mulassnqg </TD>
</TR>

<TR>
<TD>recmulnq</TD>
<TD>~ recmulnqg </TD>
</TR>

<TR>
<TD>ltanq</TD>
<TD>~ ltanqg </TD>
</TR>

<TR>
<TD>ltmnq</TD>
<TD>~ ltmnqg </TD>
</TR>

<TR>
<TD>ltexnq</TD>
<TD>~ ltexnqq </TD>
</TR>

<TR>
<TD>archnq</TD>
<TD>~ archnqq </TD>
</TR>

<TR>
<TD>df-np</TD>
<TD>~ df-inp </TD>
</TR>

<TR>
<TD>df-1p</TD>
<TD>~ df-i1p </TD>
</TR>

<TR>
<TD>df-plp</TD>
<TD>~ df-iplp </TD>
</TR>

<TR>
<TD>df-ltp</TD>
<TD>~ df-iltp </TD>
</TR>

<TR>
<TD>elnp , elnpi</TD>
<TD>~ elinp </TD>
</TR>

<TR>
<TD>prn0</TD>
<TD>~ prml , ~ prmu </TD>
</TR>

<TR>
<TD>prpssnq</TD>
<TD>~ prssnql , ~ prssnqu </TD>
</TR>

<TR>
<TD>elprnq</TD>
<TD>~ elprnql , ~ elprnqu </TD>
</TR>

<TR>
<TD>prcdnq</TD>
<TD>~ prcdnql , ~ prcunqu </TD>
</TR>

<TR>
<TD>prub</TD>
<TD>~ prubl </TD>
</TR>

<TR>
<TD>prnmax</TD>
<TD>~ prnmaxl </TD>
</TR>

<TR>
<TD>npomex</TD>
<TD><I>none</I></TD>
</TR>

<TR>
<TD>prnmadd</TD>
<TD>~ prnmaddl </TD>
</TR>

<TR>
<TD>genpv</TD>
<TD>~ genipv </TD>
</TR>

<TR>
<TD>genpcd</TD>
<TD>~ genpcdl </TD>
</TR>

<TR>
<TD>genpnmax</TD>
<TD>~ genprndl</TD>
</TR>

<TR>
<TD>ltrnq</TD>
<TD>~ltrnqg , ~ ltrnqi </TD>
</TR>

<TR>
<TD>genpcl</TD>
<TD>~ addclpr , ~ mulclpr </TD>
</TR>

<TR>
<TD>genpass</TD>
<TD>~ genpassg </TD>
</TR>

<TR>
<TD>addclprlem1</TD>
<TD>~ addnqprllem , ~ addnqprulem </TD>
</TR>

<TR>
<TD>addclprlem2</TD>
<TD>~ addnqprl , ~ addnqpru </TD>
</TR>

<TR>
<TD>plpv</TD>
<TD>~ plpvlu </TD>
</TR>

<TR>
<TD>mpv</TD>
<TD>~ mpvlu </TD>
</TR>

<TR>
<TD>nqpr</TD>
<TD>~ nqprlu </TD>
</TR>

<TR>
<TD>mulclprlem</TD>
<TD>~ mulnqprl , ~ mulnqpru </TD>
</TR>

<TR>
<TD>addcompr</TD>
<TD>~ addcomprg </TD>
</TR>

<TR>
<TD>addasspr</TD>
<TD>~ addassprg </TD>
</TR>

<TR>
<TD>mulcompr</TD>
<TD>~ mulcomprg </TD>
</TR>

<TR>
<TD>mulasspr</TD>
<TD>~ mulassprg </TD>
</TR>

<TR>
<TD>distrlem1pr</TD>
<TD>~ distrlem1prl , ~ distrlem1pru </TD>
</TR>

<TR>
<TD>distrlem4pr</TD>
<TD>~ distrlem4prl , ~ distrlem4pru </TD>
</TR>

<TR>
<TD>distrlem5pr</TD>
<TD>~ distrlem5prl , ~ distrlem5pru </TD>
</TR>

<TR>
<TD>distrpr</TD>
<TD>~ distrprg </TD>
</TR>

<TR>
<TD>ltprord</TD>
<TD>~ ltprordil </TD>
<TD>There hasn't yet been a need to investigate versions which are
biconditional or which involve proper subsets.</TD>
</TR>

<TR>
<TD>psslinpr</TD>
<TD>~ ltsopr </TD>
</TR>

<TR>
<TD>prlem934</TD>
<TD>~ prarloc2 </TD>
</TR>

<TR>
<TD>ltaddpr2</TD>
<TD>~ ltaddpr </TD>
</TR>

<TR>
<TD>ltexprlem1 , ltexprlem2 , ltexprlem3 , ltexprlem4</TD>
<TD><I>none</I></TD>
<TD>See the lemmas for ~ ltexpri generally.</TD>
</TR>

<TR>
<TD>ltexprlem5</TD>
<TD>~ ltexprlempr </TD>
</TR>

<TR>
<TD>ltexprlem6</TD>
<TD>~ ltexprlemfl , ~ ltexprlemfu </TD>
</TR>

<TR>
<TD>ltexprlem7</TD>
<TD>~ ltexprlemrl , ~ ltexprlemru </TD>
</TR>

<TR>
<TD>ltapr</TD>
<TD>~ ltaprg </TD>
</TR>

<TR>
<TD>addcanpr</TD>
<TD>~ addcanprg </TD>
</TR>

<TR>
<TD>prlem936</TD>
<TD>~ prmuloc2 </TD>
</TR>

<TR>
<TD>reclem2pr</TD>
<TD>~ recexprlempr </TD>
</TR>

<TR>
<TD>reclem3pr</TD>
<TD>~ recexprlem1ssl , ~ recexprlem1ssu </TD>
</TR>

<TR>
<TD>reclem4pr</TD>
<TD>~ recexprlemss1l , ~ recexprlemss1u , ~ recexprlemex </TD>
</TR>

<TR>
<TD>supexpr , suplem1pr , suplem2pr</TD>
<TD>~ caucvgprpr</TD>
<TD>The Least Upper Bound property for sets of real numbers does not hold,
in general, without excluded middle. We express completeness using
sequences.</TD>
</TR>

<TR>
<TD>mulcmpblnrlem</TD>
<TD>~ mulcmpblnrlemg </TD>
</TR>

<TR>
<TD>ltsrpr</TD>
<TD>~ ltsrprg </TD>
</TR>

<TR>
<TD>dmaddsr , dmmulsr</TD>
<TD><I>none</I></TD>
<TD>Although these presumably could be proved in a way similar
to ~ dmaddpq and ~dmmulpq (in fact ~ dmaddpqlem would seem to
be easily generalizable to anything of the form
` ( ( S X. T ) /. R ) ` ), we haven't yet had a need to do so.
</TR>

<TR>
<TD>addcomsr</TD>
<TD>~ addcomsrg </TD>
</TR>

<TR>
<TD>addasssr</TD>
<TD>~ addasssrg </TD>
</TR>

<TR>
<TD>mulcomsr</TD>
<TD>~ mulcomsrg </TD>
</TR>

<TR>
<TD>mulasssr</TD>
<TD>~ mulasssrg </TD>
</TR>

<TR>
<TD>distrsr</TD>
<TD>~ distrsrg </TD>
</TR>

<TR>
<TD>ltasr</TD>
<TD>~ ltasrg </TD>
</TR>

<TR>
<TD>sqgt0sr</TD>
<TD>~ mulgt0sr , ~ apsqgt0 </TD>
</TR>

<TR>
<TD>recexsr</TD>
<TD>~ recexsrlem </TD>
<TD>This would follow from sqgt0sr (as in the set.mm proof of recexsr),
but "not equal to zero" would need to be changed to
"apart from zero".</TD>
</TR>

<TR>
<TD>mappsrpr , ltpsrpr , map2psrpr</TD>
<TD>~ prsrpos , ~ prsrlt , ~ srpospr</TD>
</TR>

<TR>
<TD>supsrlem , supsr</TD>
<TD>~ caucvgsr</TD>
<TD>The Least Upper Bound property for sets of real numbers does not hold,
in general, without excluded middle. We express completeness using
sequences.</TD>
</TR>

<TR>
<TD>axaddf , ax-addf , axmulf , ax-mulf</TD>
<TD><I>none</I></TD>
<TD>Because these are described as deprecated in set.mm, we haven't
figured out what would be involved in proving them for iset.mm.</TD>
</TR>

<TR>
<TD>ax1ne0 , ax-1ne0</TD>
<TD>~ ax0lt1 , ~ ax-0lt1 , ~ 1ap0 , ~ 1ne0 </TD>
</TR>

<TR>
<TD>axrrecex , ax-rrecex</TD>
<TD>~ axprecex , ~ ax-precex </TD>
</TR>

<TR>
<TD>axpre-lttri , ax-pre-lttri</TD>
<TD>~ axpre-ltirr , ~ axpre-ltwlin , ~ ax-pre-ltirr , ~ ax-pre-ltwlin </TD>
</TR>

<TR>
<TD>axpre-sup , ax-pre-sup , axsup</TD>
<TD>~ axcaucvg , ~ ax-caucvg , ~ caucvgre</TD>
<TD>The Least Upper Bound property for sets of real numbers does not hold,
in general, without excluded middle. We express completeness using
sequences.</TD>
</TR>

<TR>
<TD>elimne0</TD>
<TD><I>none</I></TD>
<TD>Even in set.mm, the weak deduction theorem is discouraged in
favor of theorems in deduction form.</TD>
</TR>

<TR>
<TD>xrltnle</TD>
<TD>~ xrlenlt </TD>
</TR>

<TR>
<TD>ssxr</TD>
<TD>~ df-xr </TD>
<TD>Lightly used in set.mm</TD>
</TR>

<TR>
<TD>ltnle , ltnlei , ltnled</TD>
<TD>~ lenlt , ~ zltnle </TD>
</TR>

<TR>
<TD>lttri2 , lttri2i , lttri2d</TD>
<TD>~ qlttri2</TD>
<TD>Real number trichotomy is not provable.</TD>
</TR>

<TR>
<TD>lttri4</TD>
<TD>~ ztri3or , ~ qtri3or</TD>
<TD>Real number trichotomy is not provable.</TD>
</TR>

<TR>
<TD>leloe , eqlelt , leloei , leloed , eqleltd</TD>
<TD><I>none</I></TD>
</TR>

<TR>
<TD>leltne , leltned</TD>
<TD>~ leltap , ~ leltapd</TD>
</TR>

<TR>
<TD>ltneOLD</TD>
<TD>~ ltne , ~ ltap</TD>
</TR>

<TR>
<TD>letric , letrii , letrid</TD>
<TD>~ zletric , ~ qletric</TD>
</TR>

<TR>
<TD>ltlen , ltleni , ltlend</TD>
<TD>~ ltleap , ~ zltlen , ~ qltlen</TD>
</TR>

<TR>
<TD>ne0gt0 , ne0gt0d</TD>
<TD>~ ap0gt0 , ~ ap0gt0d</TD>
</TR>

<TR>
<TD>lecasei , ltlecasei</TD>
<TD><I>none</I></TD>
<TD>These are real number trichotomy</TD>
</TR>

<TR>
<TD>lelttric</TD>
<TD>~ zlelttric , ~ qlelttric</TD>
</TR>

<TR>
<TD>lttrid , lttri4d</TD>
<TD><I>none</I></TD>
<TD>These are real number trichotomy</TD>
</TR>

<TR>
  <TD>leneltd</TD>
  <TD>~ leltapd</TD>
</TR>

<TR>
<TD>dedekind , dedekindle</TD>
<TD><I>none</I></TD>
</TR>

<TR>
<TD>mul02lem1</TD>
<TD><I>none</I></TD>
<TD>The one use in set.mm is not needed in iset.mm.</TD>
</TR>

<TR>
<TD>negex</TD>
<TD>~ negcl </TD>
</TR>

<TR>
<TD>msqgt0 , msqgt0i , msqgt0d</TD>
<TD>~ apsqgt0 </TD>
<TD>"Not equal to zero" is changed to "apart from zero"</TD>
</TR>

<TR>
<TD>relin01</TD>
<TD><I>none</I></TD>
<TD>Relies on real number trichotomy.</TD>
</TR>

<TR>
<TD>ltordlem , ltord1 , leord1 , eqord1 , ltord2 , leord2 , eqord2</TD>
<TD><I>none</I></TD>
<TD>Although these presumably could be proved using theorems like
~ letri3 and ~ lenlt , at least for now we have chosen to just invoke
those other theorems directly (example: ~ expcan and its lemma
~ expcanlem ) which avoids some extra set variables and produces proofs
which are almost as short.</TD>
</TR>

<TR>
<TD>wloglei , wlogle</TD>
<TD><I>none</I></TD>
<TD>These depend on real number trichotomy and are not used until
later in set.mm.</TD>
</TR>

<TR>
<TD>recex</TD>
<TD>~ recexap </TD>
<TD>In theorems involving reciprocals or division, not equal to
zero changes to apart from zero.</TD>
</TR>

<TR>
<TD>mulcand, mulcan2d</TD>
<TD>~ mulcanapd , ~ mulcanap2d </TD>
<TD>In theorems involving reciprocals or division, not equal to
zero changes to apart from zero.</TD>
</TR>

<TR>
<TD>mulcanad , mulcan2ad</TD>
<TD>~ mulcanapad , ~ mulcanap2ad</TD>
<TD>In theorems involving reciprocals or division, not equal to
zero changes to apart from zero.</TD>
</TR>

<TR>
<TD>mulcan , mulcan2 , mulcani</TD>
<TD>~ mulcanap , ~ mulcanap2 , ~ mulcanapi </TD>
<TD>In theorems involving reciprocals or division, not equal to
zero changes to apart from zero.</TD>
</TR>

<TR>
<TD>mul0or , mul0ori , mul0ord</TD>
<TD><I>none</I></TD>
<TD>Remark 2.19 of [Geuvers] says that this does not hold in
general and has a counterexample.</TD>
</TR>

<TR>
<TD>mulne0b , mulne0bd , mulne0bad , mulne0bbd</TD>
<TD>~ mulap0b , ~ mulap0bd , ~ mulap0bad , ~ mulap0bbd </TD>
</TR>

<TR>
<TD>mulne0 , mulne0i , mulne0d</TD>
<TD>~ mulap0 , ~ mulap0i , ~ mulap0d </TD>
</TR>

<TR>
<TD>receu</TD>
<TD>~ receuap </TD>
<TD>In theorems involving reciprocals or division, not equal to
zero changes to apart from zero.</TD>
</TR>

<TR>
<TD>mulnzcnopr</TD>
<TD><I>none</I></TD>
</TR>

<TR>
<TD>msq0i , msq0d</TD>
<TD>~ sqeq0 , ~ sqeq0i</TD>
<TD>These slight restatements of sqeq0 are unused in set.mm.</TD>
</TR>

<TR>
<TD>mulcan1g , mulcan2g</TD>
<TD><I>various cancellation theorems</I></TD>
<TD>Presumably this is unavailable for the same reason that mul0or
is unavailable.</TD>
</TR>

<TR>
<TD>1div0</TD>
<TD><I>none</I></TD>
<TD>This could be proved, but the set.mm proof does not work as-is.</TD>
</TR>

<TR>
<TD>divval</TD>
<TD>~ divvalap </TD>
<TD>In theorems involving reciprocals or division, not equal to
zero changes to apart from zero.</TD>
</TR>

<TR>
<TD>divmul , divmul2 , divmul3</TD>
<TD>~ divmulap , ~ divmulap2 , divmulap3 </TD>
<TD>In theorems involving reciprocals or division, not equal to
zero changes to apart from zero.</TD>
</TR>

<TR>
<TD>divcl , reccl</TD>
<TD>~ divclap , ~ recclap </TD>
<TD>In theorems involving reciprocals or division, not equal to
zero changes to apart from zero.</TD>
</TR>

<TR>
<TD>divcan1 , divcan2</TD>
<TD>~ divcanap1 , ~ divcanap2 </TD>
<TD>In theorems involving reciprocals or division, not equal to
zero changes to apart from zero.</TD>
</TR>

<TR>
<TD>diveq0</TD>
<TD>~ diveqap0 </TD>
<TD>In theorems involving reciprocals or division, not equal to
zero changes to apart from zero.</TD>
</TR>

<TR>
<TD>divne0b , divne0</TD>
<TD>~ divap0b , ~ divap0 </TD>
</TR>

<TR>
<TD>recne0</TD>
<TD>~ recap0 </TD>
</TR>

<TR>
<TD>recid , recid2</TD>
<TD>~ recidap , ~ recidap2 </TD>
</TR>

<TR>
<TD>divrec</TD>
<TD>~ divrecap </TD>
</TR>

<TR>
<TD>divrec2</TD>
<TD>~ divrecap2  </TD>
</TR>

<TR>
<TD>divass</TD>
<TD>~ divassap </TD>
</TR>

<TR>
<TD>div23 , div32 , div13 , div12</TD>
<TD>~ div23ap , ~ div32ap , ~ div13ap , ~ div12ap </TD>
</TR>

<TR>
  <TD>divmulass</TD>
  <TD>~ divmulassap</TD>
</TR>

<TR>
  <TD>divmulasscom</TD>
  <TD>~ divmulasscomap</TD>
</TR>

<TR>
<TD>divdir , divcan3 , divcan4</TD>
<TD>~ divdirap , ~ divcanap3 , ~ divcanap4 </TD>
</TR>

<TR>
<TD>div11 , divid , div0</TD>
<TD>~ div11ap , ~ dividap , ~ div0ap </TD>
</TR>

<TR>
<TD>diveq1 , divneg</TD>
<TD>~ diveqap1 , ~ divnegap</TD>
</TR>

<TR>
  <TD>muldivdir</TD>
  <TD>~ muldivdirap</TD>
</TR>

<TR>
  <TD>divsubdir</TD>
  <TD>~ divsubdirap</TD>
</TR>

<TR>
<TD>recrec , rec11 , rec11r</TD>
<TD>~ recrecap , ~ rec11ap , ~ rec11rap </TD>
</TR>

<TR>
<TD>divmuldiv , divdivdiv , divcan5</TD>
<TD>~ divmuldivap , ~ divdivdivap , ~ divcanap5 </TD>
</TR>

<TR>
<TD>divmul13 , divmul24 , divmuleq</TD>
<TD>~ divmul13ap , ~ divmul24ap , ~ divmuleqap </TD>
</TR>

<TR>
<TD>recdiv , divcan6 , divdiv32 , divcan7</TD>
<TD>~ recdivap , ~ divcanap6 , ~ divdiv32ap , ~ divcanap7 </TD>
</TR>

<TR>
<TD>dmdcan , divdiv1 , divdiv2 , recdiv2</TD>
<TD>~ dmdcanap , ~ divdivap1 , ~ divdivap2 , ~ recdivap2 </TD>
</TR>

<TR>
<TD>ddcan , divadddiv , divsubdiv</TD>
<TD>~ ddcanap , ~ divadddivap , ~ divsubdivap </TD>
</TR>

<TR>
<TD>ddcan , divadddiv , divsubdiv</TD>
<TD>~ ddcanap , ~ divadddivap , ~ divsubdivap </TD>
</TR>

<TR>
<TD>conjmul , rereccl, redivcl</TD>
<TD>~ conjmulap , ~ rerecclap , ~ redivclap </TD>
</TR>

<TR>
<TD>div2neg , divneg2</TD>
<TD>~ div2negap , ~ divneg2ap </TD>
</TR>

<TR>
<TD>recclzi , recne0zi , recidzi</TD>
<TD>~ recclapzi , ~ recap0apzi , ~ recidapzi </TD>
</TR>

<TR>
<TD>reccli , recidi , recreci</TD>
<TD>~ recclapi , ~ recidapi , ~ recrecapi </TD>
</TR>

<TR>
<TD>dividi , div0i</TD>
<TD>~ dividapi , ~ div0api </TD>
</TR>

<TR>
<TD>divclzi , divcan1zi , divcan2zi</TD>
<TD>~ divclapzi , ~ divcanap1zi , ~ divcanap2zi </TD>
</TR>

<TR>
<TD>divreczi , divcan3zi , divcan4zi</TD>
<TD>~ divrecapzi , ~ divcanap3zi , ~ divcanap4zi </TD>
</TR>

<TR>
<TD>rec11i , rec11ii</TD>
<TD>~ rec11api , ~ rec11apii </TD>
</TR>

<TR>
<TD>divcli , divcan2i , divcan1i , divreci ,
divcan3i , divcan4i </TD>
<TD>~ divclapi , ~ divcanap2i , ~ divcanap1i , ~ divrecapi ,
~ divcanap3i , ~ divcanap4i </TD>
</TR>

<TR>
<TD>div0i</TD>
<TD>~ divap0i </TD>
</TR>

<TR>
<TD>divasszi , divmulzi , divdirzi , divdiv23zi</TD>
<TD>~ divassapzi , ~ divmulapzi , ~ divdirapzi , ~ divdiv23apzi </TD>
</TR>

<TR>
<TD>divmuli , divdiv32i</TD>
<TD>~ divmulapi , ~ divdiv32api </TD>
</TR>

<TR>
<TD>divassi , divdiri , div23i , div11i </TD>
<TD>~ divassapi , ~ divdirapi , ~ div23api , ~ div11api </TD>
</TR>

<TR>
<TD>divmuldivi, divmul13i, divadddivi, divdivdivi</TD>
<TD>~ divmuldivapi , ~ divmul13api , ~ divadddivapi , ~ divdivdivapi </TD>
</TR>

<TR>
<TD>rerecclzi , rereccli , redivclzi , redivcli</TD>
<TD>~ rerecclapzi , ~ rerecclapi , ~ redivclapzi , ~ redivclapi </TD>
</TR>

<TR>
<TD>reccld , rec0d , recidd , recid2d , recrecd ,
dividd , div0d</TD>
<TD>~ recclapd , ~ recap0d , ~ recidapd , ~ recidap2d , ~ recrecapd ,
~ dividapd , ~ div0apd </TD>
</TR>

<TR>
<TD>divcld , divcan1d , divcan2d , divrecd , divrec2d ,
divcan3d , divcan4d</TD>
<TD>~ divclapd , ~ divcanap1d , ~ divcanap2d , ~ divrecapd , ~ divrecap2d ,
~ divcanap3d , ~ divcanap4d </TD>
</TR>

<TR>
<TD>diveq0d , diveq1d , diveq1ad , diveq0ad , divne1d , div0bd , divnegd ,
divneg2d , div2negd</TD>
<TD>~ diveqap0d , ~ diveqap1d , ~ diveqap1ad , ~ diveqap0ad , ~ divap1d ,
~ divap0bd , ~ divnegapd , ~ divneg2apd , ~ div2negapd </TD>
</TR>

<TR>
<TD>divne0d , recdivd , recdiv2d , divcan6d , ddcand , rec11d</TD>
<TD>~ divap0d , ~ recdivapd , ~ recdivap2d , ~ divcanap6d , ~ ddcanapd ,
~ rec11apd </TD>
</TR>

<TR>
<TD>divmuld , div32d , div13d , divdiv32d , divcan5d , divcan5rd ,
divcan7d , dmdcand , dmdcan2d , divdiv1d , divdiv2d</TD>
<TD>~ divmulapd , ~ div32apd , ~ div13apd , ~ divdiv32apd , ~ divcanap5d ,
~ divcanap5rd , ~ divcanap7d , ~ dmdcanapd , ~ dmdcanap2d , ~ divdivap1d ,
~ divdivap2d </TD>
</TR>

<TR>
<TD>divmul2d, divmul3d, divassd, div12d, div23d,
divdird, divsubdird, div11d</TD>
<TD>~ divmulap2d , ~ divmulap3d , ~ divassapd , ~ div12apd , ~ div23apd ,
~ divdirapd , ~ divsubdirapd , ~ div11apd </TD>
</TR>

<TR>
  <TD>divmuldivd</TD>
  <TD>~ divmuldivapd</TD>
</TR>

<TR>
<TD>rereccld , redivcld</TD>
<TD>~ rerecclapd , ~ redivclapd </TD>
</TR>

<TR>
<TD>mvllmuld</TD>
<TD>~ mvllmulapd</TD>
</TR>

<TR>
<TD>elimgt0 , elimge0</TD>
<TD><I>none</I></TD>
<TD>Even in set.mm, the weak deduction theorem is discouraged in
favor of theorems in deduction form.</TD>
</TR>

<TR>
<TD>mulge0b , mulsuble0b</TD>
<TD><I>none</I></TD>
<TD>Presumably unprovable for reasons analogous to mul0or.</TD>
</TR>

<TR>
  <TD>mulle0b</TD>
  <TD>~ mulle0r</TD>
  <TD>The converse of mulle0r is presumably unprovable for reasons
  analogous to mul0or.</TD>
</TR>

<TR>
<TD>ledivp1i , ltdivp1i</TD>
<TD><I>none</I></TD>
<TD>Presumably could be proved, but unused in set.mm.</TD>
</TR>

<TR>
  <TD>fimaxre</TD>
  <TD>~ fimaxre2</TD>
  <TD>When applied to a pair this could show which of two unequal
  real numbers is larger, so perhaps not provable for that reason.
  (see ~ fin0 for inhabited versus nonempty).
  </TD>
</TR>

<TR>
  <TD>fimaxre3</TD>
  <TD><I>none</I></TD>
  <TD>The set.mm proof relies on abrexfi .</TD>
</TR>

<TR>
  <TD>fiminre</TD>
  <TD><I>none</I></TD>
  <TD>See fimaxre</TD>
</TR>

<TR>
  <TD>sup2 , sup3 , sup3ii</TD>
  <TD><I>none</I></TD>
  <TD>We won't be able to have the least upper bound property for all
  nonempty bounded sets. In cases where we can show that the supremum
  exists, we might be able to prove slightly different ways of stating
  there is a supremum.</TD>
</TR>

<TR>
  <TD>infm3</TD>
  <TD><I>none</I></TD>
  <TD>See sup3</TD>
</TR>

<TR>
  <TD>suprcl , suprcld , suprclii</TD>
  <TD>~ supclti</TD>
</TR>

<TR>
  <TD>suprub , suprubd , suprubii</TD>
  <TD>~ suprubex</TD>
</TR>

<TR>
  <TD>suprlub , suprlubii</TD>
  <TD>~ suprlubex</TD>
</TR>

<TR>
  <TD>suprnub , suprnubii</TD>
  <TD>~ suprnubex</TD>
</TR>

<TR>
  <TD>suprleub , suprleubii</TD>
  <TD>~ suprleubex</TD>
</TR>

<TR>
  <TD>supaddc , supadd</TD>
  <TD><I>none</I></TD>
  <TD>Presumably provable with suitable conditions for the existence
  of the supremums</TD>
</TR>

<TR>
  <TD>supmul1 , supmul</TD>
  <TD><I>none</I></TD>
  <TD>Presumably provable with suitable conditions for the existence
  of the supremums</TD>
</TR>

<TR>
  <TD>riotaneg</TD>
  <TD><I>none</I></TD>
  <TD>The theorem is unused in set.mm and the set.mm proof
  relies on reuxfrd</TD>
</TR>

<TR>
  <TD>infrecl</TD>
  <TD>~ infclti</TD>
</TR>

<TR>
  <TD>infrenegsup</TD>
  <TD>~ infrenegsupex</TD>
</TR>

<TR>
  <TD>infregelb</TD>
  <TD><I>none yet</I></TD>
  <TD>Presumably could be handled in a way analogous to ~ suprleubex</TD>
</TR>

<TR>
  <TD>infrelb</TD>
  <TD><I>none yet</I></TD>
  <TD>Presumably could be handled in a way analogous to ~ suprubex</TD>
</TR>

<TR>
  <TD>supfirege</TD>
  <TD>~ suprubex</TD>
  <TD>The question here is whether results like ~ maxle1 can be generalized
  (presumably by induction) from pairs to finite sets.</TD>
</TR>

<TR>
<TD>crne0</TD>
<TD>~ crap0 </TD>
</TR>

<TR>
<TD>ofsubeq0 , ofnegsub , ofsubge0</TD>
<TD><I>none</I></TD>
<TD>Depend on ofval and/or offn .</TD>
</TR>

<TR>
<TD>df-nn</TD>
<TD>~ dfnn2 </TD>
</TR>

<TR>
<TD>dfnn3</TD>
<TD>~ dfnn2 </TD>
<TD>Presumably could be proved, as it is a slight variation of dfnn2</TD>
</TR>

<TR>
<TD>avgle</TD>
<TD>~ qavgle</TD>
</TR>

<TR>
<TD>nnunb</TD>
<TD><I>none</I></TD>
<TD>Presumably provable from ~ arch but unused in set.mm.</TD>
</TR>

<TR>
<TD>frnnn0supp , frnnn0fsupp</TD>
<TD>~ nn0supp </TD>
<TD>iset.mm does not yet have either the notation, or in some
cases the theorems, related to the support of a function or
a fintely supported function.</TD>
</TR>

<TR>
<TD>suprzcl</TD>
<TD>~ suprzclex</TD>
</TR>

<TR>
<TD>zriotaneg</TD>
<TD><I>none</I></TD>
<TD>Lightly used in set.mm</TD>
</TR>

<TR>
<TD>suprfinzcl</TD>
<TD><I>none</I></TD>
</TR>

<TR>
<TD>decex</TD>
<TD>~ deccl </TD>
</TR>

<TR>
  <TD>halfthird</TD>
  <TD><I>none</I></TD>
  <TD>Presumably will be easy to intuitionize</TD>
</TR>

<TR>
  <TD>5recm6rec</TD>
  <TD><I>none</I></TD>
  <TD>Presumably will be easy to intuitionize</TD>
</TR>

<TR>
<TD>uzwo , uzwo2 , nnwo , nnwof , nnwos</TD>
<TD><I>none</I></TD>
<TD>Presumably would imply excluded middle, unless there is something
which makes this different from ~ nnregexmid .</TD>
</TR>

<TR>
<TD>negn0</TD>
<TD>~ negm </TD>
</TR>

<TR>
<TD>uzinfi, nninf, nn0inf</TD>
<TD><I>none</I></TD>
<TD>Presumably provable</TD>
</TR>

<TR>
  <TD>infssuzle</TD>
  <TD>~ infssuzledc</TD>
</TR>

<TR>
  <TD>infssuzcl</TD>
  <TD>~ infssuzcldc</TD>
</TR>

<TR>
<TD>supminf</TD>
<TD>~ supminfex</TD>
</TR>

<TR>
  <TD>zsupss , suprzcl2</TD>
  <TD>~ zsupcl , ~ suprzclex</TD>
</TR>

<TR>
<TD>suprzub</TD>
<TD><I>none</I></TD>
<TD>Presumably could prove something like this with different conditions
for the existence of the supremum (see ~ infssuzledc for something along
these lines).</TD>
</TR>

<TR>
<TD>uzsupss</TD>
<TD>~ zsupcl</TD>
</TR>

<TR>
  <TD>uzwo3 , zmin</TD>
  <TD><I>none</I></TD>
  <TD>Proved in terms of supremum theorems and presumably not possible
  without excluded middle.</TD>
</TR>

<TR>
  <TD>zbtwnre</TD>
  <TD><I>none</I></TD>
  <TD>Proved in terms of supremum theorems and presumably not possible
  without excluded middle.</TD>
</TR>

<TR>
  <TD>rebtwnz</TD>
  <TD>~ qbtwnz</TD>
</TR>

<TR>
<TD>rpneg</TD>
<TD>~ rpnegap </TD>
</TR>

<TR>
<TD>xrlttri , xrlttri2</TD>
<TD><I>none</I></TD>
<TD>A generalization of real trichotomy.</TD>
</TR>

<TR>
<TD>xrleloe , xrleltne , dfle2</TD>
<TD><I>none</I></TD>
<TD>Consequences of real trichotomy.</TD>
</TR>

<TR>
<TD>xrltlen</TD>
<TD><I>none</I></TD>
<TD>We presumably could prove an analogue to ~ ltleap but we have not
yet defined apartness for extended reals (` # ` is for complex
numbers).</TD>
</TR>

<TR>
<TD>dflt2</TD>
<TD><I>none</I></TD>
</TR>

<TR>
<TD>xrletri</TD>
<TD><I>none</I></TD>
</TR>

<TR>
<TD>xrmax1 , xrmax2 , xrmin1 , xrmin2 , xrmaxeq , xrmineq ,
xrmaxlt , xrltmin , xrmaxle , xrlemin ,
max0sub , ifle</TD>
<TD><I>none</I></TD>
</TR>

<TR>
  <TD>max1</TD>
  <TD>~ maxle1</TD>
</TR>

<TR>
  <TD>max2</TD>
  <TD>~ maxle2</TD>
</TR>

<TR>
  <TD>2resupmax</TD>
  <TD><I>none</I></TD>
  <TD>Proved from real trichotomy.
  We express maximum in iset.mm using ` sup ( { A , B } , RR , < ) `
  rather than ` if ( A <_ B , B , A ) ` . The former has the
  expected maximum properties such as ~ maxcl , ~ maxle1 , ~ maxle2 ,
  ~ maxleast , and ~ maxleb .</TD>
</TR>

<TR>
  <TD>min1</TD>
  <TD>~ min1inf</TD>
</TR>

<TR>
  <TD>min2</TD>
  <TD>~ min2inf</TD>
</TR>

<TR>
  <TD>maxle</TD>
  <TD>~ maxleastb</TD>
</TR>

<TR>
  <TD>lemin</TD>
  <TD>~ lemininf</TD>
</TR>

<TR>
  <TD>maxlt</TD>
  <TD>~ maxltsup</TD>
</TR>

<TR>
  <TD>ltmin</TD>
  <TD>~ ltmininf</TD>
</TR>

<TR>
<TD>qsqueeze</TD>
<TD><I>none yet</I></TD>
<TD>Presumably provable from ~ qbtwnre and ~ squeeze0 , but unused
in set.mm.</TD>
</TR>

<TR>
<TD>qextltlem , qextlt , qextle</TD>
<TD><I>none</I></TD>
<TD>The set.mm proof is not intuitionistic.</TD>
</TR>

<TR>
<TD>xralrple , alrple</TD>
<TD><I>none yet</I></TD>
<TD>Now that we have ~ qbtwnxr , it looks like the set.mm proof would work
with minor changes.</TD>
</TR>

<TR>
<TD>xnegex</TD>
<TD>~ xnegcl </TD>
</TR>

<TR>
<TD>xaddval , xaddf , xmulval , xaddpnf1 , xaddpnf2 , xaddmnf1 ,
xaddmnf2 , pnfaddmnf , mnfaddpnf , rexadd , rexsub , xaddnemnf ,
xaddnepnf , xnegid , xaddcl , xaddcom , xaddid1 , xaddid2 ,
xnegdi , xaddass , xaddass2 , xpncan , xnpcan , xleadd1a ,
xleadd2a , xleadd1 , xltadd1 , xltadd2 , xaddge0 , xle2add ,
xlt2add , xsubge0 , xposdif , xlesubadd , xmullem , xmullem2 ,
xmulcom , xmul01 , xmul02 , xmulneg1 , xmulneg2 , rexmul ,
xmulf , xmulcl , xmulpnf1 , xmulpnf2 , xmulmnf1 , xmulmnf2 ,
xmulpnf1n , xmulid1 , xmulid2 , xmulm1 , xmulasslem2 , xmulgt0 ,
xmulge0 , xmulasslem , xmulasslem3 , xmulass , xlemul1a ,
xlemul2a , xlemul1 , xlemul2 , xltmul1 , xltmul2 , xadddilem ,
xadddi , xadddir , xadddi2 , xadddi2r , x2times , xaddcld ,
xmulcld , xadd4d</TD>
<TD><I>none</I></TD>
<TD>There appears to be no fundamental obstacle to proving these,
because disjunctions can arise from ~ elxr rather than excluded
middle. However, ` -e ` , ` +e ` , and ` *e ` are lightly used in
set.mm, and the set.mm proofs would require significant changes.</TD>
</TR>

<TR>
<TD>ixxub , ixxlb</TD>
<TD><I>none</I></TD>
</TR>

<TR>
<TD>iccen</TD>
<TD><I>none</I></TD>
</TR>

<TR>
<TD>supicc , supiccub , supicclub , supicclub2</TD>
<TD><I>none</I></TD>
</TR>

<TR>
<TD>ixxun , ixxin</TD>
<TD><I>none</I></TD>
</TR>

<TR>
<TD>ioon0</TD>
<TD>~ ioom</TD>
<TD>Non-empty is changed to inhabited</TD>
</TR>

<TR>
<TD>iooid</TD>
<TD>~ iooidg </TD>
</TR>

<TR>
<TD>ndmioo</TD>
<TD><I>none</I></TD>
<TD>See discussion at ndmov but set.mm uses excluded middle,
both in proving this and in using it.</TD>
</TR>

<TR>
<TD>lbioo , ubioo</TD>
<TD>~ lbioog , ~ ubioog </TD>
</TR>

<TR>
<TD>iooin</TD>
<TD><I>none</I></TD>
</TR>

<TR>
<TD>icc0</TD>
<TD>~ icc0r </TD>
</TR>

<TR>
<TD>ioorebas</TD>
<TD>~ ioorebasg </TD>
</TR>

<TR>
<TD>ge0xaddcl , ge0xmulcl</TD>
<TD><I>none</I></TD>
<TD>Rely on xaddcl and xmulcl ; see discussion in this list
for those theorems.</TD>
</TR>

<TR>
<TD>icoun , snunioo , snunico , snunioc , prunioo</TD>
<TD><I>none</I></TD>
</TR>

<TR>
<TD>ioojoin</TD>
<TD><I>none</I></TD>
</TR>

<TR>
<TD>difreicc</TD>
<TD><I>none</I></TD>
</TR>

<TR>
<TD>iccsplit</TD>
<TD><I>none</I></TD>
<TD>This depends, apparently in an essential way, on real number
trichotomy.</TD>
</TR>

<TR>
<TD>xov1plusxeqvd</TD>
<TD><I>none</I></TD>
<TD>This presumably could be proved if not equal is changed
to apart, but is lightly used in set.mm.</TD>
</TR>

<TR>
<TD>fzn0</TD>
<TD>~ fzm </TD>
</TR>

<TR>
<TD>fz0</TD>
<TD><I>none</I></TD>
<TD>Although it would be possible to prove a version of this
with the additional conditions that ` M e. _V ` and ` N e. _V ` ,
the theorem is lightly used in set.mm.</TD>
</TR>

<TR>
<TD>fzon0</TD>
<TD>~ fzom </TD>
</TR>

<TR>
<TD>fzo0n0</TD>
<TD>~ fzo0m </TD>
</TR>

<TR>
<TD>ssfzoulel</TD>
<TD><I>none</I></TD>
<TD>Presumably could be proven, but the set.mm proof is not
intuitionistic and it is lightly used in set.mm.</TD>
</TR>

<TR>
<TD>fzonfzoufzol</TD>
<TD><I>none</I></TD>
<TD>Presumably could be proven, but the set.mm proof is not
intuitionistic and it is lightly used in set.mm.</TD>
</TR>

<TR>
<TD>elfznelfzo , elfznelfzob , injresinjlem , injresinj</TD>
<TD><I>none</I></TD>
<TD>Some or all of this presumably could be proven, but the set.mm
proof is not intuitionistic and it is lightly used in set.mm.</TD>
</TR>

<TR>
  <TD>flcl , reflcl , flcld</TD>
  <TD>~ flqcl , ~ flqcld</TD>
</TR>

<TR>
  <TD>fllelt</TD>
  <TD>~ flqlelt</TD>
</TR>

<TR>
  <TD>flle</TD>
  <TD>~ flqle</TD>
</TR>

<TR>
  <TD>flltp1 , fllep1</TD>
  <TD>~ flqltp1</TD>
</TR>

<TR>
  <TD>fraclt1 , fracle1</TD>
  <TD>~ qfraclt1</TD>
</TR>

<TR>
  <TD>fracge0</TD>
  <TD>~ qfracge0</TD>
</TR>

<TR>
  <TD>flge</TD>
  <TD>~ flqge</TD>
</TR>

<TR>
  <TD>fllt</TD>
  <TD>~ flqlt</TD>
</TR>

<TR>
  <TD>flflp1</TD>
  <TD><I>none</I></TD>
  <TD>The set.mm proof relies on case elimination.</TD>
</TR>

<TR>
  <TD>flidm</TD>
  <TD>~ flqidm</TD>
</TR>

<TR>
  <TD>flidz</TD>
  <TD>~ flqidz</TD>
</TR>

<TR>
  <TD>flltnz</TD>
  <TD>~ flqltnz</TD>
</TR>

<TR>
  <TD>flwordi</TD>
  <TD>~ flqwordi</TD>
</TR>

<TR>
  <TD>flword2</TD>
  <TD>~ flqword2</TD>
</TR>

<TR>
  <TD>flval2 , flval3</TD>
  <TD><I>none</I></TD>
  <TD>Unused in set.mm</TD>
</TR>

<TR>
  <TD>flbi</TD>
  <TD>~ flqbi</TD>
</TR>

<TR>
  <TD>flbi2</TD>
  <TD>~ flqbi2</TD>
</TR>

<TR>
  <TD>ico01fl0</TD>
  <TD><I>none</I></TD>
  <TD>Presumably could be proved for rationals, but lightly used in
  set.mm.</TD>
</TR>

<TR>
  <TD>flge0nn0</TD>
  <TD>~ flqge0nn0</TD>
</TR>

<TR>
  <TD>flge1nn</TD>
  <TD>~ flqge1nn</TD>
</TR>

<TR>
  <TD>refldivcl</TD>
  <TD>~ flqcl</TD>
</TR>

<TR>
  <TD>fladdz</TD>
  <TD>~ flqaddz</TD>
</TR>

<TR>
  <TD>flzadd</TD>
  <TD>~ flqzadd</TD>
</TR>

<TR>
  <TD>flmulnn0</TD>
  <TD>~ flqmulnn0</TD>
</TR>

<TR>
  <TD>fldivle</TD>
  <TD>~ flqle</TD>
</TR>

<TR>
  <TD>ltdifltdiv</TD>
  <TD><I>none</I></TD>
  <TD>Unused in set.mm.</TD>
</TR>

<TR>
  <TD>fldiv4lem1div2uz2 , fldiv4lem1div2</TD>
  <TD><I>none</I></TD>
  <TD>Presumably provable, but lightly used in set.mm.</TD>
</TR>

<TR>
  <TD>ceilval</TD>
  <TD>~ ceilqval</TD>
  <TD>The set.mm ceilval, with a real argument and no additional
  conditions, is probably provable if there is a need.</TD>
</TR>

<TR>
  <TD>dfceil2 , ceilval2</TD>
  <TD><I>none</I></TD>
  <TD>Unused in set.mm.</TD>
</TR>

<TR>
  <TD>ceicl</TD>
  <TD>~ ceiqcl</TD>
</TR>

<TR>
  <TD>ceilcl</TD>
  <TD>~ ceilqcl</TD>
</TR>

<TR>
  <TD>ceilge</TD>
  <TD>~ ceilqge</TD>
</TR>

<TR>
  <TD>ceige</TD>
  <TD>~ ceiqge</TD>
</TR>

<TR>
  <TD>ceim1l</TD>
  <TD>~ ceiqm1l</TD>
</TR>

<TR>
  <TD>ceilm1lt</TD>
  <TD>~ ceilqm1lt</TD>
</TR>

<TR>
  <TD>ceile</TD>
  <TD>~ ceiqle</TD>
</TR>

<TR>
  <TD>ceille</TD>
  <TD>~ ceilqle</TD>
</TR>

<TR>
  <TD>ceilidz</TD>
  <TD>~ ceilqidz</TD>
</TR>

<TR>
  <TD>flleceil</TD>
  <TD>~ flqleceil</TD>
</TR>

<TR>
  <TD>fleqceilz</TD>
  <TD>~ flqeqceilz</TD>
</TR>

<TR>
  <TD>quoremz , quoremnn0 , quoremnn0ALT</TD>
  <TD><I>none</I></TD>
  <TD>Unused in set.mm.</TD>
</TR>

<TR>
  <TD>intfrac2</TD>
  <TD>~ intqfrac2</TD>
</TR>

<TR>
  <TD>fldiv</TD>
  <TD>~ flqdiv</TD>
</TR>

<TR>
  <TD>fldiv2</TD>
  <TD><I>none</I></TD>
  <TD>Presumably would be provable if real is changed to rational.</TD>
</TR>

<TR>
  <TD>fznnfl</TD>
  <TD><I>none</I></TD>
  <TD>Presumably would be provable if real is changed to rational.</TD>
</TR>

<TR>
  <TD>uzsup , ioopnfsup , icopnfsup , rpsup , resup , xrsup</TD>
  <TD><I>none</I></TD>
  <TD>As with most theorems involving supremums, these would
  likely need significant changes</TD>
</TR>

<TR>
<TD>modval</TD>
<TD>~ modqval</TD>
<TD>As with theorems such as ~ flqcl , we prove most of the modulo related
theorems for rationals, although other conditions on real arguments other
than whether they are rational would be possible in the future.</TD>
</TR>

<TR>
  <TD>modvalr</TD>
  <TD>~ modqvalr</TD>
</TR>

<TR>
  <TD>modcl , modcld</TD>
  <TD>~ modqcl , ~ modqcld</TD>
</TR>

<TR>
  <TD>flpmodeq</TD>
  <TD>~ flqpmodeq</TD>
</TR>

<TR>
  <TD>mod0</TD>
  <TD>~ modq0</TD>
</TR>

<TR>
  <TD>mulmod0</TD>
  <TD>~ mulqmod0</TD>
</TR>

<TR>
  <TD>negmod0</TD>
  <TD>~ negqmod0</TD>
</TR>

<TR>
  <TD>modge0</TD>
  <TD>~ modqge0</TD>
</TR>

<TR>
  <TD>modlt</TD>
  <TD>~ modqlt</TD>
</TR>

<TR>
  <TD>modelico</TD>
  <TD>~ modqelico</TD>
</TR>

<TR>
  <TD>moddiffl</TD>
  <TD>~ modqdiffl</TD>
</TR>

<TR>
  <TD>moddifz</TD>
  <TD>~ modqdifz</TD>
</TR>

<TR>
  <TD>modfrac</TD>
  <TD>~ modqfrac</TD>
</TR>

<TR>
  <TD>flmod</TD>
  <TD>~ flqmod</TD>
</TR>

<TR>
  <TD>intfrac</TD>
  <TD>~ intqfrac</TD>
</TR>

<TR>
  <TD>modmulnn</TD>
  <TD>~ modqmulnn</TD>
</TR>

<TR>
  <TD>modvalp1</TD>
  <TD>~ modqvalp1</TD>
</TR>

<TR>
  <TD>modid</TD>
  <TD>~ modqid</TD>
</TR>

<TR>
  <TD>modid0</TD>
  <TD>~ modqid0</TD>
</TR>

<TR>
  <TD>modid2</TD>
  <TD>~ modqid2</TD>
</TR>

<TR>
  <TD>0mod</TD>
  <TD>~ q0mod</TD>
</TR>

<TR>
  <TD>1mod</TD>
  <TD>~ q1mod</TD>
</TR>

<TR>
  <TD>modabs</TD>
  <TD>~ modqabs</TD>
</TR>

<TR>
  <TD>modabs2</TD>
  <TD>~ modqabs2</TD>
</TR>

<TR>
  <TD>modcyc</TD>
  <TD>~ modqcyc</TD>
</TR>

<TR>
  <TD>modcyc2</TD>
  <TD>~ modqcyc2</TD>
</TR>

<TR>
  <TD>modadd1</TD>
  <TD>~ modqadd1</TD>
</TR>

<TR>
  <TD>modaddabs</TD>
  <TD>~ modqaddabs</TD>
</TR>

<TR>
  <TD>modaddmod</TD>
  <TD>~ modqaddmod</TD>
</TR>

<TR>
  <TD>muladdmodid</TD>
  <TD>~ mulqaddmodid</TD>
</TR>

<TR>
  <TD>modmuladd</TD>
  <TD>~ modqmuladd</TD>
</TR>

<TR>
  <TD>modmuladdim</TD>
  <TD>~ modqmuladdim</TD>
</TR>

<TR>
  <TD>modmuladdnn0</TD>
  <TD>~ modqmuladdnn0</TD>
</TR>

<TR>
  <TD>negmod</TD>
  <TD>~ qnegmod</TD>
</TR>

<TR>
  <TD>modadd2mod</TD>
  <TD>~ modqadd2mod</TD>
</TR>

<TR>
  <TD>modm1p1mod0</TD>
  <TD>~ modqm1p1mod0</TD>
</TR>

<TR>
  <TD>modltm1p1mod</TD>
  <TD>~ modqltm1p1mod</TD>
</TR>

<TR>
  <TD>modmul1</TD>
  <TD>~ modqmul1</TD>
</TR>

<TR>
  <TD>modmul12d</TD>
  <TD>~ modqmul12d</TD>
</TR>

<TR>
  <TD>modnegd</TD>
  <TD>~ modqnegd</TD>
</TR>

<TR>
  <TD>modadd12d</TD>
  <TD>~ modqadd12d</TD>
</TR>

<TR>
  <TD>modsub12d</TD>
  <TD>~ modqsub12d</TD>
</TR>

<TR>
  <TD>modsubmod</TD>
  <TD>~ modqsubmod</TD>
</TR>

<TR>
  <TD>modsubmodmod</TD>
  <TD>~ modqsubmodmod</TD>
</TR>

<TR>
  <TD>2txmodxeq0</TD>
  <TD>~ q2txmodxeq0</TD>
</TR>

<TR>
  <TD>2submod</TD>
  <TD>~ q2submod</TD>
</TR>

<TR>
  <TD>modmulmod</TD>
  <TD>~ modqmulmod</TD>
</TR>

<TR>
  <TD>modmulmodr</TD>
  <TD>~ modqmulmodr</TD>
</TR>

<TR>
  <TD>modaddmulmod</TD>
  <TD>~ modqaddmulmod</TD>
</TR>

<TR>
  <TD>moddi</TD>
  <TD>~ modqdi</TD>
</TR>

<TR>
  <TD>modsubdir</TD>
  <TD>~ modqsubdir</TD>
</TR>

<TR>
  <TD>modeqmodmin</TD>
  <TD>~ modqeqmodmin</TD>
</TR>

<TR>
  <TD>modirr</TD>
  <TD><I>none</I></TD>
  <TD>A version of this (presumably modified) may be possible,
  but it is unused in set.mm</TD>
</TR>

<TR>
<TD>om2uz0i</TD>
<TD>~ frec2uz0d</TD>
</TR>

<TR>
<TD>om2uzsuci</TD>
<TD>~ frec2uzsucd</TD>
</TR>

<TR>
<TD>om2uzuzi</TD>
<TD>~ frec2uzuzd</TD>
</TR>

<TR>
<TD>om2uzlti</TD>
<TD>~ frec2uzltd</TD>
</TR>

<TR>
<TD>om2uzlt2i</TD>
<TD>~ frec2uzlt2d</TD>
</TR>

<TR>
<TD>om2uzrani</TD>
<TD>~ frec2uzrand</TD>
</TR>

<TR>
<TD>om2uzf1oi</TD>
<TD>~ frec2uzf1od</TD>
</TR>

<TR>
<TD>om2uzisoi</TD>
<TD>~ frec2uzisod</TD>
</TR>

<TR>
<TD>om2uzoi , ltweuz , ltwenn , ltwefz</TD>
<TD><I>none</I></TD>
<TD>Based on theorems like ~ nnregexmid it is not clear what,
if anything, along these lines is possible.</TD>
</TR>

<TR>
<TD>om2uzrdg</TD>
<TD>~ frec2uzrdg</TD>
</TR>

<TR>
<TD>uzrdglem</TD>
<TD>~ frecuzrdglem</TD>
</TR>

<TR>
<TD>uzrdgfni</TD>
<TD>~ frecuzrdgfn</TD>
</TR>

<TR>
<TD>uzrdg0i</TD>
<TD>~ frecuzrdg0</TD>
</TR>

<TR>
<TD>uzrdgsuci</TD>
<TD>~ frecuzrdgsuc</TD>
</TR>

<TR>
<TD>uzinf</TD>
<TD><I>none</I></TD>
<TD>See ominf</TD>
</TR>

<TR>
<TD>uzrdgxfr</TD>
<TD><I>none</I></TD>
<TD>Presumably could be proved if restated in terms of ` frec `
(a la ~ frec2uz0d ). However, it is lightly used in set.mm.</TD>
</TR>

<TR>
<TD>fzennn</TD>
<TD>~ frecfzennn</TD>
</TR>

<TR>
<TD>fzen2</TD>
<TD>~ frecfzen2</TD>
</TR>

<TR>
<TD>cardfz</TD>
<TD><I>none</I></TD>
<TD>Cardinality does not work the same way without excluded
middle and iset.mm has few cardinality related theorems.</TD>
</TR>

<TR>
<TD>hashgf1o</TD>
<TD>~ frechashgf1o</TD>
</TR>

<TR>
<TD>fzfi</TD>
<TD>~ fzfig</TD>
</TR>

<TR>
<TD>fzfid</TD>
<TD>~ fzfigd</TD>
</TR>

<TR>
<TD>fzofi</TD>
<TD>~ fzofig</TD>
</TR>

<TR>
<TD>fsequb</TD>
<TD><I>none</I></TD>
<TD>Seems like it might be provable, but unused in set.mm</TD>
</TR>

<TR>
<TD>fsequb2</TD>
<TD><I>none</I></TD>
<TD>The set.mm proof does not work as-is</TD>
</TR>

<TR>
  <TD>fseqsupcl</TD>
  <TD><I>none</I></TD>
  <TD>The set.mm proof relies on fisupcl and it is not clear whether this
  supremum theorem or anything similar can be proved.</TD>
</TR>

<TR>
  <TD>fseqsupubi</TD>
  <TD><I>none</I></TD>
  <TD>The set.mm proof relies on fsequb2 and suprub and it is not clear
  whether this supremum theorem or anything similar can be proved.</TD>
</TR>

<TR>
<TD>uzindi</TD>
<TD><I>none</I></TD>
<TD>This could presumably be proved, perhaps from ~ uzsinds ,
but is lightly used in set.mm</TD>
</TR>

<TR>
<TD>axdc4uz</TD>
<TD><I>none</I></TD>
<TD>Although some versions of constructive mathematics accept dependent
choice, we have not yet developed it in iset.mm</TD>
</TR>

<TR>
<TD>ssnn0fi , rabssnn0fi</TD>
<TD><I>none</I></TD>
<TD>Conjectured to imply excluded middle along the lines of ~ nnregexmid
or ~ ssfiexmid </TD>
</TR>

<TR>
<TD>df-seq</TD>
<TD>~ df-iseq</TD>
</TR>

<TR>
  <TD>seqex</TD>
  <TD>~ iseqex</TD>
  <TD>The only difference is the differing syntax of ` seq ` .</TD>
</TR>

<TR>
<TD>seqeq1 , seqeq2 , seqeq3 , seqeq1d , seqeq2d , seqeq3d , seqeq123d</TD>
<TD>~ iseqeq1 , ~ iseqeq2 , ~ iseqeq3</TD>
</TR>

<TR>
<TD>nfseq</TD>
<TD>~ nfiseq</TD>
</TR>

<TR>
<TD>seqval</TD>
<TD>~ iseqval</TD>
</TR>

<TR>
<TD>seqfn</TD>
<TD>~ iseqfn</TD>
</TR>

<TR>
<TD>seq1 , seq1i</TD>
<TD>~ iseq1</TD>
</TR>

<TR>
<TD>seqp1 , seqp1i</TD>
<TD>~ iseqp1</TD>
</TR>

<TR>
  <TD>seqm1</TD>
  <TD>~ iseqm1</TD>
</TR>

<TR>
  <TD>seqcl2</TD>
  <TD><I>none yet</I></TD>
  <TD>Presumably could prove this (with adjustments analogous
  to ~ iseqp1 ). The third argument to ` seq ` in iset.mm would
  correspond to ` C ` rather than ` D ` (some of the other ` seq `
  related theorems do not allow ` C ` and ` D ` to be different,
  but seqcl2 does).</TD>
</TR>

<TR>
  <TD>seqf2</TD>
  <TD><I>none yet</I></TD>
  <TD>Presumably could prove this, analogously to seqcl2.</TD>
</TR>

<TR>
  <TD>seqcl</TD>
  <TD>~ iseqcl</TD>
  <TD>iseqcl requires that ` F ` be defined on ` ( ZZ>= `` M ) `
  not merely ` ( M ... N ) ` as in seqcl . This is not a problem
  when used on infinite sequences, but perhaps this requirement
  could be relaxed if there is a need.</TD>
</TR>

<TR>
<TD>seqf</TD>
<TD>~ iseqf</TD>
</TR>

<TR>
<TD>seqfveq2</TD>
<TD>~ iseqfveq2</TD>
</TR>

<TR>
<TD>seqfeq2</TD>
<TD>~ iseqfeq2</TD>
</TR>

<TR>
<TD>seqfveq</TD>
<TD>~ iseqfveq</TD>
</TR>

<TR>
<TD>seqfeq</TD>
<TD>~ iseqfeq</TD>
</TR>

<TR>
<TD>seqshft2</TD>
<TD>~ iseqshft2</TD>
</TR>

<TR>
  <TD>seqres</TD>
  <TD><I>none</I></TD>
  <TD>Should be intuitionizable as with the other ` seq ` theorems,
  but unused in set.mm</TD>
</TR>

<TR>
  <TD>serf</TD>
  <TD>~ iserf</TD>
</TR>

<TR>
  <TD>serfre</TD>
  <TD>~ iserfre</TD>
</TR>

<TR>
  <TD>sermono</TD>
  <TD>~ isermono</TD>
  <TD>isermono requires that ` F ` be defined on ` ( ZZ>= `` M ) `
  not merely ` ( M ... N ) ` as in sermono . Given that the intention is to
  use this for infinite series, there may be no need to look
  into whether this requirement can be relaxed.</TD>
</TR>

<TR>
  <TD>seqsplit</TD>
  <TD>~ iseqsplit</TD>
  <TD>iseqsplit requires that ` F ` be defined on ` ( ZZ>= `` K ) `
  not merely ` ( K ... N ) ` as in seqsplit . This is not a problem
  when used on infinite sequences, but perhaps this requirement
  could be relaxed if there is a need.</TD>
</TR>

<TR>
  <TD>seq1p</TD>
  <TD>~ iseq1p</TD>
  <TD>iseq1p requires that ` F ` be defined on ` ( ZZ>= `` M ) `
  not merely ` ( M ... N ) ` as in seq1p . This is not a problem
  when used on infinite sequences, but perhaps this requirement
  could be relaxed if there is a need.</TD>
</TR>

<TR>
  <TD>seqcaopr3</TD>
  <TD>~ iseqcaopr3</TD>
  <TD>iseqcaopr3 requires that ` F ` , ` G ` , and ` H ` be defined on
  ` ( ZZ>= `` M ) ` not merely ` ( M ... N ) ` as in seqcaopr3 . This
  is not a problem when used on infinite sequences, but perhaps this
  requirement could be relaxed if there is a need.</TD>
</TR>

<TR>
  <TD>seqcaopr2</TD>
  <TD>~ iseqcaopr2</TD>
  <TD>iseqcaopr2 requires that ` F ` , ` G ` , and ` H ` be defined on
  ` ( ZZ>= `` M ) ` not merely ` ( M ... N ) ` as in seqcaopr2 . This
  is not a problem when used on infinite sequences, but perhaps this
  requirement could be relaxed if there is a need.</TD>
</TR>

<TR>
  <TD>seqcaopr</TD>
  <TD>~ iseqcaopr</TD>
  <TD>iseqcaopr requires that ` F ` , ` G ` , and ` H ` be defined on
  ` ( ZZ>= `` M ) ` not merely ` ( M ... N ) ` as in seqcaopr . This
  is not a problem when used on infinite sequences, but perhaps this
  requirement could be relaxed if there is a need.</TD>
</TR>

<TR>
  <TD>seqf1o</TD>
  <TD><I>none</I></TD>
  <TD>May be adaptable with sufficient attention to issues such as
  whether the operation ` .+ ` is closed with respect to ` C ` as
  well as ` S ` , and perhaps other issues.</TD>
</TR>

<TR>
  <TD>seradd</TD>
  <TD>~ iseradd</TD>
  <TD>iseradd requires that ` F ` , ` G ` , and ` H ` be defined on
  ` ( ZZ>= `` M ) ` not merely ` ( M ... N ) ` as in seradd . This
  is not a problem when used on infinite sequences, but perhaps this
  requirement could be relaxed if there is a need.</TD>
</TR>

<TR>
  <TD>sersub</TD>
  <TD>~ isersub</TD>
  <TD>isersub requires that ` F ` , ` G ` , and ` H ` be defined on
  ` ( ZZ>= `` M ) ` not merely ` ( M ... N ) ` as in sersub . This
  is not a problem when used on infinite sequences, but perhaps this
  requirement could be relaxed if there is a need.</TD>
</TR>

<TR>
  <TD>seqid3</TD>
  <TD>~ iseqid3 , ~ iseqid3s</TD>
  <TD>~ iseqid3 and ~ iseqid3s differ with respect to which
  entries in ` F ` need to be
  zero. Further refinements to the hypotheses including where ` F `
  needs to be defined and the like might be possible (with
  a greater amount of work), but perhaps these are sufficient.</TD>
</TR>

<TR>
  <TD>seqid</TD>
  <TD>~ iseqid</TD>
</TR>

<TR>
  <TD>seqid2</TD>
  <TD><I>none yet</I></TD>
  <TD>It should be possible to come up with a (presumably
  modified) version of this, but we have not done so yet.</TD>
</TR>

<TR>
  <TD>seqhomo</TD>
  <TD>~ iseqhomo</TD>
</TR>

<TR>
  <TD>seqz</TD>
  <TD>~ iseqz</TD>
</TR>

<TR>
  <TD>seqfeq4 , seqfeq3</TD>
  <TD><I>none yet</I></TD>
  <TD>It should be possible to come up with some (presumably
  modified) versions of these, but we have not done so yet.</TD>
</TR>

<TR>
  <TD>seqdistr</TD>
  <TD>~ iseqdistr</TD>
</TR>

<TR>
  <TD>ser0</TD>
  <TD>~ iser0</TD>
  <TD>The only difference is the syntax of ` seq ` .</TD>
</TR>

<TR>
  <TD>ser0f</TD>
  <TD>~ iser0f</TD>
  <TD>The only difference is the syntax of ` seq ` .</TD>
</TR>

<TR>
  <TD>serge0</TD>
  <TD>~ serige0</TD>
  <TD>This theorem uses ` CC ` as the final argument to ` seq `
  which probably will be more convenient even if all the values
  are elements of a subset of ` CC ` .</TD>
</TR>

<TR>
  <TD>serle</TD>
  <TD>~ serile</TD>
  <TD>This theorem uses ` CC ` as the final argument to ` seq `
  which probably will be more convenient even if all the values
  are elements of a subset of ` CC ` .</TD>
</TR>

<TR>
  <TD>ser1const , seqof , seqof2</TD>
  <TD><I>none yet</I></TD>
  <TD>It should be possible to come up with some (presumably
  modified) versions of these, but we have not done so yet.</TD>
</TR>

<TR>
<TD>df-exp</TD>
<TD>~ df-iexp</TD>
<TD>The difference is that ` seq ` in iset.mm takes three arguments compared with two in set.mm.</TD>
</TR>

<TR>
<TD>expval</TD>
<TD>~ expival</TD>
</TR>

<TR>
<TD>expnnval</TD>
<TD>~ expinnval</TD>
</TR>

<TR>
<TD>expneg</TD>
<TD>~ expnegap0</TD>
<TD>The set.mm theorem does not exclude the case of
dividing by zero.</TD>
</TR>

<TR>
<TD>expneg2</TD>
<TD>~ expineg2</TD>
</TR>

<TR>
<TD>expn1</TD>
<TD>~ expn1ap0</TD>
</TR>

<TR>
<TD>expcl2lem</TD>
<TD>~ expcl2lemap</TD>
</TR>

<TR>
<TD>reexpclz</TD>
<TD>~ reexpclzap</TD>
</TR>

<TR>
<TD>expclzlem</TD>
<TD>~ expclzaplem</TD>
</TR>

<TR>
<TD>expclz</TD>
<TD>~ expclzap</TD>
</TR>

<TR>
<TD>expne0</TD>
<TD>~ expap0</TD>
</TR>

<TR>
<TD>expne0i</TD>
<TD>~ expap0i</TD>
</TR>

<TR>
<TD>expnegz</TD>
<TD>~ expnegzap</TD>
</TR>

<TR>
<TD>mulexpz</TD>
<TD>~ mulexpzap</TD>
</TR>

<TR>
<TD>exprec</TD>
<TD>~ exprecap</TD>
</TR>

<TR>
<TD>expaddzlem , expaddz</TD>
<TD>~ expaddzaplem , ~ expaddzap</TD>
</TR>

<TR>
<TD>expmulz</TD>
<TD>~ expmulzap</TD>
</TR>

<TR>
<TD>expsub</TD>
<TD>~ expsubap</TD>
</TR>

<TR>
<TD>expp1z</TD>
<TD>~ expp1zap</TD>
</TR>

<TR>
<TD>expm1</TD>
<TD>~ expm1ap</TD>
</TR>

<TR>
<TD>expdiv</TD>
<TD>~ expdivap</TD>
</TR>

<TR>
<TD>ltexp2 , leexp2 , leexp2 , ltexp2d , leexp2d</TD>
<TD><I>none</I></TD>
<TD>Presumably provable, but the set.mm proof uses ltord1</TD>
</TR>

<TR>
<TD>ltexp2r , ltexp2rd</TD>
<TD><I>none</I></TD>
<TD>Presumably provable, but the set.mm proof uses ltexp2</TD>
</TR>

<TR>
<TD>sqdiv</TD>
<TD>~ sqdivap</TD>
</TR>

<TR>
<TD>sqgt0</TD>
<TD>~ sqgt0ap</TD>
</TR>

<TR>
<TD>sqrecii , sqrecd</TD>
<TD>~ exprecap</TD>
</TR>

<TR>
<TD>sqdivi</TD>
<TD>~ sqdivapi</TD>
</TR>

<TR>
<TD>sqgt0i</TD>
<TD>~ sqgt0api</TD>
</TR>

<TR>
<TD>sqlecan</TD>
<TD>~ lemul1</TD>
<TD>Unused in set.mm</TD>
</TR>

<TR>
<TD>sqeqori</TD>
<TD><I>none</I></TD>
<TD>The reverse direction is ~ oveq1 together with ~ sqneg .
The forward direction is presumably not provable, see mul0or for
more discussion.</TD>
</TR>

<TR>
<TD>subsq0i , sqeqor</TD>
<TD><I>none</I></TD>
<TD>Variations of sqeqori .</TD>
</TR>

<TR>
<TD>sq01</TD>
<TD><I>none</I></TD>
<TD>Lightly used in set.mm. Presumably not provable as stated,
for reasons analogous to mul0or .</TD>
</TR>

<TR>
<TD>crreczi</TD>
<TD><I>none</I></TD>
<TD>Presumably could be proved if not-equal is changed to apart,
but unused in set.mm.</TD>
</TR>

<TR>
<TD>expmulnbnd</TD>
<TD><I>none</I></TD>
<TD>Should be possible to prove this or something similar, but the
set.mm proof relies on case elimination based on whether ` 0 <_ A `
or not.</TD>
</TR>

<TR>
<TD>digit2 , digit1</TD>
<TD><I>none</I></TD>
<TD>Depends on modulus and floor, and unused in set.mm.</TD>
</TR>

<TR>
<TD>modexp</TD>
<TD><I>none</I></TD>
<TD>Depends on modulus. Presumably it, or something similar,
can be made to work as it is mostly about integers rather
than reals.</TD>
</TR>

<TR>
<TD>discr1 , discr</TD>
<TD><I>none</I></TD>
<TD>The set.mm proof uses real number trichotomy.</TD>
</TR>

<TR>
<TD>sqrecd</TD>
<TD>~ sqrecapd</TD>
</TR>

<TR>
<TD>expclzd</TD>
<TD>~ expclzapd</TD>
</TR>

<TR>
<TD>exp0d</TD>
<TD>~ expap0d</TD>
</TR>

<TR>
  <TD>expne0d</TD>
  <TD>~ expap0d</TD>
</TR>

<TR>
<TD>expnegd</TD>
<TD>~ expnegapd</TD>
</TR>

<TR>
<TD>exprecd</TD>
<TD>~ exprecapd</TD>
</TR>

<TR>
<TD>expp1zd</TD>
<TD>~ expp1zapd</TD>
</TR>

<TR>
<TD>expm1d</TD>
<TD>~ expm1apd</TD>
</TR>

<TR>
<TD>expsubd</TD>
<TD>~ expsubapd</TD>
</TR>

<TR>
<TD>sqdivd</TD>
<TD>~ sqdivapd</TD>
</TR>

<TR>
<TD>expdivd</TD>
<TD>~ expdivapd</TD>
</TR>

<TR>
<TD>reexpclzd</TD>
<TD>~ reexpclzapd</TD>
</TR>

<TR>
<TD>sqgt0d</TD>
<TD>~ sqgt0apd</TD>
</TR>

<TR>
  <TD>mulsubdivbinom2</TD>
  <TD><I>none</I></TD>
  <TD>Presumably provable if not equal is changed to apart.</TD>
</TR>

<TR>
  <TD>muldivbinom2</TD>
  <TD><I>none</I></TD>
  <TD>Presumably provable if not equal is changed to apart.</TD>
</TR>

<TR>
  <TD>nn0le2msqi</TD>
  <TD>~ nn0le2msqd</TD>
  <TD>Although nn0le2msqi could be proved, having a version in
  deduction form will be more useful.</TD>
</TR>

<TR>
  <TD>nn0opthlem1</TD>
  <TD>~ nn0opthlem1d</TD>
  <TD>Although nn0opthlem1 could be proved, having a version in
  deduction form will be more useful.</TD>
</TR>

<TR>
  <TD>nn0opthlem2</TD>
  <TD>~ nn0opthlem2d</TD>
  <TD>Although nn0opthlem2 could be proved, having a version in
  deduction form will be more useful.</TD>
</TR>

<TR>
  <TD>nn0opthi</TD>
  <TD>~ nn0opthd</TD>
  <TD>Although nn0opthi could be proved, having a version in
  deduction form will be more useful.</TD>
</TR>

<TR>
  <TD>nn0opth2i</TD>
  <TD>~ nn0opth2d</TD>
  <TD>Although nn0opth2i could be proved, having a version in
  deduction form will be more useful.</TD>
</TR>

<TR>
  <TD>facmapnn</TD>
  <TD>~ faccl</TD>
  <TD>We could express this in terms of ~ wf notation, or alternately
  define the mapping operation "^m" in iset.mm. But ~ faccl would be
  sufficient for the uses in set.mm.</TD>
</TR>

<TR>
  <TD>faclbnd4 , faclbnd5 , and lemmas</TD>
  <TD><I>none</I></TD>
  <TD>Presumably provable; unused in set.mm.</TD>
</TR>

<TR>
  <TD>bcval5</TD>
  <TD>~ ibcval5</TD>
</TR>

<TR>
  <TD>seqshft</TD>
  <TD><I>none currently</I></TD>
  <TD>need to figure out how to adjust this for the differences
  between set.mm and iset.mm concerning ` seq `.</TD>
</TR>

<TR>
  <TD>df-sgn and theorems related to the sgn function</TD>
  <TD><I>none</I></TD>
  <TD>To choose a value near zero requires knowing the argument
  with unlimited precision. It would be possible to define
  for rational numbers, or real numbers apart from zero.</TD>
</TR>

<TR>
<TD>mulre</TD>
<TD>~ mulreap</TD>
</TR>

<TR>
<TD>rediv</TD>
<TD>~ redivap</TD>
</TR>

<TR>
<TD>imdiv</TD>
<TD>~ imdivap</TD>
</TR>

<TR>
<TD>cjdiv</TD>
<TD>~ cjdivap</TD>
</TR>

<TR>
<TD>sqeqd</TD>
<TD><I>none</I></TD>
<TD>The set.mm proof is not intuitionistic, and this
theorem is unused in set.mm.</TD>
</TR>

<TR>
<TD>cjdivi</TD>
<TD>~ cjdivapi</TD>
</TR>

<TR>
<TD>cjdivd</TD>
<TD>~ cjdivapd</TD>
</TR>

<TR>
<TD>redivd</TD>
<TD>~ redivapd</TD>
</TR>

<TR>
<TD>imdivd</TD>
<TD>~ imdivapd</TD>
</TR>

<TR>
<TD>df-sqrt</TD>
<TD>~ df-rsqrt</TD>
<TD>See discussion of complex square roots in the comment of ~ df-rsqrt .
Here's one possibility if we do want to define square roots on (some)
complex numbers:
It should be possible to define the complex square root function on all
complex numbers satisfying ` ( Im `` x ) # 0 \/ 0 <_ ( Re `` x ) ` , using a
similar construction to the one used in set.mm. You need the real square
root as a basis for the construction, but then there is a trick using
the complex number x + |x| (see sqreu) that yields the complex square
root whenever it is apart from zero (you need to divide by it at one
point IIRC), which is exactly on the negative real line. You can either
live with this constraint, which gives you the complex square root except
on the negative real line (which puts a hole at zero), or you can extend
it by continuity to zero as well by joining it with the real square root.
The disjunctive domain of the resulting function might not be so
useful though.</TD>
</TR>

<TR>
<TD>sqrtval</TD>
<TD>~ sqrtrval</TD>
<TD>See discussion of complex square roots in the comment of ~ df-rsqrt</TD>
</TR>

<TR>
<TD>01sqrex and its lemmas</TD>
<TD>~ resqrex</TD>
<TD>Both set.mm and iset.mm prove resqrex although via different mechanisms
so there is no need for 01sqrex.</TD>
</TR>

<TR>
<TD>cnpart</TD>
<TD><I>none</I></TD>
<TD>See discussion of complex square roots in the comment of ~ df-rsqrt</TD>
</TR>

<TR>
<TD>sqrmo</TD>
<TD>~ rsqrmo</TD>
<TD>See discussion of complex square roots in the comment of ~ df-rsqrt</TD>
</TR>

<TR>
<TD>resqreu</TD>
<TD>~ rersqreu</TD>
<TD>Although the set.mm theorem is primarily about real square roots, the
iset.mm equivalent removes some complex number related parts.</TD>
</TR>

<TR>
<TD>sqrtneg , sqrtnegd</TD>
<TD><I>none</I></TD>
<TD>Although it may be possible to extend the domain of square root
somewhat beyond nonnegative reals without excluded middle, in
general complex square roots are difficult, as discussed
in the comment of ~ df-rsqrt</TD>
</TR>

<TR>
<TD>sqrtm1</TD>
<TD><I>none</I></TD>
<TD>Although it may be possible to extend the domain of square root
somewhat beyond nonnegative reals without excluded middle, in
general complex square roots are difficult, as discussed
in the comment of ~ df-rsqrt</TD>
</TR>

<TR>
<TD>absrpcl , absrpcld</TD>
<TD>~ absrpclap , ~ absrpclapd</TD>
</TR>

<TR>
<TD>absdiv , absdivzi , absdivd</TD>
<TD>~ absdivap , ~ absdivapzi , ~ absdivapd</TD>
</TR>

<TR>
<TD>absor , absori , absord</TD>
<TD>~ qabsor</TD>
<TD>It also would be possible to prove this for real numbers apart from zero,
if we wanted</TD>
</TR>

<TR>
<TD>absmod0</TD>
<TD><I>none</I></TD>
<TD>See df-mod ; we may want to supply this for rationals or integers</TD>
</TR>

<TR>
<TD>absexpz</TD>
<TD>~ absexpzap</TD>
</TR>

<TR>
<TD>max0add</TD>
<TD>~ max0addsup</TD>
</TR>

<TR>
<TD>absz</TD>
<TD><I>none</I></TD>
<TD>Although this is presumably provable, the set.mm proof is not
intuitionistic and it is lightly used in set.mm</TD>
</TR>

<TR>
  <TD>recval</TD>
  <TD>~ recvalap</TD>
</TR>

<TR>
  <TD>absgt0 , absgt0i</TD>
  <TD>~ absgt0ap , absgt0api</TD>
</TR>

<TR>
  <TD>absmax</TD>
  <TD>~ maxabs</TD>
</TR>

<TR>
  <TD>abs1m</TD>
  <TD><I>none</I></TD>
  <TD>Because this theorem provides ` ( * `` A ) / ( abs `` A ) ` as the
  answer if ` A =/= 0 ` and ` i ` as the answer if ` A = 0 ` , and uses
  excluded middle to combine those cases, it is presumably not provable
  as stated. We could prove the theorem with the additional condition
  that ` A # 0 ` , but it is unused in set.mm.</TD>
</TR>

<TR>
  <TD>abslem2</TD>
  <TD><I>none</I></TD>
  <TD>Although this could presumably be proved if not equal were
  changed to apart, it is lightly used in set.mm.</TD>
</TR>

<TR>
  <TD>rddif , absrdbnd</TD>
  <TD><I>none</I></TD>
  <TD>If there is a need, we could prove these for rationals or real
  numbers apart from any rational. Alternately, we could prove a result
  with a slightly larger bound for any real number.</TD>
</TR>

<TR>
  <TD>rexuzre</TD>
  <TD><I>none</I></TD>
  <TD>Unless the real number ` j ` is known to be apart from an
  integer, it isn't clear there would be any way to prove this
  (see the steps in the set.mm proof which rely on the floor of
  a real number). It is unused in set.mm for whatever that is worth.</TD>
</TR>

<TR>
  <TD>caubnd</TD>
  <TD><I>none</I></TD>
  <TD>If we can prove fimaxre3 it would appear that the set.mm
  proof would work with small changes (in the case of the maximum
  of two real numbers, using ~ maxle1 , ~ maxle2 , and ~ maxcl ).</TD>
</TR>

<TR>
  <TD>sqreulem , sqreu , sqrtcl , sqrtcld , sqrtthlem , sqrtf ,
  sqrtth , sqsqrtd , msqsqrtd , sqr00d , sqrtrege0 , sqrtrege0d ,
  eqsqrtor , eqsqrtd , eqsqrt2d</TD>
  <TD>~ rersqreu , ~ resqrtcl , ~ resqrtcld , ~ resqrtth</TD>
  <TD>As described at ~ df-rsqrt , square roots of complex numbers
  are in set.mm defined with the help of excluded middle.</TD>
</TR>

<TR>
  <TD>df-limsup and all superior limit theorems</TD>
  <TD><I>none</I></TD>
  <TD>This is not developed in iset.mm currently. If it was it
  would presumably be noticeably different from set.mm given
  various differences relating to sequence convergence,
  supremums, etc.</TD>
</TR>

<TR>
  <TD>df-rlim and theorems related to limits of partial
  functions on the reals</TD>
  <TD><I>none</I></TD>
  <TD>This is not developed in iset.mm currently. If it was it
  would presumably be noticeably different from set.mm given
  various differences relating to convergence.</TD>
</TR>

<TR>
  <TD>df-o1 and theorems related to eventually bounded functions</TD>
  <TD><I>none</I></TD>
  <TD>This is not developed in iset.mm currently. If it was it
  would presumably be noticeably different from set.mm given
  various differences relating to sequence convergence,
  supremums, etc.</TD>
</TR>

<TR>
  <TD>df-lo1 and theorems related to eventually upper bounded
  functions</TD>
  <TD><I>none</I></TD>
  <TD>This is not developed in iset.mm currently. If it was it
  would presumably be noticeably different from set.mm given
  various differences relating to sequence convergence,
  supremums, etc.</TD>
</TR>

<TR>
  <TD>serclim0</TD>
  <TD>~ iserclim0</TD>
  <TD>The only difference is the syntax of ` seq ` .</TD>
</TR>

<TR>
  <TD>reccn2</TD>
  <TD><I>none yet</I></TD>
  <TD>Will need to be revamped to deal with negated equality
  versus apartness and perhaps other issues.</TD>
</TR>

<TR>
  <TD>clim2ser</TD>
  <TD>~ clim2iser</TD>
  <TD>The only difference is the syntax of ` seq ` .</TD>
</TR>

<TR>
  <TD>clim2ser2</TD>
  <TD>~ clim2iser2</TD>
  <TD>The only difference is the syntax of ` seq ` .</TD>
</TR>

<TR>
  <TD>iserex</TD>
  <TD>~ iiserex</TD>
  <TD>The only difference is the syntax of ` seq ` .</TD>
</TR>

<TR>
  <TD>isermulc2</TD>
  <TD>~ iisermulc2</TD>
  <TD>The only difference is the syntax of ` seq ` .</TD>
</TR>

<TR>
  <TD>iserle</TD>
  <TD>~ iserile</TD>
  <TD>The only difference is the syntax of ` seq ` .</TD>
</TR>

<TR>
  <TD>iserge0</TD>
  <TD>~ iserige0</TD>
  <TD>The only difference is the syntax of ` seq ` .</TD>
</TR>

<TR>
  <TD>climserle</TD>
  <TD>~ climserile</TD>
  <TD>The only difference is the syntax of ` seq ` .</TD>
</TR>

<TR>
  <TD>isershft</TD>
  <TD><I>none yet</I></TD>
  <TD>Relies on seqshft</TD>
</TR>

<TR>
  <TD>isercoll and its lemmas, isercoll2</TD>
  <TD><I>none yet</I></TD>
  <TD>The set.mm proof would need modification</TD>
</TR>

<TR>
  <TD>climsup</TD>
  <TD><I>none</I></TD>
  <TD>To show convergence would presumably require a hypothesis
  related to the rate of convergence.</TD>
</TR>

<TR>
  <TD>climbdd</TD>
  <TD><I>none</I></TD>
  <TD>Presumably could be proved but the current proof of caubnd
  would need at least some minor adjustments.</TD>
</TR>

<TR>
  <TD>caurcvg2</TD>
  <TD>~ climrecvg1n</TD>
</TR>

<TR>
  <TD>caucvg</TD>
  <TD>~ climcvg1n</TD>
</TR>

<TR>
  <TD>caucvgb</TD>
  <TD>~ climcaucn , ~ climcvg1n</TD>
  <TD>Without excluded middle, there are additional complications
  related to the rate of convergence.</TD>
</TR>

<TR>
  <TD>serf0</TD>
  <TD>~ serif0</TD>
  <TD>The only difference is the syntax of ` seq ` .</TD>
</TR>

<TR>
  <TD>iseralt</TD>
  <TD><I>none</I></TD>
  <TD>The set.mm proof relies on caurcvg2 which does not specify
  a rate of convergence.</TD>
</TR>

<TR>
  <TD>df-sum</TD>
  <TD>~ df-isum</TD>
  <TD>Although this defintion is intended to function similarly to
  the set.mm one, a lot of details have to be changed, especially
  around decidability, to make sum work.</TD>
</TR>

<TR>
  <TD>sumex</TD>
  <TD><I>none</I></TD>
  <TD>This will need to replaced by suitable closure theorems.</TD>
</TR>

<TR>
  <TD>sumeq2w</TD>
  <TD>sumeq2</TD>
  <TD>Presumably could be proved, and perhaps also would rely only
  on extensionality (and logical axioms). But unused in set.mm.</TD>
</TR>

<TR>
  <TD>sumeq2ii</TD>
  <TD>~ sumeq2d</TD>
</TR>

<TR>
  <TD>df-prod and theorems using it</TD>
  <TD><I>none</I></TD>
  <TD>To define this, will need to tackle all the issues
  with ~ df-isum plus some more around, for example, not equal to zero
  versus apart from zero</TD>
</TR>

<TR>
  <TD>dvdsaddre2b</TD>
  <TD><I>none</I></TD>
  <TD>Something along these lines (perhaps with real changed to
  rational) may be possible</TD>
</TR>

<TR>
  <TD>fsumdvds , 3dvds</TD>
  <TD><I>none</I></TD>
  <TD>May be possible when summation is well enough developed</TD>
</TR>

<TR>
  <TD>sumeven , sumodd , evensumodd , oddsumodd , pwp1fsum , oddpwp1fsum</TD>
  <TD><I>none</I></TD>
  <TD>Presumably possible when summation is well enough developed</TD>
</TR>

<TR>
  <TD>divalglem0 and other ~ divalg lemmas</TD>
  <TD>~ divalglemnn and other lemmas</TD>
  <TD>Since the end result ~ divalg is the same, we don't list
  all the differences in lemmas here.</TD>
</TR>

<TR>
  <TD>gcdcllem1 , gcdcllem2 , gcdcllem3</TD>
  <TD>~ gcdn0cl , ~ gcddvds , ~ dvdslegcd</TD>
  <TD>These are lemmas which are part of the proof of theorems
  that iset.mm proves a somewhat different way</TD>
</TR>

<TR>
  <TD>seq1st</TD>
  <TD><I>none</I></TD>
  <TD>The second argument to ` seq ` , at least as handled in
  theorems such as ~ iseqfn , must be defined on all integers
  greater than or equal to ` M ` , not just at ` M ` itself.
  It may be possible to patch this up, but seq1st is unused in
  set.mm.</TD>
</TR>

<TR>
  <TD>algr0</TD>
  <TD>~ ialgr0</TD>
  <TD>Several hypotheses are tweaked or added to reflect differences in how
  ` seq ` works</TD>
</TR>

<TR>
  <TD>algrf</TD>
  <TD>~ ialgrf</TD>
  <TD>Several hypotheses are tweaked or added to reflect differences in how
  ` seq ` works</TD>
</TR>

<TR>
  <TD>algrp1</TD>
  <TD>~ ialgrp1</TD>
  <TD>Several hypotheses are tweaked or added to reflect differences in how
  ` seq ` works</TD>
</TR>

<TR>
  <TD>alginv</TD>
  <TD>~ ialginv</TD>
  <TD>Two hypotheses are tweaked or added to reflect differences in how
  ` seq ` works</TD>
</TR>

<TR>
  <TD>algcvg</TD>
  <TD>~ ialgcvg</TD>
  <TD>` seq ` as defined in ~ df-iseq has a third argument</TD>
</TR>

<TR>
  <TD>algcvga</TD>
  <TD>~ ialgcvga</TD>
  <TD>Two hypotheses are tweaked or added to reflect differences in how
  ` seq ` works</TD>
</TR>

<TR>
  <TD>algfx</TD>
  <TD>~ ialgfx</TD>
  <TD>Two hypotheses are tweaked or added to reflect differences in how
  ` seq ` works</TD>
</TR>

<TR>
  <TD>eucalg</TD>
  <TD>~ eucialg</TD>
  <TD>Tweaked for the different ` seq ` syntax</TD>
</TR>

<TR>
  <TD>df-lcmf and theorems using it</TD>
  <TD><I>none</I></TD>
  <TD>Although this could be defined, most of the theorems would
  need decidability conditions analogous to ~ zsupcl</TD>
</TR>

<TR>
  <TD>absproddvds , absprodnn</TD>
  <TD><I>none</I></TD>
  <TD>Needs product to be developed, but once that is done seems
  like it might be possible.</TD>
</TR>

<TR>
  <TD>fissn0dvds , fissn0dvdsn0</TD>
  <TD><I>none</I></TD>
  <TD>Possibly could be proved using ~ findcard2 or the like.</TD>
</TR>

<TR>
  <TD>coprmprod , coprmproddvds</TD>
  <TD><I>none</I></TD>
  <TD>Can investigate once product is better developed.</TD>
</TR>

<TR>
  <TD>isprm5</TD>
  <TD><I>none</I></TD>
  <TD>Presumably provable, but the set.mm proof relies on excluded
  middle in multiple places.</TD>
</TR>

<TR>
  <TD>isprm7</TD>
  <TD><I>none</I></TD>
  <TD>The set.mm proof relies on isprm5</TD>
</TR>

<TR>
  <TD>maxprmfct</TD>
  <TD><I>none</I></TD>
  <TD>Presumably provable with suitable adjustments to the
  condition for the existence of the supremum</TD>
</TR>

<TR>
  <TD>ncoprmlnprm</TD>
  <TD><I>none</I></TD>
  <TD>Presumably provable but the set.mm proof uses excluded middle</TD>
</TR>

</TABLE>

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<LI><A NAME="Mendelson"></A> [Mendelson] Mendelson, Elliott, <I>Introduction to
Mathematical Logic,</I> 2nd ed., D. Van Nostrand (1979) [QA9.M537].</LI>

<LI><A NAME="Monk1"></A> [Monk1] Monk, J. Donald, <I>Introduction to Set
Theory,</I> McGraw-Hill, Inc. (1969) [QA248.M745].</LI>

<LI><A NAME="Monk2"></A> [Monk2] Monk, J. Donald, &quot;Substitutionless
Predicate Logic with Identity,&quot; <I>Archiv f&uuml;r Mathematische Logik
und Grundlagenforschung,</I> 7:103-121 (1965) [QA.A673].</LI>

<LI><A NAME="Quine"></A> [Quine] Quine, Willard van Orman, <I>Set Theory
and Its Logic,</I> Harvard University Press, Cambridge, Massachusetts,
revised edition (1969) [QA248.Q7 1969].</LI>

<LI><A NAME="Sanford"></A> [Sanford] Sanford, David H., <I>If P, then Q:
Conditionals and the Foundations of Reasoning</I>, 2nd ed., Routledge
Taylor &amp; Francis Group (2003); ISBN 0-415-28369-8; available at <A
HREF="https://books.google.com/books?id=h_AUynB6PA8C&amp;pg=PA39#v=onepage&amp;q&amp;f=false">https://books.google.com/books?id=h_AUynB6PA8C&amp;pg=PA39#v=onepage&amp;q&amp;f=false</A>
(retrieved 3 Jul 2016).</LI>

<LI><A NAME="Schechter"></A> [Schechter] Schechter, Eric, <I>Handbook of
Analysis and Its Foundations</I>, Academic Press, San Diego (1997)
[QA300.S339].</LI>

<LI><A NAME="Stoll"></A> [Stoll] Stoll, Robert R., <I>Set Theory and Logic,</I>
Dover Publications, Inc. (1979) [QA248.S7985 1979].</LI>

<LI><A NAME="Suppes"></A> [Suppes] Suppes, Patrick, <I>Axiomatic Set Theory,</I>
Dover Publications, Inc. (1972) [QA248.S959].</LI>

<LI><A NAME="TakeutiZaring"></A> [TakeutiZaring] Takeuti, Gaisi, and
Wilson M. Zaring, <I>Introduction to Axiomatic Set Theory,</I>
Springer-Verlag, New York, second edition (1982) [QA248.T136 1982].</LI>

<LI><A NAME="Tarski"></A> [Tarski] Tarski, Alfred, &quot;A Simplified
Formalization of Predicate Logic with Identity,&quot; <I>Archiv f&uuml;r
Mathematische Logik und Grundlagenforschung,</I> 7:61-79 (1965)
[QA.A673].</LI>

<LI><A NAME="WhiteheadRussell"></A> [WhiteheadRussell] Whitehead, Alfred
North, and Bertrand Russell, <I>Principia Mathematica to *56,</I>
Cambridge University Press, Cambridge, 1962 [QA9.W592 1962].</LI>

</OL>


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