131 lines
4.6 KiB
XML
131 lines
4.6 KiB
XML
$( miu.mm 20-Oct-2008 $)
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$(
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~~ PUBLIC DOMAIN ~~
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This work is waived of all rights, including copyright, according to the CC0
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Public Domain Dedication. http://creativecommons.org/publicdomain/zero/1.0/
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Norman Megill - email: nm at alum.mit.edu
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$)
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$( The MIU-system: A simple formal system $)
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$( Note: This formal system is unusual in that it allows empty wffs.
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To work with a proof, you must type SET EMPTY_SUBSTITUTION ON before
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using the PROVE command. By default this is OFF in order to reduce the
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number of ambiguous unification possibilities that have to be selected
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during the construction of a proof. $)
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$(
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Hofstadter's MIU-system is a simple example of a formal
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system that illustrates some concepts of Metamath. See
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Douglas R. Hofstadter, "G\"{o}del, Escher, Bach: An Eternal
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Golden Braid" (Vintage Books, New York, 1979), pp. 33ff. for
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a description of the MIU-system.
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The system has 3 constant symbols, M, I, and U. The sole
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axiom of the system is MI. There are 4 rules:
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Rule I: If you possess a string whose last letter is I,
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you can add on a U at the end.
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Rule II: Suppose you have Mx. Then you may add Mxx to
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your collection.
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Rule III: If III occurs in one of the strings in your
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collection, you may make a new string with U in place
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of III.
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Rule IV: If UU occurs inside one of your strings, you
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can drop it.
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Note: The following comment applied to an old version of the Metamath
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spec that didn't require $f (variable type) hypotheses for variables and
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is no longer applicable. The current spec was made stricter primarily
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to reduce the likelihood of inconsistent toy axiom systems, effectively
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requiring the concept of an "MIU wff" anyway. However, I am keeping the
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comment for historical reasons, if only to point out an intrinsic
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difference in Rules III and IV that might have relevance to other proof
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systems.
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Old comment, obsolete: "Unfortunately, Rules III and IV do not have
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unique results: strings could have more than one occurrence of III or
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UU. This requires that we introduce the concept of an "MIU well-formed
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formula" or wff, which allows us to construct unique symbol sequences to
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which Rules III and IV can be applied."
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Under the old Metamath spec, the problem this caused was that without
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the construction of specific wffs to substitute for their variables,
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Rules III and IV would sometimes not have unique unifications (as
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required by the spec) during a proof, making proofs more difficult or
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even impossible.
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$)
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$( First, we declare the constant symbols of the language.
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Note that we need two symbols to distinguish the assertion
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that a sequence is a wff from the assertion that it is a
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theorem; we have arbitrarily chosen "wff" and "|-". $)
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$c M I U |- wff $. $( Declare constants $)
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$( Next, we declare some variables. $)
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$v x y $.
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$( Throughout our theory, we shall assume that these
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variables represent wffs. $)
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wx $f wff x $.
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wy $f wff y $.
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$( Define MIU-wffs. We allow the empty sequence to be a
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wff. $)
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$( The empty sequence is a wff. $)
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we $a wff $.
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$( "M" after any wff is a wff. $)
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wM $a wff x M $.
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$( "I" after any wff is a wff. $)
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wI $a wff x I $.
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$( "U" after any wff is a wff. $)
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wU $a wff x U $.
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$( If "x" and "y" are wffs, so is "x y". This allows the conclusion of
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` IV ` to be provable as a wff before substitutions into it, for those
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parsers requiring it. (Added per suggestion of Mel O'Cat 4-Dec-04.) $)
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wxy $a wff x y $.
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$( Assert the axiom. $)
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ax $a |- M I $.
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$( Assert the rules. $)
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${
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Ia $e |- x I $.
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$( Given any theorem ending with "I", it remains a theorem
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if "U" is added after it. (We distinguish the label I_
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from the math symbol I to conform to the 24-Jun-2006
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Metamath spec change.) $)
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I_ $a |- x I U $.
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$}
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${
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IIa $e |- M x $.
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$( Given any theorem starting with "M", it remains a theorem
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if the part after the "M" is added again after it. $)
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II $a |- M x x $.
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$}
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${
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IIIa $e |- x I I I y $.
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$( Given any theorem with "III" in the middle, it remains a
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theorem if the "III" is replace with "U". $)
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III $a |- x U y $.
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$}
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${
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IVa $e |- x U U y $.
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$( Given any theorem with "UU" in the middle, it remains a
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theorem if the "UU" is deleted. $)
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IV $a |- x y $.
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$}
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$( Now we prove the theorem MUIIU. You may be interested in
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comparing this proof with that of Hofstadter (pp. 35 - 36). $)
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theorem1 $p |- M U I I U $=
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we wM wU wI we wI wU we wU wI wU we wM we wI wU we wM
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wI wI wI we wI wI we wI ax II II I_ III II IV $.
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