Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

I am trying to augment FOL.thy with the quantifier MOST, which I intend to define as the simple majority, i.e.,

(MOST x. P(x)) ==> card P(x) > card ~P(x).

I am not sure how to modify the FOL.thy file. Under axiomatization, I thought to add:

Most :: "('a => o) => o"  (binder "MOST " 10)

and, beneath the where clause:

specM: "(ALL x. P(x)) ==> (MOST x. P(x))" and
mostI: "(MOST x. P(x)) ==> ..."

where "..." is the proper way of expressing the constraint as outlined above, w.r.t. the cardinality of P(x) and ~P(x). (Again, I wasn't sure on a good name here and suggestions are welcome.)

I thought to add an entry in the "symbols" section and, for lack of better ideas, chose to use delta:

Most (binder "∆" 10)

And likewise in the notation section.

1) How do I properly express the cardinality constraint?

2) What other things do I need to modify?

To the latter question, it might be helpful to point out that, ultimately, I want to assess whether a number of different conclusions are necessary, possible, or impossible, given premises that will include quantified assertions using 'Most' and 'All' (as well as conjunctions, disjunctions, etc.).

share|improve this question
    
I edited your post s.t. Most is the basic constant (a usage would be like Most (%x. P x)) and MOST the corresponding binder (which is just nicer notation for the same constant, i.e., MOST x. P x). –  chris Oct 1 '13 at 0:52
    
Two questions: 1) which FOL.thy are you talking about? The one from the Isabelle2013 distribution? Then it should rather be IFOL.thy I guess (on which FOL.thy is based and which contains the basic constant definitions). 2) What do you mean by "symbols" section above? –  chris Oct 1 '13 at 0:56
    
Btw: For your definition to make sense you need a theory where you have cardinal numbers with a "less than" comparison. It seems that FOL alone is to weak for your purpose. (In HOL, e.g., the card function for the number of elements in a set is only defined on finite sets and thus would also not help in your case; unless you wanted a predicate P that is only true for finitely many "inputs" and whose negation is true infinitely often to be *Most*ly true.) –  chris Oct 1 '13 at 1:08
    
@chris, you are entirely correct that FOL is weak and I would need some HOL. I thought card was available within FOL. As to your other comments - the 'symbols' section was simply a part of the file in which it seemed symbols were being defined. I have avoided doing the legwork of learning how Isabelle functions, because it's not really the goal of my project, but it seems I should put the time in. If you do decide to answer, I will mark it as being helpful. –  CrashMaster Oct 1 '13 at 7:59
add comment

1 Answer

Unless there is a particular reason, it is generally better to take Isabelle/HOL as starting point for whatever application you have in mind.

The argument whether FOL or HOL is stronger depends on additional axiomatization. Isabelle/ZF provides full Zermelo-Fraenkel set-theory on top of FOL, so it is more expressive than plain HOL, but its tools and libraries are almost 20 years behind.

Instead of starting at the bottom HOL.thy, you should enter the game at the top with theory Main, potentially with some further theories from $ISABELLE_HOME/src/HOL/Library.

Your sketches with Most remind me of $ISABELLE_HOME/src/HOL/Library/Infite_Set although that is about more interesting infinite sets. There are further theories about ordinals and cardinals in HOL to be discovered. It depends what is ultimately your application.

share|improve this answer
add comment

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.