Continuum Hypothesis: Truth and Provability in FOL

In summary, "Continuum Hypothesis: Truth and Provability in FOL" explores the status of the Continuum Hypothesis (CH) within the framework of First-Order Logic (FOL). It examines the relationship between the truth of CH, its provability in set theory, and the implications of Gödel's and Cohen's work on independence results. The paper discusses how CH can be true in some models of set theory while also being unprovable in others, highlighting the complexities of mathematical truth versus formal provability.
  • #1
WWGD
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Hi,
Just to test my understanding. Is it the case that the Continuum Hypothesis( CH) is not considered true within ZFC because there are both models/interpretations of ZFC where CH holds , as well as models/interpretations of ZFC where it doesn't, whereas truth of a ( statement?)in FOL requires that the statement hold in all models/interpretations, here referring to interpretations of ZFC?
Thanks.
Edit,
Maybe
@stevendaryl Can chime in?
 
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  • #2
I think the inferred meaning of terms like 'True' in relation to a sentence in a formal language will vary depending on which semantic theory we are using, and even on which textbook we are referring to.
Most semantics I've seen use the term True in relation to a specific interpretation. That is, they say a sentence S is True in interpretation R.

Given a theory T (a set of well-formed sentences closed under deduction) in language L, we call an interpretation of L a model of theory T if it assigns True to every sentence in T.

ZFC is a theory in the language of first order predicate logic (FOPL). The CH can be expressed as a well-formed sentence of FOPL but is not part of the theory ZFC, as it cannot be deduced from ZFC's axioms.

I see that wikipedia (I know!) suggests that we call a sentence S in a formal language L logically valid with respect to a theory T if every model of T in L assigns the value True to S, and consistent if at least one model of T in L assigns the value True to S; otherwise T is inconsistent. The status of being logically valid, consistent or inconsistent depends on all three of sentence S, theory T and language L.

Using that terminology, we'd say the sentence CH of language FOPL is consistent wrt theory ZFC but not logically valid.
 
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  • #3
Thanks, Andrew, I believe too, there was a result linking truth in the above sense, with provability, right?
 
  • #4
andrewkirk said:
Using that terminology, we'd say the sentence CH of language FOPL is consistent wrt theory ZFC but not logically valid.
You can of course say exactly the same about the sentence "Not CH".
 
  • #5
WWGD said:
Thanks, Andrew, I believe too, there was a result linking truth in the above sense, with provability, right?
No, a sentence can be true but unprovable (incompleteness theorem).
 
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  • #6
pbuk said:
No, a sentence can be true but unprovable (incompleteness theorem).
Yes, thanks, I understand they're not equivalent, but I thought there were some results connecting the two, IIRC, soundness was one. Somehow I can't find straight answers from a search.
Edit: Well, here's something on soundness, from Wikipedia:
Screenshot_20231012_123804_Samsung Internet.jpg
 
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  • #7
In what follows consistency is assumed through-out (to avoid adding a qualification to every sentence). At the very first level the following can be thought of as an answer to the question:
https://www.physicsforums.com/threa...xiom-or-a-theorem.1053712/page-2#post-6913946
I will quote the relevant part here:
SSequence said:
If we have an incomplete theory under consideration [as often happens to be the case] then (assuming consistency) every statement exactly falls into one of the following three categories:
(i) provable in the theory (or a theorem of the theory)
(ii) disproveable in the theory
(iii) independent

And once again the statements in category-(ii) that would be disproveable (in the theory) would have their negation as a theorem [theorem of the theory that is].

So in that sense CH just falls into category-(iii).==============================Here is a somewhat more detailed way of looking at it (and also sort of a heuristic way of thinking about it). But it is still quite basic of course and lacks depth and detailed justification for (too many) finer points (which I don't know either). It is more of a heuristic description as a way of looking at it. However, lacking detailed understanding, I still found it fairly useful.

Essentially we think of "world of sets" as given to us [or perhaps in other words "collection of all sets"]. This is denoted by ##V## (also called cumulative hierarchy). It can be thought of as the power-set operation running through the ordinals. We set ##V_{0}## as the empty set. Next we set ##V_{\alpha+1}=\mathcal{P}(V_{\alpha})##. For limit ordinals ##\alpha##, ##V_{\alpha}## is defined as the union of all lower levels. The following two points are quite basic but are worth mentioning because of their importance:
(a) For every set ##A##, there would exist some (smallest) ordinal ##\alpha## such that ##A \in V_{\alpha}##.
(b) For all ordinals ##\alpha##, ##V_{\alpha}## will be a set. However, ##V## itself is not a set.Now when we talk about models, there are two kinds of "models":
(i) set models
(ii) class models

A more complete description is well-beyond my own understanding/knowledge. However, knowing a few points about models is fairly useful (to get a very rough picture):
(a) A set model is, as the name implies, just a set.
(b) A class model can be thought of as a "collection" in some sense. However, they aren't sets. That's because class models pick elements from ##V_{\alpha}## with ##\alpha## taking arbitrarily large values in ##\mathrm{Ord}##. In an informal sense, they are too big to be sets.
(c) Normally texts often just "write" model with the context of whether a "set model" or "class model" is being talked about as understood from the context.
(d) There is a certain (precise) sense which makes qualifies a "set/class model" as a "model". Informally it is said that a model satisfies all the axioms of ZF(C) [and I think the sense is probably slightly different for set models and class models]. However, to be honest, I don't really know what that means in a more precise sense. I had quite vague sense of it few years back, but I have forgotten it. If you look up for it you might be able to find some descriptions at least.

Nevertheless, if you picked up any specific set from ##V##, it will either be a (set) model or it won't.

(e) Quite importantly, the "world of sets" ##V## itself is a class model.
Sorry this got a bit long. But now coming to the question, what does this have to do with CH? You already kind of described it in your question. Basically every statement/question that can posed in ZF(C) [and basically CH is one of them] has either a true or false value in a specific model [be it a set model or a class model]. Now this is how it relates to your initial question. When we think about any specific ##V##, the value of CH will be either true or false in the given ##V##. There will be no two ways about it.

For example, suppose that our ##V## is what is called "constructible universe" [note that word "universe" is a just a mathematical usage]. Then CH will be true in such a ##V##. In fact, GCH is also true in such a ##V##.

However, it is also possible to have a ##V## where ##CH## is false. But it is perfectly possible that we could have class models [that, very informally, select a sub-collection of the elements in ##V## using something like a additional axiom I think] for such a ##V## where ##CH## could be true.

And that is just about the limit of the depth of my understanding for the specific question at hand :P.
 
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FAQ: Continuum Hypothesis: Truth and Provability in FOL

What is the Continuum Hypothesis?

The Continuum Hypothesis (CH) is a mathematical conjecture proposed by Georg Cantor in 1878. It posits that there is no set whose cardinality is strictly between that of the integers and the real numbers. In other words, it suggests that the cardinality of the continuum (the real numbers) is the next cardinal number after that of the integers.

Is the Continuum Hypothesis true or false?

The Continuum Hypothesis is independent of the standard axioms of set theory (Zermelo-Fraenkel set theory with the Axiom of Choice, or ZFC). This means that it can neither be proved nor disproved using these axioms. Kurt Gödel and Paul Cohen showed that both the hypothesis and its negation are consistent with ZFC, assuming ZFC itself is consistent.

What does "provability in FOL" mean in the context of the Continuum Hypothesis?

First-order logic (FOL) refers to a formal system used in mathematics, philosophy, linguistics, and computer science. In the context of the Continuum Hypothesis, "provability in FOL" means determining whether the hypothesis can be proven true or false within the framework of first-order logic, specifically within the axioms of set theory. Since CH is independent of ZFC, it is not provable or disprovable within this framework.

What are the implications of the independence of the Continuum Hypothesis?

The independence of the Continuum Hypothesis means that mathematicians can choose whether to include it as an axiom in their set-theoretic frameworks. This has led to the development of different mathematical universes where CH is true and others where it is false. It also highlights the limitations of our current axiomatic systems and suggests that additional axioms might be needed to resolve such questions.

Are there any alternative approaches to resolving the Continuum Hypothesis?

Some mathematicians and logicians explore alternative set theories or extensions of ZFC to address the Continuum Hypothesis. For instance, large cardinal axioms and forcing techniques are areas of research that might offer new insights. However, no universally accepted solution has emerged, and the independence results by Gödel and Cohen remain a central aspect of understanding CH.

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