I am trying to understand the Veblen hierarchy but I still find it confusing. The Feferman–Schütte ordinal, $\Gamma_0$, can be described as the set of all ordinals that can be written as finite expressions, starting from zero, using only the Veblen hierarchy and addition. The Veblen hierarchy starts with the function $\omega^\alpha$ and uses recursion to generate larger and larger functions. But I am not sure why we start with $f(\alpha)=\omega^\alpha$, or why we restrict the definition of $\Gamma_0$ to Veblen hierarchy and addition. Would we obtain recursive ordinals larger than $\Gamma_0$ if we start the hierarchy with some faster growing function? For instance we can use hyperoperators to define $f(\alpha)=(\alpha\uparrow ^\alpha \alpha)^{(\alpha)}$ (where the upperscript $(\alpha)$ means $\alpha$-times composition) which is immensely huge. We could also include this new hierarchy plus addition and any hyperoperator to define the limit $\Gamma_0$. But it is not clear to me if doing it this way results in the same $\Gamma_0$, or in a larger (but still predicative?) one.
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4$\Gamma_0$ has the property that whenever you pick ordinals $\alpha < \Gamma_0$ and $\beta < \Gamma_{0},$ then the hyper-operation of $\alpha$'th order applied to $\beta$ will be less than $\Gamma_{0}.$ That is, to reach $\Gamma_0$ by applying a hyper-operation of some transfinite order to a transfinite ordinal, you need to have at least one of these transfinite's reach $\Gamma_{0}.$ To make this precise we would have to define these hyper-operations, including those having limit ordinal orders (an Ackermann function type of double recursion of the lower orders handles a limit ordinal order). – Dave L. Renfro May 10 '13 at 21:02
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@DaveL.Renfro Thanks, you should put this as an answer! Do you have any textbook or reference where I can see a detailed proof of this? – Wolphram jonny May 11 '13 at 06:37
1 Answers
This is mostly a more extended version of my comment. As for a book or published paper where $\Gamma_0$ is carefully and rigorously obtained, probably the best I know of is:
Wolfram Pohlers, Proof Theory. The First Step into Impredicativity, 2008.
However, the audience and goals of Pohlers' book are quite distant (in my opinion) from the basic ideas behind normal functions on ordinals and fixed-points of normal functions, which I think have not had enough exposition about in the mathematical literature. For example, pick up any of the dozens of introductory set theory books and many more related books (in real analysis, topology, etc.) in which ordinals are discussed, and you'll see nearly identical discussions of how the countable ordinals include $\epsilon_0$ and beyond (but no author seems to vary on this and indicate, even if briefly, some of the interesting things that lie in the "and beyond" realm), and if you pick up any of the more advanced books and papers in set theory and in proof theory where large countable ordinals are discussed, you're in for a whirlwind ride in which $\epsilon_0$ and $\Gamma_0$ are barely mentioned as bacteria on a microscope slide in the quest to reach the distant quasars of ever more exotic recursive ordinal notations, which are cryptically pitched to an audience of a few specialists. There seem to be no middle-ground expositions of this topic.
Maybe A short introduction to Ordinal Notations by Harold Simmons comes close to being a middle-ground exposition.
However, I think much better is the following, which is not written with applications of large ordinals to proof theory as its end goal. Instead, the focus is on the ride up through the ordinals.
John Baez, This Week's Finds in Mathematical Physics (Week 236; 26 July 2006)
Also, look up diagonal intersection. I believe this is the operation that takes you from ordinals defined via the $\alpha$'th order hyper-operation (applied to $\beta$) to $\Gamma_{0}.$
Finally, below are some things I've posted elsewhere that may be of use. Incidentally, I never continued the treatment of ordinal numbers I began in the first post below, as I wound up getting busy at work. I also started to think that it wasn't such a good idea to spend so much time preparing ASCII expositions of things that I had planned to write up more formally in LaTeX and distribute in some manner (publication, math arXiv site, or perhaps just toss out like I did with this).
Renfro, ORDINAL NUMBERS #1, sci.math, 29 October 2006. [Last version of this essay. See the discussion at the end concerning ${\omega}^{\omega}$ being simultaneously the ${\omega}^{\omega}$'th ordinal and the ${\omega}^{\omega}$'th limit ordinal.]
Renfro, Transfinite Aleph and Beth ordinal sequences, sci.math, 23 November 2003.
Renfro, fixed points with ordinal maps, sci.math, 30 November 2008. [See also the follow-up on 2 December 2008.]
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2Another excellent reference on $\Gamma_0$ is the survey paper: Jean H. Gallier. What's so special about Kruskal's theorem and the ordinal $\Gamma_0$? A survey of some results in proof theory, Ann. Pure Appl. Logic 53 (3), (1991), 199-260. Also, Erratum, Ann. Pure Appl. Logic 89 (2-3), (1997), 275. – Andrés E. Caicedo May 12 '13 at 04:54
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1For those who might be interested, sometime in the next few days or so (certainly within two weeks from now) I'll step up to the plate so to speak and post some results I worked out back in 1990 or 1991 that fit the middle-ground exposition I complained is most absent. Specifically, I'll post (mostly without proofs) the things I brought up in this post. – Dave L. Renfro May 12 '13 at 17:19
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Dave, I am very interested! Would you please add a link here once the post is available? – Andrés E. Caicedo May 13 '13 at 19:18
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@Andres Caicedo: I'll be posting this in math StackExchange. One of the reasons I never got around to writing it up in sci.math (besides those I mentioned in the post I cited in my earlier comment) is that ASCII was so tedious and provided such limited readability for others that I just didn't feel the effort was worth it. However, the situation here is different. I've already spent a couple of hours today (early morning hours before work) beginning it, and it looks nice so far. I'll give an example in another comment, as I don't have room left in this one. – Dave L. Renfro May 13 '13 at 19:49
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ordinal tetration (base case) $;; \sideset{{}^0}{}\alpha = 1$ (successor case) $;; \sideset{{}^{\beta + 1}}{}\alpha ; = ; \left(\sideset{{}^{\beta}}{}\alpha \right)^{\alpha};$ if $\beta \geq 1$ (limit case) $;; \sideset{{}^{\lambda}}{}\alpha ; = ; \sup \left{\sideset{{}^{\beta}}{}{\alpha}: ; \beta < \lambda \right};$ if $\lambda$ is a nonzero limit ordinal Reader Exercise $;; \sideset{{}^{\epsilon_0}}{}{\epsilon_0} ; = ; {\omega}^{{\omega}^{{\omega}^{{\epsilon}_0 \cdot 2}}} $ (Not the same as usual tetration when finite ordinals are used, however.) – Dave L. Renfro May 13 '13 at 19:51
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@Andres Caicedo: This is to let you know I'm still working on the ordinal numbers stuff. Things have been extremely busy at work the past couple of weeks, but they've let up some now, so maybe in a week or two I'll be done. I'm trying to do a fairly good job, as I suspect it'll have at least as much impact as my 4 March 2002 sci.math post Graham's Number and Rapidly Growing Functions, which by the way is also part of my 1991 handwritten 63 page document that contains the ordinal stuff (and more) that I'm trying to format for here. – Dave L. Renfro May 25 '13 at 16:10
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@Andres Caicedo and Will Jagy: Andres, see this 6 February 2002 sci.math post. However, some of the things I said there are not quite correct and other things there are rather incompletely described. What I'll post here will be very detailed and carefully written, with proofs. Will, this isn't the "beyond the Borel sets" post I talked about here, but I suspect the ordinals stuff I'll post will be the longest answer in math stackexchange for now. – Dave L. Renfro May 25 '13 at 16:25
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@DaveL.Renfro: did you ever finish writing this up? I'd be very interested to read it. – Robin Saunders Oct 11 '15 at 06:04
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@Robin Saunders: I got a large part of it done, but unfortunately I learned there is a 50,000 character limit to answers and what I wrote back in 2013 was over 90,000 characters before I gave up on it. What I'd like to do is LaTeX the stuff using my Scientific Workplace software, but I don't know how to get a "preview look" of the essay to type from. What's on the Microsoft Word document I was using to write the essay is mostly unreadable due to the large number of extremely complex mathematical expressions. Print Screen doesn't seem to work when I post parts to preview at StackExchange. – Dave L. Renfro Oct 12 '15 at 14:48
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@DaveL.Renfro: if what you wrote in Word was designed to be copy-pasted into a Stack Exchange post then presumably you used $ tags to delimit the LaTeX code. Shouldn't you just be able to remove those tags and copy-paste straight into your TeX editor? Edit: alternatively, the MathJax hompage provides a free preview service, although I'm not sure what the length limits are like: https://www.mathjax.org/#modal-livedemo – Robin Saunders Oct 12 '15 at 16:12
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Update: having looked into Scientific Workplace, it sounds like you might need to first save what you wrote in Word (with the $ tags removed) as a LaTeX source file, which you should then be able to open using Scientific Workplace. – Robin Saunders Oct 12 '15 at 16:26
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@Robin Saunders: Actually, I wasn't planning on such an easy fix. For one thing, I don't have Word on my home computer, and I've run into problems trying to save it using Wordpad (stuff gets omitted or something, I forgot now). I was simply going to retype it all (2 years later, 2nd writing, I should be able to improve the exposition), but I don't know how to get a "previewed version" to print out to look at while re-typing it. If you want the Word file to see what you can do, I can send it to you. See my profile for my email address. – Dave L. Renfro Oct 12 '15 at 16:52