🔄Theory of Recursive Functions Unit 11 – Recursive Ordinals and Notations

Recursive ordinals extend ordinal numbers beyond finite and transfinite realms using recursive functions. They capture infinite iteration of ordinal operations and play a crucial role in proof theory, measuring the strength of mathematical theories. Ordinal notations symbolically represent ordinals, with Cantor normal form being the most common. These notations can be extended to recursive ordinals using various functions and hierarchies, with the Church-Kleene ordinal marking the limit of recursive ordinal notations.

Study Guides for Unit 11

11.1

Ordinals and well-orderings

9 min read

11.2

Recursive ordinals

7 min read

11.3

Church-Kleene ordinal

4 min read

11.4

Ordinal notations and recursive pseudo-well-orderings

11 min read

11.5

Relationship between recursive ordinals and hyperarithmetical hierarchy

5 min read

What are Recursive Ordinals?

Recursive ordinals extend the concept of ordinal numbers beyond the finite and transfinite realms
They are defined using recursive functions and notations, allowing for the representation of extremely large ordinals
Recursive ordinals capture the idea of "infinite iteration" of ordinal operations, such as exponentiation and the Veblen hierarchy
The class of recursive ordinals is closed under ordinal arithmetic operations and forms a proper class
Recursive ordinals play a crucial role in proof theory and the study of formal systems
- They are used to measure the strength and consistency of mathematical theories
- Recursive ordinals provide a way to compare the proof-theoretic strength of different axiomatic systems

Fundamentals of Ordinal Notation

Ordinal notations are symbolic representations used to denote specific ordinal numbers
The most common ordinal notation is the Cantor normal form, which expresses an ordinal as a sum of powers of $\omega$
Ordinal notations can be extended to represent recursive ordinals using various recursive functions and hierarchies
The Church-Kleene ordinal $\omega_1^{CK}$ is the smallest non-recursive ordinal and marks the limit of recursive ordinal notations
Fundamental sequences are used to assign notations to limit ordinals and define recursive hierarchies
- A fundamental sequence for a limit ordinal $\alpha$ is a sequence $(\alpha[n])_{n<\omega}$ of ordinals converging to $\alpha$
Recursive ordinal notations are well-founded, meaning there is no infinite descending sequence of ordinals

Cantor Normal Form

The Cantor normal form represents an ordinal $\alpha$ $α$ as a sum of powers of $\omega$ $ω$ : $\alpha = \omega^{\beta_1} \cdot k_1 + \omega^{\beta_2} \cdot k_2 + \cdots + \omega^{\beta_n} \cdot k_n$ $α = ω^{β_{1}} \cdot k_{1} + ω^{β_{2}} \cdot k_{2} + \dots + ω^{β_{n}} \cdot k_{n}$
- $\beta_1 > \beta_2 > \cdots > \beta_n$ are ordinals and $k_1, k_2, \ldots, k_n$ are positive integers
Every ordinal has a unique Cantor normal form representation
The Cantor normal form allows for the comparison and arithmetic manipulation of ordinals
Ordinal exponentiation is a key operation in the Cantor normal form
- $\omega^\alpha$ represents the $\alpha$ -th infinite cardinal number
The Cantor normal form can be extended to represent epsilon numbers $\varepsilon_\alpha$ using epsilon notation

Recursive Ordinal Arithmetic

Recursive ordinal arithmetic extends the operations of addition, multiplication, and exponentiation to recursive ordinals
Ordinal addition is defined as the concatenation of well-ordered sets
- $\alpha + \beta$ represents the ordinal obtained by appending a copy of $\beta$ after $\alpha$
Ordinal multiplication is defined as the lexicographic order on the Cartesian product of well-ordered sets
- $\alpha \cdot \beta$ represents the ordinal obtained by replacing each element of $\beta$ with a copy of $\alpha$
Ordinal exponentiation is defined recursively using the Cantor normal form and fundamental sequences
The arithmetic operations on recursive ordinals satisfy the usual properties, such as associativity and distributivity
Recursive ordinal arithmetic is used to define and manipulate large ordinal hierarchies and notations

Ordinal Hierarchies and Classification

Ordinal hierarchies are families of recursive functions used to generate and classify large ordinals
The Veblen hierarchy $\varphi_\alpha$ $φ_{α}$ is a transfinite extension of the Cantor normal form
- It is defined using a two-argument function $\varphi_\alpha(\beta)$ that enumerates the fixed points of the previous functions
The Feferman-Schütte ordinal $\Gamma_0$ is the smallest ordinal that cannot be expressed using the Veblen hierarchy
The Bachmann-Howard ordinal $\psi(\varepsilon_{\Omega+1})$ is a large countable ordinal obtained using the collapsing function $\psi$
The extended Veblen hierarchy and the Buchholz hierarchy provide notations for even larger ordinals
Ordinal hierarchies are used to measure the strength of formal theories and classify their proof-theoretic ordinals

Notations for Large Recursive Ordinals

Various notations and naming schemes are used to represent and study large recursive ordinals
The Madore naming scheme assigns names to large countable ordinals using a recursive system of abbreviations
- It extends the Veblen hierarchy and provides names for ordinals up to the Bachmann-Howard ordinal and beyond
The Takeuti-Feferman-Buchholz (TFB) ordinal notation system is based on the extended Veblen hierarchy
- It uses a ternary Veblen function $\varphi_{\alpha}(\beta,\gamma)$ to generate large ordinals
The Rathjen $\Psi$ $Ψ$ function is a powerful notation system that extends the Buchholz hierarchy
- It allows for the representation of extremely large ordinals and is used in the study of strong axiom systems
Ordinal collapsing functions, such as the $\psi$ $ψ$ function and the $\theta$ $θ$ function, are used to define large ordinal notations
- They "collapse" a given ordinal notation to a smaller one while preserving its essential properties

Applications in Proof Theory

Recursive ordinals and notations play a central role in proof theory and the study of formal systems
The proof-theoretic ordinal of a theory is the smallest recursive ordinal that cannot be proved to be well-founded within the theory
- It measures the strength and consistency of the theory
Recursive ordinals are used to establish the consistency and independence of mathematical statements
- Gentzen's consistency proof for Peano arithmetic uses transfinite induction up to the ordinal $\varepsilon_0$
Ordinal analysis is a technique that assigns recursive ordinals to theories to compare their strength
- It involves the use of ordinal notations and collapsing functions to extract ordinal information from proofs
Recursive ordinals are used in the study of fast-growing hierarchies and the classification of computable functions
Ordinal notations provide a way to define and study subrecursive hierarchies, such as the Hardy hierarchy and the Wainer hierarchy

Challenges and Open Problems

The study of recursive ordinals and notations presents several challenges and open problems
The continuum hypothesis and its relationship to recursive ordinals remain unresolved
- It is unknown whether there exist recursive ordinals between $\omega_1^{CK}$ and $\omega_1$ , the first uncountable ordinal
The exact relationship between the Church-Kleene ordinal $\omega_1^{CK}$ and the proof-theoretic ordinals of certain theories is still being investigated
Developing efficient algorithms and computational methods for working with large recursive ordinals is an ongoing challenge
Extending ordinal notations and hierarchies to even larger ordinals and exploring their properties is an active area of research
The role of recursive ordinals in the foundations of mathematics and the consistency of strong axiom systems continues to be a subject of study
- The search for a "natural" axiomatization of the recursive ordinals is an open problem