Induction, bounding and least number principles

In first-order arithmetic, the induction principles, bounding principles, and least number principles are three related families of first-order principles, which may or may not hold in nonstandard models of arithmetic. These principles are often used in reverse mathematics to calibrate the axiomatic strength of theorems.

Definitions[edit]

Informally, for a first-order formula of arithmetic $\varphi (x)$ with one free variable, the induction principle for $\varphi$ expresses the validity of mathematical induction over $\varphi$ , while the least number principle for $\varphi$ asserts that if $\varphi$ has a witness, it has a least one. For a formula $\psi (x,y)$ in two free variables, the bounding principle for $\psi$ states that, for a fixed bound $k$ , if for every $n<k$ there is $m_{n}$ such that $\psi (n,m_{n})$ , then we can find a bound on the $m_{n}$ 's.

Formally, the induction principle for $\varphi$ is the sentence:^[1]

{\mathsf {I}}\varphi :\quad {\big [}\varphi (0)\land \forall x{\big (}\varphi (x)\to \varphi (x+1){\big )}{\big ]}\to \forall x\ \varphi (x)

There is a similar strong induction principle for $\varphi$ :^[1]

{\mathsf {I}}'\varphi :\quad \forall x{\big [}{\big (}\forall y<x\ \ \varphi (y){\big )}\to \varphi (x){\big ]}\to \forall x\ \varphi (x)

The least number principle for $\varphi$ is the sentence:^[1]

{\mathsf {L}}\varphi :\quad \exists x\ \varphi (x)\to \exists x'{\big (}\varphi (x')\land \forall y<x'\ \,\lnot \varphi (y){\big )}

Finally, the bounding principle for $\psi$ is the sentence:^[1]

{\mathsf {B}}\psi :\quad \forall u{\big [}{\big (}\forall x<u\ \,\exists y\ \,\psi (x,y){\big )}\to \exists v\ \,\forall x<u\ \,\exists y<v\ \,\psi (x,y){\big ]}

More commonly, we consider these principles not just for a single formula, but for a class of formulae in the arithmetical hierarchy. For example, ${\mathsf {I}}\Sigma _{2}$ is the axiom schema consisting of ${\mathsf {I}}\varphi$ for every $\Sigma _{2}$ formula $\varphi (x)$ in one free variable.

Nonstandard models[edit]

It may seem that the principles ${\mathsf {I}}\varphi$ , ${\mathsf {I}}'\varphi$ , ${\mathsf {L}}\varphi$ , ${\mathsf {B}}\psi$ are trivial, and indeed, they hold for all formulae $\varphi$ , $\psi$ in the standard model of arithmetic $\mathbb {N}$ . However, they become more relevant in nonstandard models. Recall that a nonstandard model of arithmetic has the form $\mathbb {N} +\mathbb {Z} \cdot K$ for some linear order $K$ . In other words, it consists of an initial copy of $\mathbb {N}$ , whose elements are called finite or standard, followed by many copies of $\mathbb {Z}$ arranged in the shape of $K$ , whose elements are called infinite or nonstandard.

Now, considering the principles ${\mathsf {I}}\varphi$ , ${\mathsf {I}}'\varphi$ , ${\mathsf {L}}\varphi$ , ${\mathsf {B}}\psi$ in a nonstandard model ${\mathcal {M}}$ , we can see how they might fail. For example, the hypothesis of the induction principle ${\mathsf {I}}\varphi$ only ensures that $\varphi (x)$ holds for all elements in the standard part of ${\mathcal {M}}$ - it may not hold for the nonstandard elements, who can't be reached by iterating the successor operation from zero. Similarly, the bounding principle ${\mathsf {B}}\psi$ might fail if the bound $u$ is nonstandard, as then the (infinite) collection of $y$ could be cofinal in ${\mathcal {M}}$ .

Relations between the principles[edit]

The following relations hold between the principles (over the weak base theory ${\mathsf {PA}}^{-}+{\mathsf {I}}\Sigma _{0}$ ):^[1]^[2]

${\mathsf {I}}'\varphi \equiv {\mathsf {L}}\lnot \varphi$ for every formula $\varphi$ ;
${\mathsf {I}}\Sigma _{n}\equiv {\mathsf {I}}\Pi _{n}\equiv {\mathsf {I}}'\Sigma _{n}\equiv {\mathsf {I}}'\Pi _{n}\equiv {\mathsf {L}}\Sigma _{n}\equiv {\mathsf {L}}\Pi _{n}$ ;
${\mathsf {I}}\Sigma _{n+1}\implies {\mathsf {B}}\Sigma _{n+1}\implies {\mathsf {I}}\Sigma _{n}$ , and both implications are strict;
${\mathsf {B}}\Sigma _{n+1}\equiv {\mathsf {B}}\Pi _{n}\equiv {\mathsf {L}}\Delta _{n+1}$ ;
${\mathsf {L}}\Delta _{n}\implies {\mathsf {I}}\Delta _{n}$ , but it is not known if this reverses.

Over ${\mathsf {PA}}^{-}+{\mathsf {I}}\Sigma _{0}+{\mathsf {exp}}$ , Slaman proved that ${\mathsf {B}}\Sigma _{n}\equiv {\mathsf {L}}\Delta _{n}\equiv {\mathsf {I}}\Delta _{n}$ .^[3]

Reverse mathematics[edit]

The induction, bounding and least number principles are commonly used in reverse mathematics and second-order arithmetic. For example, ${\mathsf {I}}\Sigma _{1}$ is part of the definition of the subsystem ${\mathsf {RCA}}_{0}$ of second-order arithmetic. Hence, ${\mathsf {I}}'\Sigma _{1}$ , ${\mathsf {L}}\Sigma _{1}$ and ${\mathsf {B}}\Sigma _{1}$ are all theorems of ${\mathsf {RCA}}_{0}$ . The subsystem ${\mathsf {ACA}}_{0}$ proves all the principles ${\mathsf {I}}\varphi$ , ${\mathsf {I}}'\varphi$ , ${\mathsf {L}}\varphi$ , ${\mathsf {B}}\psi$ for arithmetical $\varphi$ , $\psi$ . The infinite pigeonhole principle is known to be equivalent to ${\mathsf {B}}\Pi _{1}$ and ${\mathsf {B}}\Sigma _{2}$ over ${\mathsf {RCA}}_{0}$ .^[4]