Non-standard model of arithmetic
This article needs additional citations for verification. (July 2012) |
In
Non-standard models of arithmetic exist only for the first-order formulation of the
Existence
There are several methods that can be used to prove the existence of non-standard models of arithmetic.
From the compactness theorem
The existence of non-standard models of arithmetic can be demonstrated by an application of the compactness theorem. To do this, a set of axioms P* is defined in a language including the language of Peano arithmetic together with a new constant symbol x. The axioms consist of the axioms of Peano arithmetic P together with another infinite set of axioms: for each numeral[clarify] n, the axiom x > n is included. Any finite subset of these axioms is satisfied by a model that is the standard model of arithmetic plus the constant x interpreted as some number larger than any numeral mentioned in the finite subset of P*. Thus by the compactness theorem there is a model satisfying all the axioms P*. Since any model of P* is a model of P (since a model of a set of axioms is obviously also a model of any subset of that set of axioms), we have that our extended model is also a model of the Peano axioms. The element of this model corresponding to x cannot be a standard number, because as indicated it is larger than any standard number.
Using more complex methods, it is possible to build non-standard models that possess more complicated properties. For example, there are models of Peano arithmetic in which Goodstein's theorem fails. It can be proved in Zermelo–Fraenkel set theory that Goodstein's theorem holds in the standard model, so a model where Goodstein's theorem fails must be non-standard.
From the incompleteness theorems
Gödel's incompleteness theorems also imply the existence of non-standard models of arithmetic. The incompleteness theorems show that a particular sentence G, the Gödel sentence of Peano arithmetic, is neither provable nor disprovable in Peano arithmetic. By the completeness theorem, this means that G is false in some model of Peano arithmetic. However, G is true in the standard model of arithmetic, and therefore any model in which G is false must be a non-standard model. Thus satisfying ~G is a sufficient condition for a model to be nonstandard. It is not a necessary condition, however; for any Gödel sentence G and any infinite cardinality there is a model of arithmetic with G true and of that cardinality.
Arithmetic unsoundness for models with ~G true
Assuming that arithmetic is consistent, arithmetic with ~G is also consistent. However, since ~G states that arithmetic is inconsistent, the result will not be
From an ultraproduct
Another method for constructing a non-standard model of arithmetic is via an ultraproduct. A typical construction uses the set of all sequences of natural numbers, . Choose an ultrafilter on , then identify two sequences whenever they have equal values on positions that form a member of the ultrafilter (this requires that they agree on infinitely many terms, but the condition is stronger than this as ultrafilters resemble axiom-of-choice-like maximal extensions of the Fréchet filter). The resulting
Structure of countable non-standard models
The ultraproduct models are uncountable. One way to see this is to construct an injection of the infinite product of N into the ultraproduct. However, by the Löwenheim–Skolem theorem there must exist countable non-standard models of arithmetic. One way to define such a model is to use Henkin semantics.
Any
So, the order type of the countable non-standard models is known. However, the arithmetical operations are much more complicated.
It is easy to see that the arithmetical structure differs from ω + (ω* + ω) ⋅ η. For instance if a nonstandard (non-finite) element u is in the model, then so is m ⋅ u for any m in the initial segment N, yet u2 is larger than m ⋅ u for any standard finite m.
Also one can define "square roots" such as the least v such that v2 > 2 ⋅ u. These cannot be within a standard finite number of any rational multiple of u. By analogous methods to
This shows that the arithmetical structure of a countable non-standard model is more complex than the structure of the rationals. There is more to it than that though:
References
Citations
- ISSN 1431-4657. Here: Ch. VI.3
- ISBN 978-1-4612-6841-3
- ^ Andrey Bovykin and Richard Kaye Order-types of models of Peano arithmetic: a short survey June 14, 2001
- ^ Andrey Bovykin On order-types of models of arithmetic thesis submitted to the University of Birmingham for the degree of Ph.D. in the Faculty of Science 13 April 2000
- ^ Fred Landman LINEAR ORDERS, DISCRETE, DENSE, AND CONTINUOUS – includes proof that Q is the only countable dense linear order.
Sources
- ISBN 0-521-38923-2.
- Skolem, Thoralf (1934). "Über die Nicht-charakterisierbarkeit der Zahlenreihe mittels endlich oder abzählbar unendlich vieler Aussagen mit ausschließlich Zahlenvariablen" (PDF). .
See also
- Non-Euclidean geometry — about non-standard models in geometry