Definable set

Last updated January 04, 2023

In mathematical logic, a definable set is an n-ary relation on the domain of a structure whose elements satisfy some formula in the first-order language of that structure. A set can be defined with or without parameters, which are elements of the domain that can be referenced in the formula defining the relation.

Definition

Let ${\mathcal {L}}$ be a first-order language, ${\mathcal {M}}$ an ${\mathcal {L}}$ -structure with domain $M$ , $X$ a fixed subset of $M$ , and $m$ a natural number. Then:

A set $A\subseteq M^{m}$ is definable in ${\mathcal {M}}$ with parameters from $X$ if and only if there exists a formula $\varphi [x_{1},\ldots ,x_{m},y_{1},\ldots ,y_{n}]$ and elements $b_{1},\ldots ,b_{n}\in X$ such that for all $a_{1},\ldots ,a_{m}\in M$ ,

(a_{1},\ldots ,a_{m})\in A

if and only if

{\mathcal {M}}\models \varphi [a_{1},\ldots ,a_{m},b_{1},\ldots ,b_{n}].

The bracket notation here indicates the semantic evaluation of the free variables in the formula.

A set $A$ is definable in ${\mathcal {M}}$ without parameters if it is definable in ${\mathcal {M}}$ with parameters from the empty set (that is, with no parameters in the defining formula).
A function is definable in ${\mathcal {M}}$ (with parameters) if its graph is definable (with those parameters) in ${\mathcal {M}}$ .
An element $a$ is definable in ${\mathcal {M}}$ (with parameters) if the singleton set $\{a\}$ is definable in ${\mathcal {M}}$ (with those parameters).

Examples

The natural numbers with only the order relation

Let ${\mathcal {N}}=(\mathbb {N} ,<)$ be the structure consisting of the natural numbers with the usual ordering. Then every natural number is definable in ${\mathcal {N}}$ without parameters. The number $0$ is defined by the formula $\varphi (x)$ stating that there exist no elements less than x:

\varphi =\neg \exists y(y<x),

and a natural number $n>0$ is defined by the formula $\varphi (x)$ stating that there exist exactly $n$ elements less than x:

\varphi =\exists x_{0}\cdots \exists x_{n-1}(x_{0}<x_{1}\land \cdots \land x_{n-1}<x\land \forall y(y<x\rightarrow (y\equiv x_{0}\lor \cdots \lor y\equiv x_{n-1})))

In contrast, one cannot define any specific integer without parameters in the structure ${\mathcal {Z}}=(\mathbb {Z} ,<)$ consisting of the integers with the usual ordering (see the section on automorphisms below).

The natural numbers with their arithmetical operations

Let ${\mathcal {N}}=(\mathbb {N} ,+,\cdot ,<)$ be the first-order structure consisting of the natural numbers and their usual arithmetic operations and order relation. The sets definable in this structure are known as the arithmetical sets, and are classified in the arithmetical hierarchy. If the structure is considered in second-order logic instead of first-order logic, the definable sets of natural numbers in the resulting structure are classified in the analytical hierarchy. These hierarchies reveal many relationships between definability in this structure and computability theory, and are also of interest in descriptive set theory.

The field of real numbers

Let ${\mathcal {R}}=(\mathbb {R} ,0,1,+,\cdot )$ be the structure consisting of the field of real numbers. Although the usual ordering relation is not directly included in the structure, there is a formula that defines the set of nonnegative reals, since these are the only reals that possess square roots:

\varphi =\exists y(y\cdot y\equiv x).

Thus any $a\in \mathbb {R}$ is nonnegative if and only if ${\mathcal {R}}\models \varphi [a]$ . In conjunction with a formula that defines the additive inverse of a real number in ${\mathcal {R}}$ , one can use $\varphi$ to define the usual ordering in ${\mathcal {R}}$ : for $a,b\in \mathbb {R}$ , set $a\leq b$ if and only if $b-a$ is nonnegative. The enlarged structure ${\mathcal {R}}^{\leq }=(\mathbb {R} ,0,1,+,\cdot ,\leq )$ is called a definitional extension of the original structure. It has the same expressive power as the original structure, in the sense that a set is definable over the enlarged structure from a set of parameters if and only if it is definable over the original structure from that same set of parameters.

The theory of ${\mathcal {R}}^{\leq }$ has quantifier elimination. Thus the definable sets are Boolean combinations of solutions to polynomial equalities and inequalities; these are called semi-algebraic sets. Generalizing this property of the real line leads to the study of o-minimality.

Invariance under automorphisms

An important result about definable sets is that they are preserved under automorphisms.

Let

{\mathcal {M}}

be an

{\mathcal {L}}

-structure with domain

M

,

X\subseteq M

, and

A\subseteq M^{m}

definable in

{\mathcal {M}}

with parameters from

X

. Let

\pi :M\to M

be an automorphism of

{\mathcal {M}}

that is the identity on

X

. Then for all

a_{1},\ldots ,a_{m}\in M

,

(a_{1},\ldots ,a_{m})\in A

if and only if

(\pi (a_{1}),\ldots ,\pi (a_{m}))\in A.

This result can sometimes be used to classify the definable subsets of a given structure. For example, in the case of ${\mathcal {Z}}=(\mathbb {Z} ,<)$ above, any translation of ${\mathcal {Z}}$ is an automorphism preserving the empty set of parameters, and thus it is impossible to define any particular integer in this structure without parameters in ${\mathcal {Z}}$ . In fact, since any two integers are carried to each other by a translation and its inverse, the only sets of integers definable in ${\mathcal {Z}}$ without parameters are the empty set and $\mathbb {Z}$ itself. In contrast, there are infinitely many definable sets of pairs (or indeed n-tuples for any fixed n > 1) of elements of ${\mathcal {Z}}$ : (in the case n = 2) Boolean combinations of the sets $\{(a,b)\mid a-b=m\}$ for $m\in \mathbb {Z}$ . In particular, any automorphism (translation) preserves the "distance" between two elements.

Additional results

The Tarski–Vaught test is used to characterize the elementary substructures of a given structure.

Related Research Articles

In mathematics, an abelian group, also called a commutative group, is a group in which the result of applying the group operation to two group elements does not depend on the order in which they are written. That is, the group operation is commutative. With addition as an operation, the integers and the real numbers form abelian groups, and the concept of an abelian group may be viewed as a generalization of these examples. Abelian groups are named after early 19th century mathematician Niels Henrik Abel.

In mathematics, a finite field or Galois field is a field that contains a finite number of elements. As with any field, a finite field is a set on which the operations of multiplication, addition, subtraction and division are defined and satisfy certain basic rules. The most common examples of finite fields are given by the integers mod $p$ when $p$ is a prime number.

In abstract algebra, a group isomorphism is a function between two groups that sets up a one-to-one correspondence between the elements of the groups in a way that respects the given group operations. If there exists an isomorphism between two groups, then the groups are called isomorphic. From the standpoint of group theory, isomorphic groups have the same properties and need not be distinguished.

<span class="mw-page-title-main">Isomorphism</span> In mathematics, invertible homomorphism

In mathematics, an isomorphism is a structure-preserving mapping between two structures of the same type that can be reversed by an inverse mapping. Two mathematical structures are isomorphic if an isomorphism exists between them. The word isomorphism is derived from the Ancient Greek: ἴσοςisos "equal", and μορφήmorphe "form" or "shape".

In mathematical logic, model theory is the study of the relationship between formal theories, and their models. The aspects investigated include the number and size of models of a theory, the relationship of different models to each other, and their interaction with the formal language itself. In particular, model theorists also investigate the sets that can be defined in a model of a theory, and the relationship of such definable sets to each other. As a separate discipline, model theory goes back to Alfred Tarski, who first used the term "Theory of Models" in publication in 1954. Since the 1970s, the subject has been shaped decisively by Saharon Shelah's stability theory.

The Riesz representation theorem, sometimes called the Riesz–Fréchet representation theorem after Frigyes Riesz and Maurice René Fréchet, establishes an important connection between a Hilbert space and its continuous dual space. If the underlying field is the real numbers, the two are isometrically isomorphic; if the underlying field is the complex numbers, the two are isometrically anti-isomorphic. The (anti-) isomorphism is a particular natural isomorphism.

In mathematics, specifically in group theory, the concept of a semidirect product is a generalization of a direct product. There are two closely related concepts of semidirect product:

In mathematics, a quadric or quadric surface, is a generalization of conic sections. It is a hypersurface in a (D + 1)-dimensional space, and it is defined as the zero set of an irreducible polynomial of degree two in D + 1 variables; for example, D = 1 in the case of conic sections. When the defining polynomial is not absolutely irreducible, the zero set is generally not considered a quadric, although it is often called a degenerate quadric or a reducible quadric.

In mathematics, a linear form is a linear map from a vector space to its field of scalars.

In set theory and its applications to logic, mathematics, and computer science, set-builder notation is a mathematical notation for describing a set by enumerating its elements, or stating the properties that its members must satisfy.

<span class="mw-page-title-main">Foliation</span> In mathematics, a type of equivalence relation on an n-manifold

In mathematics, a foliation is an equivalence relation on an n-manifold, the equivalence classes being connected, injectively immersed submanifolds, all of the same dimension p, modeled on the decomposition of the real coordinate space Rⁿ into the cosets x + R^p of the standardly embedded subspace R^p. The equivalence classes are called the leaves of the foliation. If the manifold and/or the submanifolds are required to have a piecewise-linear, differentiable, or analytic structure then one defines piecewise-linear, differentiable, or analytic foliations, respectively. In the most important case of differentiable foliation of class C^r it is usually understood that r ≥ 1. The number p is called the dimension of the foliation and q = n − p is called its codimension.

In commutative algebra and field theory, the Frobenius endomorphism is a special endomorphism of commutative rings with prime characteristic $p$ , an important class which includes finite fields. The endomorphism maps every element to its $p$ -th power. In certain contexts it is an automorphism, but this is not true in general.

Independence-friendly logic is an extension of classical first-order logic (FOL) by means of slashed quantifiers of the form $and, where is a finite set of variables. The intended reading of is "there is a which is functionally independent from the variables in ". IF logic allows one to express more general patterns of dependence between variables than those which are implicit in first-order logic. This greater level of generality leads to an actual increase in expressive power; the set of IF sentences can characterize the same classes of structures as existential second-order logic.$

In mathematics, the resultant of two polynomials is a polynomial expression of their coefficients, which is equal to zero if and only if the polynomials have a common root, or, equivalently, a common factor. In some older texts, the resultant is also called the eliminant.

In model theory and related areas of mathematics, a type is an object that describes how a element or finite collection of elements in a mathematical structure might behave. More precisely, it is a set of first-order formulas in a language L with free variables x₁, x₂,…, x_n that are true of a sequence of elements of an L-structure $. Depending on the context, types can be complete or partial and they may use a fixed set of constants, A, from the structure . The question of which types represent actual elements of leads to the ideas of saturated models and omitting types .$

In universal algebra and in model theory, a structure consists of a set along with a collection of finitary operations and relations that are defined on it.

In mathematics, a Witt vector is an infinite sequence of elements of a commutative ring. Ernst Witt showed how to put a ring structure on the set of Witt vectors, in such a way that the ring of Witt vectors $over the finite field of order is the ring of -adic integers . They have a highly non-intuitive structure upon first glance because their additive and multiplicative structure depends on an infinite set of recursive formulas which do not behave like addition and multiplication formulas for standard p-adic integers. The main idea behind Witt vectors is instead of using the standard -adic expansion$

<span class="mw-page-title-main">Classical group</span>

In mathematics, the classical groups are defined as the special linear groups over the reals $R$ , the complex numbers $C$ and the quaternions $H$ together with special automorphism groups of symmetric or skew-symmetric bilinear forms and Hermitian or skew-Hermitian sesquilinear forms defined on real, complex and quaternionic finite-dimensional vector spaces. Of these, the complex classical Lie groups are four infinite families of Lie groups that together with the exceptional groups exhaust the classification of simple Lie groups. The compact classical groups are compact real forms of the complex classical groups. The finite analogues of the classical groups are the classical groups of Lie type. The term "classical group" was coined by Hermann Weyl, it being the title of his 1939 monograph The Classical Groups.

In discrete mathematics, ideal lattices are a special class of lattices and a generalization of cyclic lattices. Ideal lattices naturally occur in many parts of number theory, but also in other areas. In particular, they have a significant place in cryptography. Micciancio defined a generalization of cyclic lattices as ideal lattices. They can be used in cryptosystems to decrease by a square root the number of parameters necessary to describe a lattice, making them more efficient. Ideal lattices are a new concept, but similar lattice classes have been used for a long time. For example, cyclic lattices, a special case of ideal lattices, are used in NTRUEncrypt and NTRUSign.

In mathematics, and especially algebraic geometry, a Bridgeland stability condition, defined by Tom Bridgeland, is an algebro-geometric stability condition defined on elements of a triangulated category. The case of original interest and particular importance is when this derived category is the derived category of coherent sheaves on a Calabi–Yau manifold, and this situation has fundamental links to string theory and the study of D-branes.

References

Hinman, Peter. Fundamentals of Mathematical Logic, A K Peters, 2005.
Marker, David. Model Theory: An Introduction, Springer, 2002.
Rudin, Walter. Principles of Mathematical Analysis, 3rd. ed. McGraw-Hill, 1976.
Slaman, Theodore A. and Woodin, W. Hugh. Mathematical Logic: The Berkeley Undergraduate Course. Spring 2006.

This page is based on this Wikipedia article
Text is available under the CC BY-SA 4.0 license; additional terms may apply.
Images, videos and audio are available under their respective licenses.