- Canonical form
-
Generally, in mathematics, a canonical form (often called normal form or standard form) of an object is a standard way of presenting that object.
Canonical form can also mean a differential form that is defined in a natural (canonical) way; see below.
Finding a canonical form is called canonization. In some branches of computer science the term canonicalization is adopted.
Contents
Definition
Suppose we have some set S of objects, with an equivalence relation. A canonical form is given by designating some objects of S to be "in canonical form", such that every object under consideration is equivalent to exactly one object in canonical form. In other words, the canonical forms in S represent the equivalence classes, once and only once. To test whether two objects are equivalent, it then suffices to test their canonical forms for equality. A canonical form thus provides a classification theorem and more, in that it not just classifies every class, but gives a distinguished (canonical) representative.
In practical terms, one wants to be able to recognize the canonical forms. There is also a practical, algorithmic question to consider: how to pass from a given object s in S to its canonical form s*? Canonical forms are generally used to make operating with equivalence classes more effective. For example in modular arithmetic, the canonical form for a residue class is usually taken as the least non-negative integer in it. Operations on classes are carried out by combining these representatives and then reducing the result to its least non-negative residue. The uniqueness requirement is sometimes relaxed, allowing the forms to be unique up to some finer equivalence relation, like allowing reordering of terms (if there is no natural ordering on terms).
A canonical form may simply be a convention, or a deep theorem.
For example, polynomials are conventionally written with the terms in descending powers: it is more usual to write x2 + x + 30 than x + 30 + x2, although the two forms define the same polynomial. By contrast, the existence of Jordan canonical form for a matrix is a deep theorem.
Examples
Note: in this section, "up to" some equivalence relation E means that the canonical form is not unique in general, but that if one object has two different canonical forms, they are E-equivalent.
Linear algebra
Objects A is equivalent to B if: Normal form Notes Normal matrices over the complex numbers A = U * BU for some unitary matrix U Diagonal matrices (up to reordering) This is the Spectral theorem Matrices over the complex numbers A = UBV * for some unitary matrices U and V Diagonal matrices with real positive entries (in descending order) Singular value decomposition Matrices over an algebraically closed field A = P − 1BP for some invertible matrix P Jordan normal form (up to reordering of blocks) Matrices over a field A = P − 1BP for some invertible matrix P Frobenius normal form Matrices over a principal ideal domain A = P − 1BQ for some invertible Matrices P and Q Smith normal form The equivalence is the same as allowing invertible elementary row and column transformations Finite-dimensional vector spaces over a field K A and B are isomorphic as vector spaces Kn, n a non-negative integer Classical logic
- Negation normal form
- Conjunctive normal form
- Disjunctive normal form
- Algebraic normal form
- Canonical form (Boolean algebra)
- Prenex normal form
- Skolem normal form
Functional analysis
Objects A is equivalent to B if: Normal form Hilbert spaces A and B are isometrically isomorphic as Hilbert spaces 
sequence spaces (up to exchanging the index set I with another index set of the same cardinality)Commutative C * -algebras with unit A and B are isomorphic as C * -algebras The algebra C(X) of continuous functions on a compact Hausdorff space, up to homeomorphism of the base space. Algebra
Objects A is equivalent to B if: Normal form Finitely generated R-modules with R a principal ideal domain A and B are isomorphic as R-modules Primary decomposition (up to reordering) or invariant factor decomposition Geometry
- The equation of a line: Ax + By = C
- C = 0 or C = 1
- The equation of a circle:
By contrast, there are alternative forms for writing equations. For example, the equation of a line may be written as a linear equation in point-slope and slope-intercept form.
Mathematical notation
Standard form is used by many mathematicians and scientists to write extremely large numbers in a more concise and understandable way.
Set theory
- Cantor normal form of an ordinal number
Game theory
- Normal form game
Proof theory
Rewriting systems
- In an abstract rewriting system a normal form is an irreducible object.
Lambda calculus
- Beta normal form if no beta reduction is possible; Lambda calculus is a particular case of an abstract rewriting system.
Dynamical systems
- Normal form of a bifurcation
Graph theory
Main article: Graph canonizationDifferential forms
Canonical differential forms include the canonical one-form and canonical symplectic form, important in the study of Hamiltonian mechanics and symplectic manifolds.
See also
- Canonical class
- Normalization
- Standardization
References
- Shilov, Georgi E. (1977), Silverman, Richard A., ed., Linear Algebra, Dover, ISBN 0-486-63518-X.
Wikimedia Foundation. 2010.
