Function space explained

In mathematics, a function space is a set of functions between two fixed sets. Often, the domain and/or codomain will have additional structure which is inherited by the function space. For example, the set of functions from any set into a vector space has a natural vector space structure given by pointwise addition and scalar multiplication. In other scenarios, the function space might inherit a topological or metric structure, hence the name function space.

In linear algebra

Let be a field and let be any set. The functions → can be given the structure of a vector space over where the operations are defined pointwise, that is, for any, : →, any in, and any in, define\begin (f+g)(x) &= f(x)+g(x) \\ (c\cdot f)(x) &= c\cdot f(x)\endWhen the domain has additional structure, one might consider instead the subset (or subspace) of all such functions which respect that structure. For example, if and also itself are vector spaces over, the set of linear maps → form a vector space over with pointwise operations (often denoted Hom). One such space is the dual space of : the set of linear functionals → with addition and scalar multiplication defined pointwise.

The cardinal dimension of a function space with no extra structure can be found by the Erdős–Kaplansky theorem.

Examples

Function spaces appear in various areas of mathematics:

X\leftrightarrowY

. The factorial notation X! may be used for permutations of a single set X.

Functional analysis

Functional analysis is organized around adequate techniques to bring function spaces as topological vector spaces within reach of the ideas that would apply to normed spaces of finite dimension. Here we use the real line as an example domain, but the spaces below exist on suitable open subsets

\Omega\subseteq\Rn

C(\R)

continuous functions endowed with the uniform norm topology

Cc(\R)

continuous functions with compact support

B(\R)

bounded functions

C0(\R)

continuous functions which vanish at infinity

Cr(\R)

continuous functions that have continuous first r derivatives.

Cinfty(\R)

smooth functions
infty
C
c(\R)
smooth functions with compact support

C\omega(\R)

real analytic functions

Lp(\R)

, for

1\leqp\leqinfty

, is the Lp space of measurable functions whose p-norm \|f\|_p = \left(\int_\R |f|^p \right)^ is finite

l{S}(\R)

, the Schwartz space of rapidly decreasing smooth functions and its continuous dual,

l{S}'(\R)

tempered distributions

D(\R)

compact support in limit topology

Wk,p

Sobolev space of functions whose weak derivatives up to order k are in

Lp

l{O}U

holomorphic functions

Lip0(\R)

, the space of all Lipschitz functions on

\R

that vanish at zero.

Norm

If is an element of the function space

l{C}(a,b)

of all continuous functions that are defined on a closed interval, the norm

\|y\|infty

defined on

l{C}(a,b)

is the maximum absolute value of for,[2] \| y \|_\infty \equiv \max_ |y(x)| \qquad \text \ \ y \in \mathcal (a,b)

is called the uniform norm or supremum norm ('sup norm').

Bibliography

See also

Notes and References

  1. Book: Representation Theory: A First Course. Fulton. William. Harris. Joe. 1991. Springer Science & Business Media. 9780387974958. en. 4.
  2. Book: Gelfand . I. M. . Israel Gelfand . Fomin . S. V. . Sergei Fomin . Calculus of variations . 2000 . 6 . Dover Publications . Mineola, New York . 978-0486414485 . Unabridged repr. . Silverman . Richard A..