Schauder basis

Schauder basis

In mathematics, a Schauder basis or countable basis is similar to the usual (Hamel) basis of a vector space; the difference is that Hamel bases use linear combinations that are finite sums, while for Schauder bases they may be infinite sums. This makes Schauder bases more suitable for the analysis of infinite-dimensional topological vector spaces including Banach spaces.

Schauder bases were described by Juliusz Schauder in 1927,[1][2] although such bases were discussed earlier. For example, the Haar basis was given in 1909, and Faber (1910) discussed a basis for continuous functions on an interval, sometimes called a Faber–Schauder system.

Contents

Definition

Let V denote a Banach space over the field F. A Schauder basis is a sequence (bn) of elements of V such that for every element vV there exists a unique sequence (αn) of elements in F so that

 v = \sum_{n \in \N} \alpha_n b_n \,

where the convergence is understood with respect to the norm topology. Schauder bases can also be defined analogously in a general topological vector space.

As opposed to a Hamel basis, the elements of the basis must be ordered since the series may not converge unconditionally.

Examples and properties

The standard bases of c0 and lp for 1 ≤ p < ∞ are Schauder bases.

Every orthonormal basis in a separable Hilbert space is a Schauder basis.

The Haar system is an example of a basis for Lp(0, 1) with 1 ≤ p < ∞. Another example is the trigonometric system defined below.

The Banach space C([0, 1]) of continuous functions on the interval [0, 1], with the supremum norm, admits a Schauder basis.

A Banach space with a Schauder basis is necessarily separable, but the converse is false, as described below. Every Banach space with a Schauder basis has the approximation property.

Basis problem

A theorem of Mazur asserts that every infinite-dimensional Banach space has an infinite-dimensional subspace that has a Schauder basis. A question of Banach asked whether every separable Banach space has a Schauder basis; this was negatively answered by Per Enflo who constructed a separable Banach space without a Schauder basis.[3]

Relation to Fourier series

Let (xn) be the sequence (in the real case)

 \{ 1, \cos x, \sin x, \cos(2x), \sin(2x), \cos(3x), \sin(3x), \ldots \} \,

or (in the complex case)

 \{ 1, e^{ix}, e^{-ix}, e^{2ix}, e^{-2ix}, e^{3ix}, e^{-3ix}, \ldots \} .

The sequence (xn) (called the trigonometric system) is a Schauder basis for the space Lp[0, 2π] for any p > 1. For p = 2, this is the content of the Riesz–Fischer theorem. However, the set (xn) is not a Schauder basis for L1[0, 2π]. This means that there are functions in L1 whose Fourier series does not converge in the L1 norm.

Unconditionality

A Schauder basis (bn) is unconditional if whenever the series  \sum \alpha_nb_n converges, it converges unconditionally. Unconditionality is an important property since it allows us to forget about the order of summation.

The standard bases of the sequence spaces c0 and lp for 1 ≤ p < ∞, as well as every orthonormal basis in a Hilbert space, are unconditional.

The trigonometric system is not an unconditional basis in Lp, except for p = 2.

The Haar system is a unconditional basis in Lp for any 1 < p < ∞. Actually, the space L1 has no unconditional basis.

A natural question is whether every infinite-dimensional Banach space has a infinite-dimensional subspace with an unconditional basis. This was solved negatively by Timothy Gowers and Bernard Maurey in 1992.

Related concepts

A Hamel basis is a subset B of a vector space V such that every element v ∈ V can uniquely be written as

 v = \sum_{b \in B} \alpha_b b \,

with αbF, with the extra condition that the set

 \{ b \in B \mid \alpha_b \neq 0 \} \,

is finite. This property makes the Hamel basis unwieldy for infinite-dimensional Banach spaces; as a Hamel basis for an infinite-dimensional Banach space would be uncountable. (Every finite dimensional subspace of an infinite-dimensional Banach space X has empty interior, and is no-where dense in X. It then follows from the Baire category theorem that the a countable union of these finite-dimensional subspaces cannot serve as a basis[4].)

A family of vectors is total if its linear span (the set of finite linear combinations) is dense in V. Every complete set of vectors is total, but the converse need not hold in an infinite-dimensional space.

If V is an inner product space, an orthogonal basis is a subset B such that its linear span is dense in V and elements in the basis are pairwise orthogonal.

See also

Notes

This article incorporates material from Countable basis on PlanetMath, which is licensed under the Creative Commons Attribution/Share-Alike License.

  1. ^ J. Schauder, "Zur Theorie stetiger Abbildungen in Funktionalraumen", Mathematische Zeitschrift 26 (1927) pp. 47–65.
  2. ^ J. Schauder, "Eine Eigenschaft des Haarschen Orthogonalsystems, Mathematische Zeitschrift, 28 (1928) pp. 317–320.
  3. ^ Enflo, Per (July 1973). "A counterexample to the approximation problem in Banach spaces". Acta Mathematica 130 (1): 309–317. doi:10.1007/BF02392270. 
  4. ^ N.L. Carothers, A short course on Banach space theory (2005), Cambridge University Press ISBN 0-521-60372-2

References


Wikimedia Foundation. 2010.

Игры ⚽ Нужен реферат?

Look at other dictionaries:

  • Schauder-Basis — In der Funktionalanalysis wird eine abzählbare Menge {bn} eines Banachraums, deren lineare Hülle dicht im ganzen Raum ist, als Schauderbasis bezeichnet, falls jeder Vektor bezüglich ihr eine eindeutige Darstellung als (unendliche)… …   Deutsch Wikipedia

  • Basis — may refer to* Basis future, the value differential between a future and the spot price * Basis (options), the value differential between a call option and a put option * Cost basis, in the calculation of capital gains * Basis (crystal structure) …   Wikipedia

  • Basis function — In mathematics, particularly numerical analysis, a basis function is an element of the basis for a function space. The term is a degeneration of the term basis vector for a more general vector space; that is, each function in the function space… …   Wikipedia

  • Basis (linear algebra) — Basis vector redirects here. For basis vector in the context of crystals, see crystal structure. For a more general concept in physics, see frame of reference. In linear algebra, a basis is a set of linearly independent vectors that, in a linear… …   Wikipedia

  • Base de Schauder — La notion de base de Schauder est une généralisation de celle de base (algébrique). La différence vient du fait que dans une base algébrique on considère des combinaisons linéaires finies d éléments, alors que pour des bases de Schauder elles… …   Wikipédia en Français

  • Orthonormal basis — In mathematics, particularly linear algebra, an orthonormal basis for inner product space V with finite dimension is a basis for V whose vectors are orthonormal.[1][2][3] For example, the standard basis for a Euclidean space Rn is an orthonormal… …   Wikipedia

  • Juliusz Schauder — Juliusz Paweł Schauder (1899 1943) was a Polish mathematician of Jewish origin, known for his work in functional analysis, partial differential equation and mathematical physics.Born on September 21 1899 in Lwów, he had to fight in World War I… …   Wikipedia

  • Per Enflo — Born 1944 Stockholm, Sweden …   Wikipedia

  • List of mathematics articles (S) — NOTOC S S duality S matrix S plane S transform S unit S.O.S. Mathematics SA subgroup Saccheri quadrilateral Sacks spiral Sacred geometry Saddle node bifurcation Saddle point Saddle surface Sadleirian Professor of Pure Mathematics Safe prime Safe… …   Wikipedia

  • Approximation theory — In mathematics, approximation theory is concerned with how functions can best be approximated with simpler functions, and with quantitatively characterizing the errors introduced thereby. Note that what is meant by best and simpler will depend on …   Wikipedia

Share the article and excerpts

Direct link
Do a right-click on the link above
and select “Copy Link”