Difference between revisions of "Orthogonalization of a system of functions"
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| − | The construction, for a given system of functions | + | {{TEX|done}} |
| + | The construction, for a given system of functions $\{f_n\}$ which are square integrable on the segment $[a,b]$, of an orthogonal system of functions $\{\phi_n\}$ by using a process of [[Orthogonalization|orthogonalization]] or by extending the functions $f_n$ to a larger interval $[c,d]$, $c<a<b<d$. | ||
| − | The use of the Schmidt orthogonalization process for a [[Complete system of functions|complete system of functions]] | + | The use of the Schmidt orthogonalization process for a [[Complete system of functions|complete system of functions]] $\{f_n\}$ always reduces it to a complete [[Orthonormal system|orthonormal system]] $\{\phi_n\}$, and given a corresponding choice of the sequence $\{f_n\}$, permits the construction of a system which possesses some good properties. In this way, for example, the Franklin system (see [[Orthogonal series|Orthogonal series]]) is created, which is a basis in $C[0,1]$ and in $L_p[0,1]$, $p\geq1$. |
| − | Orthogonalization of a system of functions by extension to a larger interval was first introduced by I. Schur (see [[#References|[1]]]). He proved that for the existence of a system | + | Orthogonalization of a system of functions by extension to a larger interval was first introduced by I. Schur (see [[#References|[1]]]). He proved that for the existence of a system $\{\phi_n\}$, $\phi_n(x)=f_n(x)$, $x\in[a,b]$, $0<a<b<1$, orthonormal in $L_2[0,1]$, it is necessary and sufficient that the condition |
| − | + | $$\sup\int\limits_a^b\left[\sum\xi_if_i(x)\right]^2dx=1$$ | |
| − | be fulfilled, where the supremum is taken over all | + | be fulfilled, where the supremum is taken over all $\{\xi_i\}$ with $\sum\xi_i^2=1$. Necessary and sufficient conditions have also been found such that, when these are fulfilled, one can obtain a complete orthonormal system $\{\phi_n\}$ by means of such an orthogonalization (see [[#References|[2]]]). |
| − | A number of constructions of orthogonalization by extension of functions are given by D.E. Men'shov [[#References|[3]]]. They are used to prove theorems on the accuracy of the condition < | + | A number of constructions of orthogonalization by extension of functions are given by D.E. Men'shov [[#References|[3]]]. They are used to prove theorems on the accuracy of the condition $\sum a_n^2\ln^2n<\infty$ for the almost-everywhere convergence of an orthogonal series $\sum a_n\phi_n(x)$. |
====References==== | ====References==== | ||
Latest revision as of 11:37, 10 August 2014
The construction, for a given system of functions $\{f_n\}$ which are square integrable on the segment $[a,b]$, of an orthogonal system of functions $\{\phi_n\}$ by using a process of orthogonalization or by extending the functions $f_n$ to a larger interval $[c,d]$, $c<a<b<d$.
The use of the Schmidt orthogonalization process for a complete system of functions $\{f_n\}$ always reduces it to a complete orthonormal system $\{\phi_n\}$, and given a corresponding choice of the sequence $\{f_n\}$, permits the construction of a system which possesses some good properties. In this way, for example, the Franklin system (see Orthogonal series) is created, which is a basis in $C[0,1]$ and in $L_p[0,1]$, $p\geq1$.
Orthogonalization of a system of functions by extension to a larger interval was first introduced by I. Schur (see [1]). He proved that for the existence of a system $\{\phi_n\}$, $\phi_n(x)=f_n(x)$, $x\in[a,b]$, $0<a<b<1$, orthonormal in $L_2[0,1]$, it is necessary and sufficient that the condition
$$\sup\int\limits_a^b\left[\sum\xi_if_i(x)\right]^2dx=1$$
be fulfilled, where the supremum is taken over all $\{\xi_i\}$ with $\sum\xi_i^2=1$. Necessary and sufficient conditions have also been found such that, when these are fulfilled, one can obtain a complete orthonormal system $\{\phi_n\}$ by means of such an orthogonalization (see [2]).
A number of constructions of orthogonalization by extension of functions are given by D.E. Men'shov [3]. They are used to prove theorems on the accuracy of the condition $\sum a_n^2\ln^2n<\infty$ for the almost-everywhere convergence of an orthogonal series $\sum a_n\phi_n(x)$.
References
| [1] | S. Kaczmarz, H. Steinhaus, "Theorie der Orthogonalreihen" , Chelsea, reprint (1951) |
| [2] | A.M. Olevskii, "On the extension of a sequence of functions to a complete orthonormal system" Math. Notes , 6 : 6 (1969) pp. 908–913 Mat. Zametki , 6 : 6 (1969) pp. 737–747 |
| [3] | D.E. Men'shov, "Sur les séries des fonctions orthogonales bornees dans leur ensemble" Mat. Sb. , 3 (1938) pp. 103–120 |
| [4] | Ph. Franklin, "A set of continuous orthogonal functions" Math. Ann. , 100 (1928) pp. 522–529 |
Comments
The Schmidt orthogonalization process is often called the Gram–Schmidt orthogonalization process.
How to Cite This Entry:
Orthogonalization of a system of functions. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=Orthogonalization_of_a_system_of_functions&oldid=15583
Orthogonalization of a system of functions. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=Orthogonalization_of_a_system_of_functions&oldid=15583
This article was adapted from an original article by A.A. Talalyan (originator), which appeared in Encyclopedia of Mathematics - ISBN 1402006098. See original article