Polynomial of best approximation
A polynomial furnishing the best approximation of a function 
in some metric, relative to all polynomials constructed from a given (finite) system of functions. If 
is a normed linear function space (such as 
or 
, 
), and if
 |
is a system of linearly independent functions in 
, then for any 
the (generalized) polynomial of best approximation
 | (*) |
defined by the relation
 |
exists. The polynomial of best approximation is unique for all 
if 
is a space with a strictly convex norm (i.e. if 
and 
, then 
). This is the case for 
, 
. In 
, which has a norm that is not strictly convex, the polynomial of best approximation for any 
is unique if 
is a Chebyshev system on 
, i.e. if each polynomial
 |
has at most 
zeros on 
. In particular, one has uniqueness in the case of the (usual) algebraic polynomials in 
, and also for the trigonometric polynomials in the space 
of continuous 
-periodic functions on the real line, with the uniform metric. If the polynomial of best approximation exists and is unique for any 
, it is a continuous function of 
.
Necessary and sufficient conditions for a polynomial to be a best approximation in the spaces 
and 
are known. For example, one has Chebyshev's theorem: If 
is a Chebyshev system, then the polynomial (*) is a polynomial of best approximation for a function 
in the metric of 
if and only if there exists a system of 
points 
, 
, at which the difference
 |
assumes values
 |
and, moreover,
 |
The polynomial (*) is a polynomial of best approximation for a function 
, 
, in the metric of that space, if and only if for 
,
 |
In 
, the conditions
 |
are sufficient for 
to be a polynomial of best approximation for 
, and if the measure of the set of all points 
at which 
is zero, they are also necessary; see also Markov criterion.
There exist algorithms for the approximate construction of polynomials of best uniform approximation (see e.g. [3], [5]).
References
| [1] | N.I. [N.I. Akhiezer] Achiezer, "Theory of approximation" , F. Ungar (1956) (Translated from Russian) |
| [2] | N.P. Korneichuk, "Extremal problems in approximation theory" , Moscow (1976) (In Russian) |
| [3] | V.K. Dzyadyk, "Introduction to the theory of uniform approximation of functions by polynomials" , Moscow (1977) (In Russian) |
| [4] | V.M. Tikhomirov, "Some problems in approximation theory" , Moscow (1976) (In Russian) |
| [5] | P.J. Laurent, "Approximation et optimisation" , Hermann (1972) |
| [6] | E.Ya. Remez, "Foundations of numerical methods of Chebyshev approximation" , Kiev (1969) (In Russian) |
Comments
References
| [a1] | A.M. Pinkus, "On  -approximation" , Cambridge Univ. Press (1989) |
| [a2] | A. Schönhage, "Approximationstheorie" , de Gruyter (1971) |
| [a3] | G.A. Watson, "Approximation theory and numerical methods" , Wiley (1980) |
| [a4] | E.W. Cheney, "Introduction to approximation theory" , McGraw-Hill (1966) pp. Chapts. 4&6 |
| [a5] | M.J.D. Powell, "Approximation theory and methods" , Cambridge Univ. Press (1981) |
| [a6] | J.R. Rice, "The approximation of functions" , 1. Linear theory , Addison-Wesley (1964) |
| [a7] | T.J. Rivlin, "An introduction to the approximation of functions" , Blaisdell (1969) |
Polynomial of best approximation. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=Polynomial_of_best_approximation&oldid=48237