Bohman-Korovkin theorem
The starting point is the following theorem of P.P. Korovkin (1953) [a6], [a7]: for a given sequence 
of positive linear operators on the space 
into itself (where 
is a compact interval and 
denotes the Banach space of all continuous real-valued functions on 
with the supremum norm 
), the relations
 |
imply convergence:
 |
Here, the functions 
are defined by 
and 
is the supremum norm on the interval 
. An element 
is positive (denoted by 
) if 
for all 
, and the linear operator 
is positive if 
implies 
. One year earlier, in 1952, H. Bohman [a2] had proved this theorem for positive operators 
having a representation
 |
with 
knots 
in the open interval 
, and 
on 
.
One says that the functions 
are a Korovkin set for (positive linear operators on) 
. Korovkin proved that a set of three functions in 
that replaces the set 
must be a Chebyshev system; he also proved that there are no sets of only two functions such that convergence for these two functions implies convergence for all 
(cf. also Korovkin theorems; Korovkin-type approximation theory).
The results have been generalized to other compact Hausdorff spaces 
. For example, on the circle 
, the set of functions 
with 
, 
, 
is a Korovkin set for 
. As usual, one identifies the functions in 
with the continuous 
-periodic functions on 
(cf, [a1], [a4]). On the 
-dimensional cube 
, the set of 
functions 
(with 
and 
for 
and 
) is a Korovkin set for 
, but not a minimal Korovkin set.
There is also the following generalization. Let 
be a Banach lattice, let 
be the class of all positive linear operators on 
, and let 
be a fixed subset of 
. Then the Korovkin closure (or shadow, or Korovkin hull) 
of 
is the set of all 
with the property that for each sequence 
in 
the relations 
, 
, imply 
. The problem is to find 
for a given 
; if 
, then 
is a Korovkin set (cf. [a1], [a5], [a8]).
In some cases one can prove a quantitative form of the Korovkin theorem, estimating the rate of convergence 
in terms of the rate of convergence for the elements of the Korovkin set. For 
one has obtained estimates in terms of the first- or second-order modulus of continuity 
; for example:
 |
with 
and some constant 
.
If some 
is a polynomial operator, i.e., 
is a polynomial of degree less than or equal to 
, then at least one of the functions 
can not be approximated better than 
.
Similar results can be obtained for 
. Also, it is possible to estimate 
in terms of the moduli of smoothness corresponding to
 |
Furthermore, quantitative Korovkin theorems for positive linear operators on 
-spaces have been obtained (cf. [a3], [a4]).
References
| [a1] | F. Altomare, M. Campiti, "Korovkin-type approximation theory and its applications" , de Gruyter (1994) |
| [a2] | H. Bohman, "On approximation of continuous and of analytic functions" Arkiv. Mat. (2) , 1 (1952) pp. 43–56 |
| [a3] | R.A. DeVore, "The approximation of continuous functions by positive linear operators" , Lecture Notes in Mathematics , 293 , Springer (1972) |
| [a4] | R.A. DeVore, G.G. Lorentz, "Constructive approximation" , Springer (1993) |
| [a5] | K. Donner, "Extension of positive operators and Korovkin theorems" , Lecture Notes in Mathematics , 904 , Springer (1982) |
| [a6] | P.P. Korovkin, "On convergence of linear positive operators in the space of continuous functions" Dokl. Akad. Nauk. SSSR , 90 (1953) pp. 961–964 (In Russian) |
| [a7] | P.P. Korovkin, "Linear operators and approximation theory" , Hindustan Publ. Corp. (1960) (In Russian) |
| [a8] | G.G. Lorentz, M. von Golitschek, Y. Makovoz, "Constructive approximation: advanced problems" , Springer (1996) |
Bohman-Korovkin theorem. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=Bohman-Korovkin_theorem&oldid=16494