160 Homogeneous Difference Schemesis the error of approximation of equation (1) by the difference scheme (2)
on the solution u = 1t(x) of problem (1).
In Section 1.4 we have established conditions of the second-order lo-
cal approxirnation for the conservative scheme (2) with linear nonnegative
pattern functionals A[k(s)] and F[f(s)] such as:
(5) A[l]=l, A[s]=-!, F[l]=l, F[s]=O.
As can readily be observed, these conditions remain valid for any scheme
from the primary family.
In order to evaluate the order of accuracy for scheme (2), it is necessary
to make the accurate account of the error z = y - u being viewed as a solu-
tion of problem (3). Moreover, the desirable estimate should be expressed
in terrns of the right-hand side 1/;. In this direction the error of approxi-
mation to 1/;(x) is considered first. If k(x) E C(^3 ) and q(x), f(x) E cC^2 l,
then
1/;(x) =Au+ <p - (Lu+ f)= [(aux) x - (ku')'] - (d - q) u + (<p- J) = O(h^2 ).
This means that scheme (2) provides a local approximation of order 2, so
that 111/J lie< Mh^2 , where M = const > 0 is independent of h.
In the sequel we succeed in showing that111/J II. = ~~
1
h I k~l h 1/;k I < J'vi h2if k(x), q(x), f(x) E cC^2 l, meaning that k(x) possesses two (but not three)
continuous derivatives.
- The error of approximation in the class of discontinuous coefficients.
Our aim here is to justify that the error of approxirnation ( 4) can always
be represented in the forn1
(6) 1/; = 7/a: + 1/;*,
(7)(8)1/2
1/J7 = (<pi - j f(x; +sh) ds)
-1/21/2
( d; ui - j q(xi +sh) u(x; +sh) ds).
-1/2