Difference approximation of elementary differential operators 67In a similar manner one can wt·ite down on the pattern 5.a the operator(24)On the other hand, a two-parameter family of difference operatorsis based on the nine-point pattern 5.d, whence (23) follows for 0" 1 = 0" 2 = 0
and (24) follows for 0" 2 = 0 and 0" 1 = 1. We have occasion to use the
asymptotic formulae82 v(x, t) 2
V11 = 8t2 +O(r ), vxx - = a2v(x, 8x2 t) + 0(12) i ,thereby justifying that operator (23) provides an approximation of O(h^2 +
r^2 ). Operator (25) has the same order of approximation for 0" 1 = 0" 2 = O",
where O" is an arbitrary number.
We note in passing that a key role of the parameters 0" 1 and 0" 2 just
as the parameter O" in the previous example is connected not only with the
approximation order, but also with stability of the appropriate difference
scheme. This important property will appear in subsequent discussions in
Chapter 5, Section LExample 6. L v = v^11 • An irregular pattern (a non-equidistant grid).
Grantee! two numbers h_ > 0 and h+ > 0, other ideas are connected with
the three-point pattern ( x - h_, x, x + h+). When h_ f- h+, any such
pattern is said to be irregular, since the grid including this pattern turns
out to be non-equidistant. Being concerned with new membersv(x)-v(x~h_)
vx = h_ ,v(x + h+) - v(x)
Vx = h
+
we refer to the operator L1i with the valuesIi= h_ + h+
2(26) L1i v - ~ Ii [v(x + h+) h+ - v(x) v(x) - v(x h_ - h-)]
For h_ = h+ = n. the preceding is identical with expression (7) (see Example
2). Plain calculations of the local approximation error at a point x show
that