120 Basic Concepts of the Theory of' Difference Sche1nesIn this case we write, as before, A = Ah with further reference that h is a
vector of the dimension N, that is, an element of the space Qt consisting
of all functions defined on the gridwt= { X; E ( 0, 1], i = 1, 2, ... , N, xN = 1}.
Example 2. The third boundary-value problem. Given the same
grid wh as in Example 1, we now consider the difference boundary-value
problem of the third kindAy = Y:tx = -J(x)' O<x=ih<l,
(9)Let rth be a set of all functions defined on the grid wh = { J:; = i h, i =
0, 1, ... , N }. We begin by specifying the operator A by the relations
1
0.5h (Y~·.o - cr1 Yo)= A_- y, i --^0 '
(A Y); = A y = Y:fJo:' i=l,2, ... ,N-1,- 0.5 1 ( h Y:r:,N + CT2YN) -- A + y' i = N.
By merely setting A= -A problem (9) is recast as
(10)where'Pi =
Ay=<p,
1
0.5 h μ^1 '
f;'
1
-0 .u r: I 7, μ^2 'i = 0'
i = 1, 2, ... , N - 1,i = N.
The linear operator A 1naps (th onto (th. To 1nake our exposition 1nore
transparent, it will be convenient to introduce the inner product
N-1
[y, v] = L Y;V;h+ ~h(y 0 v 0 +yNvN)
i=land the associated norm I [y] I = J[Y,Y]. The operator A is self-adjoint,
that is, [y, Av] = [v, Ay], where
1
[y, Av] = -(y, Av) - 2 h (Yo A - v + YN A+ v)