Difference Green's function 1993.6 DIFFERENCE GREEN'S FUNCTION- Difference Green's function. Further estimation of a solution of the
boundary-value problem for a second-order difference equation will involve
its representation in terms of Green's function. The boundary-value prob-
lem for the differential equation
(1)Lu=-d ( k(x)-du) -q(x)u=-f(x),
dx dxO<x<l,
u(O) = 0, u(l) = 0, k(x)>c 1 >0, q(x)>O,
can add interest and aid in understanding. As known, the solution of this
problem arranges itself as an integral1
(2) u( x) = f G( x, ~) f ( 0 d~,
0where G(x, ~) is the source function or Green's function. Function (2) is a
solution to equation (1) subject to the boundary conditions u(O) = 0 and
u( 1) = 0 if Green's function G( x, ~) as a function of x for fixed ~ satisfies
the conditionsd ( dG(x, ~))
LxG(x,~)= dx k(x) dx -q(x)G(x,~)=0,(3) x I~,^0 < x < 1, G(O,~) = G(l,~) = 0,
[G] = G(~ + o,~) - G(~ - o,~) = 0, [ k dG] dx = -1 for X -- <, c.
The very defipition implies that Green's function is nonnegative and
symmetric:
G(x,~) > 0, G(x,~)=G(~,x).
The function C( x, ~) so defined can be written in the explicit form
(4) G(x, ~) =
D'(x) /)(~)
Cl'( 1)Cl'(~) fJ(J:)
n( 1)for x < ~,
for x :::: ~ ,