272 Difference Schemes for Elliptic Equations4.4 SOME PROPERTIES OF DIFFERENCE ELLIPTIC OPERATORSIn this section we reveal some properties of difference operators approxi-
mating the Laplace operator in a rectangle and derive several estimates for
difference approximations to elliptic second-order operators with variable
coefficients and mixed derivatives.- Eigenvalue problems for the Laplace difference operator in a rectan-
gle. Let Go = {O < Xcx < IQ J Cl: = 1, 2} be a rectangle, wh = {x =
(i 1 h 1 , i 2 h 2 ), i°' = 0, 1, 2, ... , Ncx, Na h°' =I°'} be a grid in Go and lh be
the set of all boundary grid nodes. The grid w h is taken to be equidistant
in each direction x °' with step ha.
The eigenvalue problem for the Laplace operator in the rectangle Go
subject to the first kind boundary conditions
6.v+ Av= 0, xEGo, vlr=O, v(x):,i:O,
has an infinite set of the eigenvalues such aska = 1,2,. .. , CY= 1,2,
associated with the orthonormal system of eigenfunctionsso that
where
I 1 I 2
(u:v)= j dx 1 j dx 2 u(x 1 ,x 2 )v(x 1 ,x 2 ).
0 0This problem can be solved by the method of separation of variables. The
eigenvalue problem for the difference Laplace operator Ay = Y:c,x, + Yx 2 x 2
supplied by the first kind boundary conditions may be set up in a quite
similar manner as follows: it is required to find the values of the parameter
A (eigenvalues) associated with nontrivial solutions of the homogeneous
equation subject to the homogeneous boundary conditions
(1) Au+ Av= 0, vi -Yh = 0, v(x):,i:O.