678 Methods for Solving Grid EquationsOn account of the basic theoren1 proved in Section 1 of the present
chapter Seidel method converges if the operator A is self-adjoint and posi-
tive. !VI ore specifically, the sufficient stability condition (11) for the conver-
gence of iterations in scheme (3') with a non-self-adjoint operator B takes
the fonn(8)T
Bo - -A> 0.
2Within the fra1nework of Seidel method we thus have B = A- + D, T = 1
and
Bo=~ [(A-+D)+(A- +D)*] =~(A- +A+ +2D),since A+ = (A -)* and D* = D > 0 in light of the properties of the operator
A: A= A* > 0. With this in mind, condition (8) becomesT 1 1
Bo - - A = B 0 - - A > 0 = - D > 0
2 2 2thereby justifying that Seidel method converges with the rate of a geometric
progression.- The upper relaxation method. In order to accelerate the iteration
process in view, we are forced to revise Seidel method by inserting in (5)
the i tera ti on parameter w so that
(9) ( A-+wD l ) (y k+l -y)+AY=f. k k
This method falls within the category of relaxation methods and gives rise
to Seidel method in one particular case where w = 1. In the modern
literature the iteration process (9) with w > 1 is known as the upper
relaxation inethod.
By comparing of (9) with (6) it is easily seen that
1
B=A-+-D,
wor, what amounts to the same,
B=wA-+D,
As far as a non-self-adjoint operator Bis concerned, the workable procedure
reduces to inversion of a lower triangle matrix.