48 Basic Concepts of the Theory of Difference Schernes
for all x. As a matter of fact,
(Ax, x) = (A 0 x, x),
where A 0 = (A+ A* )/2 is a self-adjoint operator. Hence, (Ax, x) > bl I x 112,
where c5 is the smallest eigenvalue of A 0. The number c5 cannot vanish due
to the positiveness of the operator A.
For the sake of simplicity we will assume in the body of this book that
H is a finite-dimensional space.
Recall that the norm of an operator A is defined by
llAll= sup llAxll·
11x11=1
With this, for any self-adjoint operator A the following relations occur:
l(Ax,x)I
11x11
( 11) llAll= sup l(Ax,x)l=llAll= sup
II x 11=1 II x ll;to
Lemma 3 If S = S* is a linear bounded operator and n is a positive
integer, tlren
Proof \!Ve proceed to prove this assertion by induction on n. Let n = 2.
Then
1152 11= sup l(S^2 x,x)I= sup llSxii2=11Sll^2 ,
11x11=1 11x11=1
meaning 11 52 11 = 11 S 112. Assuming that relation (12) is valid with n = k - l
and n = k, we are going to show that it continues to hold for n = k + 1,
k > 1. Indeed,
llS^2 kll= sup l(S^2 kx,:i:)I= sup l(Sk+^1 x,sk-^1 x)I
11 x lt=1 11x11=1
< sup II 5k+^1 x II · II sk-lx II< II s"+^1 II · II sk-l II
11x11=1
or, what amounts to the same,
11 sk+l II · II sk-^1 II> II s^2 k II= II sk 112 =II s ll^2 k.
This provides support for the view that 115k+l II> II S llk+l, since
II 5k-^1 II= II s llk-l.
On the other hand,
so that
II sk+l II= II s llk+l.
As far as (12) holds for n = 1 and n = 2, it will be true for any n.