Advanced High-School Mathematics

(Tina Meador) #1

SECTION 5.2 Numerical Series 281


∑n
k=1

akbk = snbn+1+

∑n
k=1

sk(bk−bk+1).

Proof. Settings 0 = 0 we obviously haveak=sn−sk− 1 , k≥1. From
this, one has


∑n
k=1

akbk =

∑n
k=1

(sk−sk− 1 )bk

=

∑n
k=1

skbk−

∑n
k=1

sk− 1 bk

= snbn+1+

∑n
k=1

sk(bk−bk+1).

Dirichlet’s Theorem for Convergence. Let (an) and (bn) be


two sequences of real numbers. If the partial sums


∣∣
∣∣

∑n
k=1

an

∣∣
∣∣
∣ are all

bounded by some constantM, and if


b 1 > b 2 > b 3 >···≥ 0 with nlim→∞bn= 0,

then the series


∑∞
k=1

akbk converges.

Proof. Settingsn=


∑n
k=1

anandrn=

∑n
k=1

akbk we have from the above

lemma that


rn−rm=snbn+1−smbm+1+

∑n
k=m+1

sk(bk−bk+1),

wheren≥mare positive indices. Taking absolute values and applying
theTriangle inequalityprovides


|rn−rm| ≤ |sn|bn+1+|sm|bm+1+

∑n
k=m+1

|sk|(bk−bk+1)

≤ Mbn+1+Mbm+1+M

∑n
k=m+1

(bk−bk+1)

= 2Mbm+1.
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