Advanced High-School Mathematics

(Tina Meador) #1

SECTION 5.2 Numerical Series 277



  1. As in the above sequence, LetF 0 , F 1 , F 2 , ... be the terms of the
    Fibonacci sequence. Show that


∑∞
k=0

1

Fk

< α,where α =

1 +


5

2

(thegolden ratio). (Hint: show that if k ≥2, thenFk > αk−^1.
and then use the ratio test.)^12


  1. Consider the generalized Fibonacci sequence (see Exercise 9 on
    page 106) defined byu 0 =u 1 = 1 and un+2= un+1+un. Show
    that ifa, bare such thatun→0 asn→∞, then


∑∞
n=0

unconverges
and compute this sum in terms ofaandb.

5.2.3 Conditional and absolute convergence; alternating se-
ries


In this subsection we shall consider series of the form


∑∞
n=0

an where

the individual terms an are not necessarily non-negative. We shall


first make the following useful definition. An infinite series


∑∞
n=0

an is

calledabsolutely convergent if the series


∑∞
n=0

|an|converges. This is

important because of the following result.


Theorem. If the series


∑∞
n=0

an is absolutely convergent, then it is con-

vergent.


Proof.Note that we clearly have


0 ≤an+|an|≤ 2 |an|, n= 0, 1 , 2 , ....

Since


∑∞
n=0

2 |an|converges, so does

∑∞
n=0

(an+|an|); call the limitL. There-

fore,


∑∞
n=0

an=L−

∑∞
n=0

|an|, proving that

∑∞
n=0

anconverges, as well.

(^12) The above says, of course, that the infinite series of the reciprocals of the Fibonacci numbers
converges. Its value is known to be an irrational number≈ 3. 35988566 ...

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