1550251515-Classical_Complex_Analysis__Gonzalez_

(jair2018) #1
Sequences and Series

taking Dn = nlnn in (c). Then

Dn+1 = (n + 1) ln(n + 1) = (n + 1) (inn+ ln ( 1 + ~)]


=(n+l) [inn+~ +O(n-^2 )]


1
=(n+l)lnn+l+ - +O(n-^1 )
n
so that

Dn-lanl lanl ( -1
1

--
1


  • Dn+1 = nlnn-
    1


--
1


  • n + l)lnn -1-O(n )
    an+1 an+1


Hence

= lnn [n (~ -1)-1] -1-O(n-^1 )
lan+1I

lim (nn -


1

lanl I - Dn+ 1 ) = lim Inn [n (-
1

lanl I -1) -1] -1
n-+oo an+1 n->oo an+1

and it follows that if


lim lnn[n(-
1

1anl
1

-1)-1] >1
n-+oo an+1

the series 2= Ian I converges, and if


lim ln n [n (-
1

Ian I I - 1) -1] < 1
n-+oo an+1

the series diverges.


195

There are also a number of special rules discussed in treatises on series,
some of which can be obtained from the preceding tests. As an example,
we prove the following:
(g) Suppose that


~ =a:+ f!_ + O(n-,.,,)
lan+1 I n

where a:, (:J, 1 are real constants with 'Y > 1. Then, if a: > 1, the series

2= Ian I converges, and if a: < 1, 2= Ian I diverges. If a: = 1, then 2= Ian I


converges if (:J > 1 and diverges if (:J :::; 1.

Proof The first part follows at once from the ratio test, since lim(lanl/
lan+1 I) = a:. For case a: = 1 we have, using Raabe's test,


hm. n ( --Ian! -1 ) = (:J
n-+oo lan+1 I
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