494 Real Analysis
The problem now repeats forw 1 , which is irrational and between 0 and 1. Againp 1 has
to be the unique integer with the property that
1
p 1 + 1< 1 −p 0 w<1
p 1.
If we setw 2 = 1 −p 1 w 1 , then
w=1
p 0−
1
p 0 p 1+
w 2
p 0 p 1.
Now the inductive pattern is clear. At each step we setwk+ 1 = 1 −pkwk, which is an
irrational number between 0 and 1. Then choosepk+ 1 such that
1
pk+ 1 + 1<wk+ 1 <1
pk+ 1.
Note that
wk+ 1 = 1 −pkwk< 1 −pk1
pk+ 1=
1
pk+ 1,
and thereforepk+ 1 ≥pk+ 1 >pk.
Once the numbersp 0 ,p 1 ,p 2 ,...have been constructed, it is important to observe
that sincewk∈( 0 , 1 )andp 0 p 1 ···pk≥(k+ 1 )!, the sequence
1
p 0−
1
p 0 p 1+···+(− 1 )k+^1
wk+ 1
p 1 p 2 ···pkconverges tow.Sop 0 ,p 1 ,...,pk,...have the required properties, and as seen above,
they are unique.
(13th W.L. Putnam Mathematical Competition, 1953)
363.First, denote byMthe set of positive integers greater than 1 that are not perfect
powers (i.e., are not of the forman, whereais a positive integer andn≥2). Note that
the terms of the series are positive, so we can freely permute them. The series is therefore
equal to
∑m∈M∑∞
k= 21
mk− 1.
Expanding each term as a geometric series, we transform this into