Real Analysis 495∑m∈M∑∞
k= 2∑∞
j= 11
mkj=
∑
m∈M∑∞
j= 1∑∞
k= 21
mkj.
Again, we can change the order of summation because the terms are positive. The
innermost series should be summed as a geometric series to give
∑
m∈M∑∞
j= 11
mj(mj− 1 ).
This is the same as
∑∞n= 21
n(n− 1 )=
∑∞
n= 2(
1
n− 1−
1
n)
= 1 ,
as desired.
(Ch. Goldbach, solution from G.M. Fihtenholts,Kurs Differentsial’novo i Integral’no-
vo Ischisleniya(Course in Differential and Integral Calculus), Gosudarstvennoe Izda-
tel’stvo Fiziko-Matematicheskoi Literatury, Moscow 1964)
364.Let us make the convention that the letterpalways denotes a prime number. Consider
the setA(n)consisting of those positive integers that can be factored into primes that do
not exceedn. Then
∏p≤n(
1 +
1
p+
1
p^2+···
)
=
∑
m∈A(n)1
m.
This sum includes∑n
m= 1
1
m, which is known to exceed lnn. Thus, after summing the
geometric series, we obtain
∏p≤n(
1 −
1
p)− 1
>lnn.For the factors of the product we use the estimateet+t
2
≥( 1 −t)−^1 , for 0≤t≤1
2
.
To prove this estimate, rewrite it asf(t)≥1, wheref(t)=( 1 −t)et+t
2. Because
f′(t)=t( 1 − 2 t)et+t^2 ≥0on[ 0 ,^12 ],fis increasing; thusf(t)≥f( 0 )=1.
Returning to the problem, we have
∏
p≤nexp(
1
p+
1
p^2)
≥
∏
p≤n(
1 −
1
p)− 1
>lnn.