Arithmetic Average of Second Chebyshev Function

Theorem
Let $x \ge 1$ be a real number.

Then:
 * $\ds \sum_{n \mathop \le x} \map \psi {x/n} = x \ln x - x + \map \OO {\map \ln {x + 1} }$

where:
 * $\OO$ is big-O notation
 * $\psi$ is the second Chebyshev function.

Proof
We have, by the definition of the second Chebyshev function:


 * $\ds \sum_{n \mathop \le x} \map \psi {x/n} = \sum_{n \mathop \le x} \sum_{m \mathop \le x/n} \map \Lambda m$

where $\Lambda$ is the Von Mangoldt function.

Consider the sum:


 * $\ds \sum_{n \mathop \le x} \sum_{m \mathop \le x/n} \map \Lambda m$

The sum runs over the pairs of natural numbers $\tuple {n, m}$ such that $n m \le x$.

This is equivalent to running over the divisors of each natural number $t$ such that $t \le x$.

That is:


 * $\ds \sum_{n \mathop \le x} \sum_{m \mathop \le x/n} \map \Lambda m = \sum_{t \mathop \le x} \sum_{m \mathop \divides t} \map \Lambda m$

Then, from Sum Over Divisors of von Mangoldt is Logarithm, we have:


 * $\ds \sum_{t \mathop \le x} \sum_{m \mathop \divides t} \map \Lambda m = \sum_{t \mathop \le x} \ln t$

With a view to bound this sum, note that:


 * $\ds \sum_{t \mathop \le x} \ln t = \ln 1 + \sum_{2 \mathop \le t \mathop \le x} \ln t = \sum_{2 \mathop \le t \mathop \le x} \ln t$

We have, from Sum of Integrals on Adjacent Intervals for Integrable Functions:


 * $\ds \sum_{2 \mathop \le t \mathop \le x} \ln t = \sum_{2 \mathop \le t \mathop \le x} \paren {\int_{t - 1}^t \ln t \rd u}$

From Logarithm is Strictly Increasing, we have:


 * $\ln u \le \ln t \le \map \ln {u + 1}$

for $t - 1 \le u \le t$.

So, from Relative Sizes of Definite Integrals:


 * $\ds \sum_{2 \mathop \le t \mathop \le x} \paren {\int_{t - 1}^t \ln u \rd u} \le \sum_{2 \mathop \le t \mathop \le x} \paren {\int_{t - 1}^t \ln t \rd u} \le \sum_{2 \mathop \le t \mathop \le x} \paren {\int_{t - 1}^t \map \ln {u + 1} \rd u}$

Now, from Sum of Integrals on Adjacent Intervals for Integrable Functions, we have:


 * $\ds \sum_{2 \mathop \le t \mathop \le x} \paren {\int_{t - 1}^t \map \ln {u + 1} \rd u} = \int_1^{\floor x} \map \ln {u + 1} \rd u$

and:


 * $\ds \sum_{2 \mathop \le t \mathop \le x} \paren {\int_{t - 1}^t \ln u \rd u} = \int_1^{\floor x} \ln u \rd u$

We can compute:

and:


 * $\ds \int_1^{\floor x} \ln u \rd u = \floor x \ln \floor x - \floor x$

Since $x - 1 < \floor x \le x$, and $1 - 2 \ln 2 < 0$, we have:


 * $\paren {\floor x + 1} \map \ln {\floor x + 1} - \floor x - 2 \ln 2 + 1 \le \paren {x + 1} \map \ln {x + 1} - x$

and:


 * $\paren {x - 1} \map \ln {x - 1} - \paren {x - 1} \le \floor x \ln \floor x - \floor x$

from Logarithm is Strictly Increasing.

We have therefore obtained that:


 * $\ds \paren {x - 1} \map \ln {x - 1} - \paren {x - 1} \le \sum_{n \mathop \le x} \map \psi {x/n} \le \paren {x + 1} \map \ln {x + 1} - x$

We will use this inequality to show that:


 * $\ds \sum_{n \mathop \le x} \map \psi {x/n} - \paren {x \ln x - x} = \map \OO {\map \ln {x + 1} }$

We have:


 * $\ds \paren {x - 1} \map \ln {x - 1} - x \ln x \le \sum_{n \mathop \le x} \map \psi {x/n} - \paren {x \ln x - x} \le \paren {x + 1} \map \ln {x + 1} - x \ln x$

We will show that for sufficiently large $x$ we have:


 * $\paren {x + 1} \map \ln {x + 1} - x \ln x \le 2 \map \ln {x + 1}$

and:


 * $-2 \map \ln {x + 1} \le \paren {x - 1} \map \ln {x - 1} - x \ln x$

at which point we have the claim.

Lemma 2
Putting these two inequalities together, for $x \ge 3$ we have:


 * $\ds -2 \map \ln {x + 1} \le \sum_{n \mathop \le x} \map \psi {x/n} - \paren {x \ln x - x} \le 2 \map \ln {x + 1}$

so, by the definition of big-O notation:


 * $\ds \sum_{n \mathop \le x} \map \psi {x/n} - \paren {x \ln x - x} = \map \OO {\map \ln {x + 1} }$

so:


 * $\ds \sum_{n \mathop \le x} \map \psi {x/n} = x \ln x - x + \map \OO {\map \ln {x + 1} }$