Hermite Id.

rsoldo · 02.08.2019, 08:57

If $x$ is a positive number and $n$ is a positive integer, prove using the Hermite's Identity that:
$\[[nx] > \frac{[x]}{1} + \frac{[2x]}{2} + \frac{[3x]}{3} + ... + \frac{[nx]}{n}.\]$

wrest · 02.08.2019, 11:42

rsoldo
Inequality does not hold for $x=1,n=1$ , we have $nx=1; [nx]=[1\cdot x]/1$ (assume square brackets mean integer part of a number between them)

rsoldo · 02.08.2019, 13:07

It's a trivial case when hold equality :-)

wrest · 02.08.2019, 14:00

rsoldo
Yes, but you’ve used $>$ symbol, not $\ge$
Mistake?

nnosipov · 02.08.2019, 16:17

rsoldo в сообщении #1408298 писал(а):

If $x$ is a positive number and $n$ is a positive integer, prove using the Hermite's Identity that:
$\[[nx] > \frac{[x]}{1} + \frac{[2x]}{2} + \frac{[3x]}{3} + ... + \frac{[nx]}{n}.\]$

In the case $\{x\}<1/n$ , this is not true. Can you give a correct version?

rsoldo · 02.08.2019, 18:59

Ok. This is another case where hold equality. My mistake, I have to include equality.
Otherwise, this is Problem from USAMO 1981.

rsoldo · 20.11.2020, 12:35

Reminder on Problem if anyone got nice idea ( using the Hermite's Identity, of course ).

If $x$ is a positive real number, and $n$ is a positive integer, prove that

$\[[ nx]\geq \frac{[ x]}1 + \frac{[ 2x]}2 +\frac{[ 3x]}3 + \cdots + \frac{[ nx]}n\]$

Спасибо!

Edward_Tur · 20.11.2020, 19:40

Индукция. Для $n=1$ неравенство очевидно. Индуктивный переход. Предположим, что оно верно для $1,2,...,n$ и докажем его для $n+1$ .
Сложим неравенства $[x]\ge[x],[2x]\ge[x]+\frac{[2x]}2,...,[nx]\ge[x]+\frac{[2x]}2+...+\frac{[nx]}n:$
$[x]+[2x]+...+[nx]\ge n[x]+(n-1)\frac{[2x]}2+...+\frac{[nx]}n.$
Прибавим к обеим частям сумму $[x]+[2x]+...+[nx]$ и воспользуемся неравенством $[a+b]\ge[a]+[b]$ :
$n[(n+1)x]\ge\left([x]+[nx]\right)+\left([2x]+[(n-1)x]\right)...+\left([nx]+[x]\right)\ge (n+1)\left([x]+\frac{[2x]}2+...+\frac{[nx]}n\right),$
$\frac n{n+1}[(n+1)x]\ge[x]+\frac{[2x]}2+...+\frac{[nx]}n,$
$[(n+1)x]\ge[x]+\frac{[2x]}2+...+\frac{[nx]}n+\frac{[(n+1)x]}{n+1}.$

rsoldo · 25.11.2020, 14:10

If you need... ( Hermite's ident. )

$\lfloor nx\rfloor=\sum_{i=0}^{n-1}\left\lfloor x+\frac in\right\rfloor$

Научный форум dxdy

Hermite Id.