Harder 3 unit question! (1 Viewer)

AbsoluteValue · Jul 2, 2012

The AM-GM inequality states that for any n positive real numbers a_1,a_2,a_3,… a_n: $\frac{a_{1}+a_{2}+...+a_{n}}{n} \geq \sqrt[n]{a_{1}a_{2}...a_{n}}$
_{Prove that:} $(n+1)^n\geq 2^{n}n!$
Can anyone prove this? It is really tricky but once you get it is easy to solve.

Carrotsticks · Jul 2, 2012

Why is the 'i' there?

Shadowdude · Jul 2, 2012

Where i is the imaginary unit?

AbsoluteValue · Jul 2, 2012

Carrotsticks said:
Why is the 'i' there?

Sorry, my bad, it is a factorial

I was revising complex numbers today so I'm still into imaginary stuff LOL

Aesytic · Jul 2, 2012

(n+1)/2 >/ root(n*1)
((n-1)+2)/2 >/ root((n-1)*2) ---> (n+1)/2 >/ root(2*(n-1))
((n-2)+3)/2 >/ root((n-2)*3) ---> (n+1)/2 >/ root(3*(n-2))
if we keep doing this, we should eventually get n/2 inequalities similar to those above
multiplying them all together:
[(n+1)^(n/2)]/2^(n/2) >/ root(1*2*3*...*(n-1)*n)
[(n+1)^n/2)]/2^(n/2) >/ root(n!)
(n+1)^(n/2) >/ (2^(n/2)) * root(n!)
squaring both sides,
(n+1)^n >/ 2^n * n!

Trebla · Jul 2, 2012

$$Let $ a_i = i\\\\$The inequality then becomes$\\\\\dfrac{1}{n}(1+2+3+.....+n)\geq (1\times 2 \times 3\times ..... \times n)^{\frac{1}{n}}\\\\$The $LHS$ is an arithmetic series hence$\\\\\dfrac{1}{2}(n+1)\geq (n!)^{\frac{1}{n}}$

The result then immediately follows....

AbsoluteValue · Jul 2, 2012

Yeah, that's right, it is really easy but say in the test you don't realise that 1 + 2 + 3 + … + n = n/2 (n+1), this means you can't do the question.

petepopp · May 3, 2013

Harder 3 unit question! (1 Viewer)

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