Analysis

Real & Complex Analysis, Calculus & Multivariate Calculus, Functional Analysis,
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Asis ghosh
Posts: 9
Joined: Mon Feb 05, 2018 4:22 am

Analysis

#1

Post by Asis ghosh »

solve the question

Let $f:[0, 2\pi] \rightarrow [0, 2\pi]$ be continuous such that $f(0)=f(2\pi)$. Show that there exists $x \in [0, 2\pi]$ such that

$$f(x)= f(x+\pi)$$
Last edited by Math_Mod on Thu Feb 15, 2018 1:53 pm, edited 1 time in total.
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Riemann
Posts: 176
Joined: Sat Nov 14, 2015 6:32 am
Location: Melbourne, Australia

Re: Analysis

#2

Post by Riemann »

Asis ghosh wrote:solve the question

Let $f:[0, 2\pi] \rightarrow [0, 2\pi]$ be continuous such that $f(0)=f(2\pi)$. Show that there exists $x \in [0, 2\pi]$ such that

$$f(x)= f(x+\pi)$$
Hello my friend,

consider the function $g(t)=f(t) - f(t+\pi) \; , \; t \in [0, 2\pi]$. Clearly, $g$ is continuous as a sum of continuous functions. Note that

$$g(0)=f(0)-f(\pi) \quad , \quad g(\pi)=f(\pi)-f(2\pi)=f(\pi)-f(0)$$

Hence

$$g(0) g(\pi) = -\left ( f(0)- f(\pi) \right )^2 \leq 0$$

Hence by Bolzano's theorem we have that there exists an $x \in (0, \pi) \subset [0, 2\pi]$ such that $g(x)=0$. That is $f(x)=f(x+\pi)$. Can you now complete the proof of the existence of $x \in [0, 2\pi]$?
$\displaystyle \sum_{n=1}^{\infty}\frac{1}{n^s}= \prod_{p \; \text{prime}}\frac{1}{1-p^{-s}}$
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