If $f(x+1) + f(x-1) = \sqrt3f(x)$, then what is the period of $f(x)$?
periodicity of function
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6And what have you tried? – 2011-05-07
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0Hint: Mathematica says that your $f(x)$ are of the form $f(x)=e^{-\frac{1}{6} i \pi x} \left(a+b e^{\frac{i \pi x}{3}}\right)$ for some real $a,b$ – 2011-05-07
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0@user3123 : Actually, I think Mathematica's answer is not exhaustive. You can take $a$ and $b$ to be any $1$-periodical function. – 2011-05-07
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0ok I did not check that – 2011-05-07
2 Answers
You can start solving the equation $(E_{\lambda})$ (where $\lambda$ is a complex number) :
$f(x+1) = \lambda \, f(x)$
If $\lambda_1$ and $\lambda_2$ are the roots of $X^2 - \sqrt{3} X + 1$, you can check solutions to $(E_{\lambda_1})$ and $(E_{\lambda_2})$ are solution to your equation. Conversely solution of your equation are linear combinations of the previous ones.
Finally (and most importantly), you can wonder how I came up with this idea and what is the general setting in which this idea could be applied.
$$ f(x+1)+f(x-1) = \sqrt{3} f(x) $$
$$ \sqrt{3}f(x+1) + \sqrt{3}f(x-1)= 3f(x) $$
$$ f(x)+f(x+2)+f(x-2)+f(x)= 3 f(x)$$
$$ f(x+2)+f(x-2)=f(x) $$
$$ f(x+4)+f(x) = f(x+2) $$
Adding last two equations give ,
$$ f(x+4)+f(x-2)= 0$$
$$ f(x+10)+f(x+4)= 0 \implies f(x+10) = f(x-2) \implies f(x+12)=f(x) $$
Thus period = 12 $\Box$
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0To be strickt: this only shows that the period is at most 12. – 2014-07-09