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Is complex valued function like $y(t) = t^2 + i\cdot t^2$ a periodic function?

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You can simply factorize your function as $y(t)=(1+\mathrm i)t^2$. So the question boils down to whether $t^2$ is a periodic function. That would mean that there's an $a\ne 0$ so that for all $t$, $(t+a)^2 = t^2$. Now applying the binomial formula and subtracting $t^2$ on both sides gives the equation $2ta+a^2=0$ or, if $a\ne 0$, $t=-a/2$, which clearly cannot be true for arbitrary $t$. Therefore the function is not periodic.

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    Thanks a lot for help. That's all I wanted to know.2012-09-17
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    Sorry I've one more question. if $a \neq 0, t = \frac{-a}{2}, \text{ which clearly cannot be true for arbitrary } t$ why's that? I mean why can't $t \neq \frac{-a}{2}$ for arbitrary $t$?2012-09-17
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    @mvr950: I'm not sure what you mean. The equation which would have to be true for arbitrary $t$ is $t=-a/2$. This equation is clearly not fulfilled for $t\ne-a/2$ because that's exactly what $t\ne-a/2$ means. But it would have to be fulfilled for all values of $t$ if $t^2$ were periodic.2012-09-17
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    Sorry I made a spelling mistake in my last post. I meant why can't $t = \frac{-a}{2}$ for arbitrary $t$? Why can't I use $t = \frac{-a}{2}$?2012-09-17
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    Because for a given $a$, there's exactly one $t$ which fulfils the equation $t=-a/2$, namely the one which you get by dividing $a$ by $2$ and changing the sign. For example, for $a=1$, the only $t$ which fulfils $t=-a/2$ is $t=-1/2$, but e.g. $t=1$ doesn't fulfill that equation. Thus $t^2$ is not $1$-periodic. The same is true for any $a$, therefore $t^2$ is not periodic at all. The critical point is that for *fixed* $a$, the equation would have to be fulfilled for *all* $t$. There's no $a$ such that $t=-a/2$ is fulfilled for all $t$.2012-09-17
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    Because $(\frac{-a}{2} + a)^2$ is equal to $t^2 = (\frac{-a}{2})^2$.2012-09-17
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    I have no idea at all what you want to say with that latest comment, sorry.2012-09-17
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    sorry I posted without seeing your posting. Yes I understand now. Thanks.2012-09-17
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No non-constant polynomial $p(x)$ can ever be periodic. If it were, there would be infinitely many solutions to $p(x)-p(0) = 0$.

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This is nothing but $(1+i)t^{2}$. Why you would think this is periodical?

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    I just wanted to make sure. Thanks for your answer.2012-09-17