0
$\begingroup$

Does there exist such an equation that the differences, are infinite? And if there isn't then what is the proof?

For example:

$x^2$ has a finite difference of 2.

$ \begin{array}{c|c|c|c} n & y & \text{first differences} & \text{second differences} \\ \hline 1 & 1 & 0 & 0 \\ 2 & 4 & 3 & 2 \\ 3 & 9 & 5 & 2 \\ 4 & 16& 7 & 2 \\ 5 & 25& 9 & 2 \\ \end{array} $

Therefore, all of the second differences are the same. Furthermore, this found by subtracting the first differences e.g. $5-3 = 2$ and $7-5=2$ etc.

  • 0
    in essence, yes.2012-09-19

2 Answers 2

2

If $y$ is finite for every $n$, then the first differences, being differences of finite numbers, will all be finite, and then the second differences, being differences of finite numbers, will all be finite, and so on. You'll never get any infinite differences --- how could you?

Now, you can get unbounded differences, e.g., see what happens if you take $y$ to be $2^n$. But that's a different thing entirely.

  • 0
    Yes, now I have. I see what you mean.2012-09-21
2

What you will find is that if you start with any polynomial the $k$th differences will eventually be constant. The reason for this is that the difference of two values on a polynomial is a multiple of the value of its derivative inbetween, $ p(x+1)-p(x)=p'(c)(x+1-x) = p'(c) $ for some $c$ between $x$ and $x+1$. For the $k$th differences we may slightly modify this argument to show that that they are multiples of $p^{(k)}$ at some point.

However, we know that the ($n+1$) derivative of an $n$th degree polynomial will be zero, so the $n$th differences will be constant.

You will find that if you try with a function that is infinitely differentiable and all of its derivatives are positive, the $k$th differences will never be constant. A good example of such a function is $e^x$.