# Compute the 'elbow' for a curve automatically and mathematically

One example for curve is shown as below. The elbow point might be x=3 or 4. How to compute the elbow for a curve automatically and mathematically?

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You may want to ask that here: math.stackexchange.com. But in any case you need to provide some context on how the curve is produced and what possible shapes it can take. –  TToni Dec 17 '10 at 15:33
possible duplicate of finding the best trade-off point on a curve –  Jacob Dec 17 '10 at 15:38
There is an excellent answer to this problem. Check out the link I've posted as a possible duplicate. –  Jacob Dec 17 '10 at 15:39
The solutions for finding the best trade-off point on a curve (stackoverflow.com/questions/2018178/…) is a good suggestion. However, this solution depends on the points on the curve. I take the suggestion of @ebo and @Chris Taylor by looking for the point with the maximum absolute second derivative which, for a set of discrete points x[i] as I have there, is approximated with a central difference: secondDerivative(i) = x(i+1) + x(i-1) - 2 * x(i); [max,idx] = max(secondDerivative); –  Jie Dec 19 '10 at 0:03

You might want to look for the point with the maximum absolute second derivative which, for a set of discrete points `x[i]` as you have there, can be approximated with a central difference:

`secondDerivative[i] = x[i+1] + x[i-1] - 2 * x[i]`

As noted above, what you really want is the point with maximum curvature, but the second derivative will do, and this central difference is a good proxy for the second derivative.

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The data provided is noisy. You'll need to be more careful than that. Your suggestion might identify, for example, x=12 or x=19. –  Josephine Dec 18 '10 at 20:26
Thanks for your suggestions. I take your idea as my solutions. –  Jie Dec 18 '10 at 23:51
Hi, Chris, You got me a good answer. Can you tell me if there is a reference for this solution? I want to draft a paper and so I need a reference for this solution. –  Jie May 23 '11 at 7:49

Functions like this one are usually called L-curves for their shapes. They appear when solving ill-posed problems through regularization.

The 'elbow'-point is the point on the curve with the maximum absolute second derivative.

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Yes, your ideas is the same as Chris Taylor. Thanks. –  Jie Dec 18 '10 at 23:52
Another question is that why the 'elbow'-point is the point on the curve with the maximum absolute second derivative? –  Jie Dec 19 '10 at 0:26