# Normalize to scale

I have an 2-D array of data (C), where C(:,1) has values corresponding to C(:,2). C(:,2) varies from 0.0001:0.0001:1, i.e. 10,000 values. I need to calculate the d(log(C(i,1))) / d(log(C(i,2))), which I do by simply calculating log(C(i,1)) / log(C(i,2)). But as C(i,2), approaches 1, the denominator approaches zero, and the quotient shoots up. One way to keep this in check would be to normalize it using a parameter, but I'm not sure how to do that. Does anyone have an idea about this?

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You want to calculate the quotient... but not if the quotient is too big... so you want to perform some other calculation instead. what are you actually trying to do? –  Beta Jan 14 '13 at 15:58
I actually want to plot this quotient, i.e. the slope d(log(C(i,1))) / d(log(C(i,2))) vs log(C(:,2)), and as C(i,2) approaches 1, the slope should converge to zero, to be able to study it. –  Eight Jan 14 '13 at 16:06

Since this is discrete differentiation, the answer is bound to be a little inelegant.

You're interested in the derivative d(log(C(i,1))) / d(log(C(i,2)))

``````=∆(log(C(i,1))) / ∆(log(C(i,2)))

=(log(C(i+1,1))-log(C(i,1))) / (log(C(i,2)) - log(C(i,2)))
``````

which is tractable. The denominator does not go to zero, it goes to the step size (0.0001).

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