Thursday, July 21, 2016

derivatives - Why is this incorrect (regarding differentiating the natural log)?



We must differentiate the following:



$$ [f(x) = \ln (3x^2 +3)]\space '$$



Why is this incorrect? I am just using the product rule:



$ [f(x) = \ln (3x^2 +3)]\space ' = \dfrac{1}{x} \times (3x^2 + 3) + \ln(6x) = \dfrac{3x^2 +3}{x} + \ln(6x)$




My book gives the following answer:



$$\dfrac{6x}{3x^2 +3}$$


Answer



There is no product here; you should be using the chain rule.



The start of your answer makes it look like you were differentiating $\log(x) \cdot (3x^2 + 3)$ instead of the given function, but the latter part of your attempt clarifies that you are just getting tangled up.



(Also, it's a bit strange that your book didn't reduce its final answer, but it's still correct.)




More precisely:



$[f(g(x))]' = f'(g(x)) \cdot g'(x)$.



In this case,
$$[\log(3x^2 + 3)]' = \frac{1}{3x^2 +3} \cdot (3x^2 + 3)' = \frac{6x}{3x^2 + 3}$$ as your book suggests. Of course, we could divide top and bottom by $3$ to simplify our answer to:



$$\frac{2x}{x^2 + 1}$$




Going back to the original function, note that $\log(3x^2 + 3x) = \log(3) + \log(x^2 + x)$. If you now differentiate the function in this form, the derivative of the constant term $\log(3)$ will be $0$, and you will end up with the same answer as above (already in simplified form).


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