- #1
moe darklight
- 409
- 0
I thought I should start numbering these... anyway, here's another brain-fart where I miss something obvious:
in the book the dude uses:
\[<br /> f(x) = \frac{1}{{30}}\sqrt {a^2 + x^2 } + \frac{1}{{60}}(b - x)<br /> \]<br />
later on he continues, using:
\[<br /> f'(x) = \frac{1}{{30}}\frac{1}{2}(a^2 + x^2 )^{ - 1/2} (2x) - \frac{1}{{60}}<br /> \]<br />
where'd that 2x come from? isn't the derivative of \[<br /> \sqrt {a^2 + x^2 } <br /> \] just \[<br /> \frac{1}{2}(a^2 + x^2 )^{ - 1/2} <br /> \]?
thanks
in the book the dude uses:
\[<br /> f(x) = \frac{1}{{30}}\sqrt {a^2 + x^2 } + \frac{1}{{60}}(b - x)<br /> \]<br />
later on he continues, using:
\[<br /> f'(x) = \frac{1}{{30}}\frac{1}{2}(a^2 + x^2 )^{ - 1/2} (2x) - \frac{1}{{60}}<br /> \]<br />
where'd that 2x come from? isn't the derivative of \[<br /> \sqrt {a^2 + x^2 } <br /> \] just \[<br /> \frac{1}{2}(a^2 + x^2 )^{ - 1/2} <br /> \]?
thanks
Last edited:
. o well, haha thanks.
