The discussion focuses on finding the derivatives of two functions: f(s) = [(√s) - 1]/[(√s) + 1] and v = (1 + x - 4√x)/x. The correct derivative for f(s) is f'(s) = 1/[√s(√s + 1)^2], while for v, the book provides v' = -1/x^2 + 2x^(-3/2). Participants emphasize the importance of using LaTeX for clarity in mathematical expressions and suggest simplifying expressions before differentiation to ease the process.
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SteamKing said:Your attempt at finding the derivative apparently consists of re-writing f(s) and replacing the square root signs with exponents.
Do you know how to take the derivative of this function: f(s) = s^(1/2)?
TommG said:yes I do. I deleted my attempt because I don't think I can write it well enough so people can understand it. Is it ok if I post a pic of it?
TommG said:Well I figured out this problem but need help with another.
Thanks ray for the advice.
I could use help with a new problem.
Have to find the derivative.
v = \frac {1 + x - 4\sqrt{x}} x
My attempt
v = \frac {1 + x - 4\sqrt{x}} {x}
v = \frac {x(1-\frac{2}{√x}) - (1+x -4 √x)}{x^2}
v = \frac {x-\frac{2x}{√x} -1-x +4 √x}{x^2}
v = \frac {-\frac{2x}{√x} -1- +4 √x}{x^2} don't know where to go from here
answer in book is v' = \frac {-1}{x^2}+ 2x ^{-3/2}
Ray Vickson said:You are doing it the hard way (and I have not checked your work). It is much easier to expand out ##v## and so write
v = \frac {1 + x - 4\sqrt{x}}{ x} = \frac{1}{x} + 1 - \frac{4}{\sqrt{x}} = x^{-1} + 1 - 4 x^{-1/2}
and then differentiate each term separately. If you want, you can re-combine the results in the end.
BTW: in "\ frac{ } " you forgot the second { } (so you had "\ frac {y} x " instead of "\ frac {y}{x}". I am surprised it worked at all, but it does, as shown by the following test ##\frac{y}x##. Nevertheless, you should NEVER forget that final {} because if you have something more than one letter it won't work: "\ frac{y}x\sin(x) " produces ##\frac{y}x\sin(x)## instead of the wanted ##\frac{y}{x \sin(x)}##.
Interestingly, if you have just one letter in the numerator and in the denominator, you don't need braces at all:Ray Vickson said:BTW: in "\ frac{ } " you forgot the second { } (so you had "\ frac {y} x " instead of "\ frac {y}{x}". I am surprised it worked at all, but it does, as shown by the following test ##\frac{y}x##. Nevertheless, you should NEVER forget that final {} because if you have something more than one letter it won't work: "\ frac{y}x\sin(x) " produces ##\frac{y}x\sin(x)## instead of the wanted ##\frac{y}{x \sin(x)}##.
##\frac a b##TommG said:I have to do it the hard way.
I have to follow the derivative quotient rule.
Still need help if anyone could help out.
Ray Vickson said:(1) Why must you do it the hard way? Where in the original question does it tell you that?
(2) Why did you put everything over a common denominator? The quotient rule says that
\left( \frac{u}{v} \right)' = \frac{u'}{v} - \frac{u v'}{v^2}
but you wrote
\left( \frac{u}{v} \right)' = \frac{u' v - u v'}{v^2}
for no good reason that I can see. It is correct but unnecessary.
(3) You should combine and simplify your previous final answer.
(4) The book's answer does NOT involve a common denominator, so you need to 'undo' your final answer, or else re-write the book's answer in a form similar to yours, so you can compare the two.
Surely you know that \frac{x}{\sqrt{x}}= \sqrt{x}?TommG said:Well I figured out this problem but need help with another.
Thanks ray for the advice.
I could use help with a new problem.
Have to find the derivative.
v = \frac {1 + x - 4\sqrt{x}} x
My attempt
v = \frac {1 + x - 4\sqrt{x}} x
v = \frac {x(1-\frac{2}{√x}) - (1+x -4 √x)}{x^2}
v = \frac {x-\frac{2x}{√x} -1-x +4 √x}{x^2}
v = \frac {-\frac{2x}{√x} -1- +4 √x}{x^2} don't know where to go from here
answer in book is v' = \frac {-1}{x^2}+ 2x ^{-3/2}
The second equation is the quotient rule as it was taught to me.Ray Vickson said:The quotient rule says that
\left( \frac{u}{v} \right)' = \frac{u'}{v} - \frac{u v'}{v^2}
but you wrote
\left( \frac{u}{v} \right)' = \frac{u' v - u v'}{v^2}
Yup! (I agree with Fredrik -- if anyone cares.)Fredrik said:The second equation is the quotient rule as it was taught to me.