MATH 221

Arun Ram
Department of Mathematics and Statistics
University of Melbourne
Parkville, VIC 3010 Australia
aram@unimelb.edu.au

Last updated: 6 September 2014

Lecture 37

Logarithmic differentiation

Sometimes it can simplify calculations to take the log of both sides before taking the derivative.

Find $\frac{d y}{d x}$ when $y = \frac{{(x + 2)}^{\frac{5}{2}}}{{(x + 6)}^{\frac{1}{2}} {(x + 3)}^{\frac{7}{2}}} .$ $\begin{matrix} ln y & = & ln (\frac{{(x + 2)}^{\frac{5}{2}}}{{(x + 6)}^{\frac{1}{2}} {(x + 3)}^{\frac{7}{2}}}) \\ = & ln {(x + 2)}^{\frac{5}{2}} - ln {(x + 6)}^{\frac{1}{2}} - ln {(x + 3)}^{\frac{7}{2}} \\ = & \frac{5}{2} ln (x + 2) - \frac{1}{2} ln (x + 6) - \frac{7}{2} ln (x + 3) . \end{matrix}$ So, by taking the derivative with respect to $x,$ $\frac{1}{y} \frac{d y}{d x} = \frac{5}{2} \frac{1}{(x + 2)} - \frac{1}{2} \frac{1}{(x + 6)} - \frac{7}{2} \frac{1}{(x + 3)} .$ So $\begin{matrix} \frac{d y}{d x} & = & y (\frac{5}{2} (\frac{1}{x + 2}) - \frac{1}{2} (\frac{1}{x + 6}) - \frac{7}{2} (\frac{1}{x + 3})) \\ = & \frac{{(x + 2)}^{52}}{{(x + 6)}^{\frac{1}{2}} {(x + 3)}^{\frac{7}{2}}} (\frac{5}{2} (\frac{1}{x + 2}) - \frac{1}{2} (\frac{1}{x + 6}) - \frac{7}{2} (\frac{1}{x + 3})) . \end{matrix}$

If $x^{m} y^{n} = {(x + y)}^{m + n}$ show that $\frac{d y}{d x} = y x .$

Take the log of both sides $ln (x^{m} y^{n}) = ln ({(x + y)}^{m + n}) .$ So $ln x^{m} + ln y^{n} = (m + n) ln (x + y) .$ So $m ln x + n ln y = (m + n) ln (x + y) .$ Take the derivative with respect to $x .$ $\frac{m}{x} + \frac{n}{y} \frac{d y}{d x} = (m + n) (\frac{1}{x + y}) (1 + \frac{d y}{d x}) .$ So $\frac{m}{x} + \frac{n}{y} \frac{d y}{d x} = \frac{m + n}{x + y} + (\frac{m + n}{x + y}) \frac{d y}{d x} .$ So $(\frac{n}{y} - \frac{m + n}{x + y}) \frac{d y}{d x} = \frac{m + n}{x + y} - \frac{m}{x} .$ So $(\frac{n x + n y - m y - n y}{y (x + y)}) \frac{d y}{d x} = \frac{m x + n x - m x - m y}{x (x + y)} .$ So $(\frac{n x - m y}{y}) \frac{d y}{d x} = \frac{n x - m y}{x} .$ So $\frac{d y}{d x} = \frac{y}{x} .$

Often the derivative can be done as usual.

Find $\frac{d y}{d x}$ when $y = a^{x} + e^{tan x} + {(cot x)}^{cos x} .$ $\begin{matrix} y & = & {(e^{ln a})}^{x} + e^{tan x} + {(e^{ln (cot x)})}^{cos x} \\ = & e^{x ln a} + e^{tan x} + e^{cos x ln (cot x)} . \end{matrix}$ So $\begin{matrix} \frac{d y}{d x} & = & e^{x ln a} ln a + e^{tan x} {sec}^{2} x + e^{cos x ln (cot x)} (\frac{cos x (- {csc}^{2} x)}{cot x} + (- sin x) ln (cot x)) \\ = & a^{x} ln a + e^{tan x} {sec}^{2} x + {(cot x)}^{cos x} (\frac{cos x \frac{- 1}{{sin}^{2} x}}{\frac{cos x}{sin x}} + (- sin x) ln (cot x)) \\ = & a^{x} ln a + e^{tan x} {sec}^{2} x + {(cot x)}^{cos x} (- csc x - sin x ln (cot x)) . \end{matrix}$

Find $\frac{d y}{d x}$ when $y = x^{x^{x^{⋰}}} .$

Then $y = x^{y} .$ So $y = {(e^{ln x})}^{y} = e^{y ln x} .$ So $\frac{d y}{d x} = e^{y ln x} \frac{d (y ln x)}{d x} = e^{y ln x} (\frac{y}{x} + \frac{d y}{d x} ln x) .$ So $\frac{d y}{d x} = \frac{y}{x} e^{y ln x} + ln x e^{y ln x} \frac{d y}{d x} .$ So $(1 - ln x e^{y ln x}) \frac{d y}{d x} = \frac{y}{x} x^{y} .$ So $\frac{d y}{d x} = \frac{\frac{y x^{y}}{x}}{1 - ln x \cdot x^{y}} = \frac{y x^{y}}{x (1 - x^{y} ln x)} .$

Motion

The main point is: If $s = distance$ traveled then $\frac{d s}{d t} = speed.$ Speed is the same thing as velocity and $\frac{d speed}{d t} = \frac{d velocity}{d t} = acceleration.$

A particle falls from the top of a tower and in the last second before it hits the ground it falls $\frac{9}{25}$ of the total height of the tower. Find the height of the tower.

Tower: $\begin{matrix} \end{matrix}$ Position of particle is ???
Acceleration of particle is $- 9.8 \frac{m}{s^{2}} .$
So $\frac{d v}{d t} = - 9.8 .$ So $d v = - 9.8 d t .$ So $\int d v = \int - 9.8 d t .$ So $v = - 9.8 t + c .$ Now $v$ at time $0$ is $0 .$ So $0 = - 9.8 \cdot 0 + c .$ So $c = 0$ and $v = - 9.8 t .$ Since $v = \frac{d s}{d t},$ $d s = v d t = - 9.8 t d t .$ So $\int d s = \int 0 9.8 t d t .$ So $s = - 9.8 \frac{t^{2}}{2} + c_{1} .$ At time $0,$ $s = H .$ So $H = - \frac{9.8}{2} \cdot 0^{2} + c_{1} .$ So $c_{1} = H .$ So $s = - \frac{9.8 t^{2}}{2} + H .$ The particle hits the ground when $s = 0 .$ $0 = - \frac{9.8}{2} t^{2} + H .$ So $\frac{9.8}{2} t^{2} = H .$ So $t^{2} = \frac{2 H}{9.8} = \frac{H}{4.9} .$ So $t = \sqrt{\frac{H}{4.9}} .$ So the particle hits the ground when $t = \sqrt{\frac{H}{4.9}} .$ One second before the particle hits the ground its height is $\frac{9}{25} H .$ So when $t = \sqrt{\frac{H}{4.9}} - 1,$ $s = \frac{9}{25} H .$ So $\frac{9}{25} H = - \frac{9.8}{2} {(\sqrt{\frac{H}{4.9}} - 1)}^{2} + H .$ So $\begin{matrix} \frac{9}{25} H & = & - 4.9 (\frac{H}{4.9} - \frac{2}{\sqrt{4.9}} \sqrt{H} + 1) + H \\ = & - H + 2 \sqrt{4.9} \sqrt{H} - 4.9 + H \\ = & 2 \sqrt{4.9} \sqrt{H} - 4.9 . \end{matrix}$ So $\frac{9}{25} H - 2 \sqrt{4.9} \sqrt{H} + 4.9 = 0 .$ So $\begin{matrix} \sqrt{H} & = & \frac{2 \sqrt{4.9} \pm \sqrt{{(2 \sqrt{4.9})}^{2} - \frac{4.9}{25} (4.9)}}{\frac{2.9}{25}} \\ = & \frac{2 \sqrt{4.9} \pm \sqrt{4 (4.9) - 4 (4.9) \frac{9}{25}}}{\frac{18}{25}} \\ = & \frac{2 \sqrt{4.9} \pm 2 \sqrt{4.9} \sqrt{\frac{16}{25}}}{\frac{18}{25}} \\ = & \frac{2 \sqrt{4.9} (1 \pm \frac{4}{5})}{\frac{18}{25}} \\ = & {\begin{matrix} \frac{\sqrt{4.9} \frac{9}{5}}{\frac{9}{25}} \\ \frac{\sqrt{4.9} \frac{1}{5}}{\frac{9}{25}} \end{matrix} \\ = & {\begin{matrix} 5 \sqrt{4.9} \\ or \\ \frac{5}{9} \sqrt{4.9} \end{matrix} . \end{matrix}$

Notes and References

These are a typed copy of Lecture 37 from a series of handwritten lecture notes for the class MATH 221 given on December 8, 2000.

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