Author Topic: VCE Methods Question Thread! (Read 5714990 times) Tweet Share

PsychoM · « **Reply #1380 on:** December 31, 2012, 06:20:29 pm »

Quote from: polar on December 29, 2012, 06:13:24 pm

Consider a right-angled triangle:

$\begin{aligned} \frac{\pi}{2} + \sin^{-1}(x) + \cos^{-1}(x) &= \pi \; \; \; \; \; \; \; \; (\text{Angles add up to} \; \pi \; \text{in a triangle}) \\ \sin^{-1}(x) &= \frac{\pi}{2} - \cos^{-1}(x) \\ \text{Let \;} \sin^{-1}(x) &= \theta, \; x= \sin(\theta) \\ \theta &= \frac{\pi}{2} - \cos^{-1}(x) \\ \cos^{-1}(x) &= \frac{\pi}{2} - \theta \\ x &= \cos(\frac{\pi}{2} - \theta) \\ \sin(\theta) &= \cos(\frac{\pi}{2} - \theta) \end{aligned}$

Why haven't I learn this before? Is it from yr 12 methods?
Thanks everyone for the explanation but only get some bit and not all.

EDIT: I have another question.

T=22 + 3 sin $\frac{\pi t}{12}$
a) What is the amplidute? and the highest y value and lowest y value(what is it called)
b) can u find the period from this equation? or u need a domain : 0<(equal to) t< (equal to) 24. Btw how do u put equal to/larger than together as a symbol?
c) Find the time(s) when the temperature is 20.5.

Thanks

polar · « **Reply #1381 on:** December 31, 2012, 07:40:14 pm »

Quote from: PsychoM on December 31, 2012, 06:20:29 pm

Why haven't I learn this before? Is it from yr 12 methods?
Thanks everyone for the explanation but only get some bit and not all.

the angles in a triangle add up to 180 degrees - which is the same as $\pi$ in radians, the 3 angles in a right-angled triangle are equal to $\sin^{-1}(x), \cos^{-1}(x)$ and $\frac{\pi}{2}$ . after adding them up, you just move a few things around to get to the final answer. you don't really need to prove formulas in methods though, so don't worry about it too much. it's more important to know the formula and how to use it.

Quote from: PsychoM on December 31, 2012, 06:20:29 pm

T=22 + 3 sin $\frac{\pi t}{12}$
a) What is the amplidute? and the highest y value and lowest y value(what is it called)
b) can u find the period from this equation? or u need a domain : 0<(equal to) t< (equal to) 24. Btw how do u put equal to/larger than together as a symbol?
c) Find the time(s) when the temperature is 20.5.
Thanks

(a) amplitude is 3, $T_{max} = 22+3=25, T_{min} = 22-3=22$

(b) the period of an a sinusoidal function ( $y=a\cos(bx+c)+d, y=a\sin(bx+c)+d$ ) is $\frac{2\pi}{b}$ , in this case $b = \frac{\pi}{12}$ thus,
$T= \frac{2\pi}{\frac{\pi}{12}} = 24$

in latex, the less or equal to sign is \le or \leq.
more information on latex: Re: Logs help

(c) by hand:
$\begin{aligned} 22 + 3\sin(\frac{\pi{t}}{12}) &= 20.5 \\ \sin(\frac{\pi{t}}{12}) &= -\frac{1}{2} \\ \frac{\pi{t}}{12} &= \pi + \frac{\pi}{6}, 2\pi - \frac{\pi}{6} \\ &= \frac{7\pi}{6}, \frac{11\pi}{6} \\ t &= \frac{7\pi}{6}\times\frac{12}{\pi}, \frac{11\pi}{6}\times\frac{12}{\pi} \\ t &= 14, 22 \end{aligned}$

using a CAS:
$\text{solve}(22 + 3\sin(\frac{\pi}{12}t) = 20.5|0\le t \le 24, t)$

darklight · « **Reply #1382 on:** January 02, 2013, 01:09:11 pm »

Hi, I'm not sure how to write maths symbols on the forum so hopefully this is understandable. It's question 3 from chapter 9 extended response, essentials maths book.

f(x)= (x-a)^n (x-b)^m where m and n are positive integers with m>n and b>a.

Find f'(x). I tried using product rule but it didn't seem to work...

polar · « **Reply #1383 on:** January 02, 2013, 01:13:50 pm »

Quote from: darklight on January 02, 2013, 01:09:11 pm

Hi, I'm not sure how to write maths symbols on the forum so hopefully this is understandable. It's question 3 from chapter 9 extended response, essentials maths book.

f(x)= (x-a)^n (x-b)^m where m and n are positive integers with m>n and b>a.

Find f'(x). I tried using product rule but it didn't seem to work...

$\begin{aligned} \frac{d}{dx}\left((x-a)^n(x-b)^m\right) &= (x-a)^n\frac{d}{dx}\left((x-b)^m\right) + (x-b)^m\frac{d}{dx}\left((x-a)^n\right) \\ &=(x-a)^n\times{m}(x-b)^{m-1} + (x-b)^m \times{n}(x-a)^{n-1} \\ &= (x-a)^{n-1}(x-b)^{m-1}\times{m(x-a)} + (x-a)^{n-1}(x-b)^{m-1}\times{n(x-b)} \; (\text{Finding the common factor}) \\ &= (x-a)^{n-1}(x-b)^{m-1}(m(x-a) + n(x-b)) \\ &= (x-a)^{n-1}(x-b)^{m-1}(mx - an + nx - bn) \\ &= (x-a)^{n-1}(x-b)^{m-1}((m+n)x - am - bn) \end{aligned}$

darklight · « **Reply #1384 on:** January 02, 2013, 01:23:20 pm »

See I got up to line 2 as well, but I don't get the simplyifing part. :S
Why is it m(x-a) shouldn't it be n(x-a)? And m(x-b) not n(x-b)?

polar · « **Reply #1385 on:** January 02, 2013, 01:24:36 pm »

Quote from: darklight on January 02, 2013, 01:23:20 pm

See I got up to line 2 as well, but I don't get the simplyifing part. :S
Why is it m(x-a) shouldn't it be n(x-a)? And m(x-b) not n(x-b)?

the m in m(x-a) is from the derivative of (x-b)^m

darklight · « **Reply #1386 on:** January 02, 2013, 01:36:14 pm »

Quote from: polar on January 02, 2013, 01:24:36 pm

the m in m(x-a) is from the derivative of (x-b)^m

Ahh, I get it now! Thanks so much

darklight · « **Reply #1387 on:** January 02, 2013, 01:59:49 pm »

Quote from: darklight on January 02, 2013, 01:09:11 pm

Hi, I'm not sure how to write maths symbols on the forum so hopefully this is understandable. It's question 3 from chapter 9 extended response, essentials maths book.

f(x)= (x-a)^n (x-b)^m where m and n are positive integers with m>n and b>a.

Find f'(x). I tried using product rule but it didn't seem to work...

With much excitement I tried to answer the next few parts and got stuck again.

If m and n are odd, find the set of values for which f'(x) > 0. I got the answer by simply subbing in the derivative into the inequality, but didn't take into account the m and n are odd bit. What effect does this have?

For the second part, if m is odd and n is even find the set of values for f'(x) > 0, you can't just sub it into the inequality because the answers are different...

polar · « **Reply #1388 on:** January 02, 2013, 04:24:03 pm »

Quote from: darklight on January 02, 2013, 01:59:49 pm

With much excitement I tried to answer the next few parts and got stuck again.

If m and n are odd, find the set of values for which f'(x) > 0. I got the answer by simply subbing in the derivative into the inequality, but didn't take into account the m and n are odd bit. What effect does this have?

For the second part, if m is odd and n is even find the set of values for f'(x) > 0, you can't just sub it into the inequality because the answers are different...

$f'(x) = 0 \; \text{for} \; x= \alpha, \beta, \frac{\alpha{m} + \beta{n}}{m+n}$

drawing graphs (or substituting values of $m,n, \alpha$ and $\beta$ for similar shapes) and then looking at which parts have a positive gradient make the next part easier:

m odd, n odd (graph has similar shape to $y=(x-3)^3(x-5)^5$ )
the function $f(x) = (x-\alpha)^n(x-\beta)^m$ would have stationary points of inflection at $x= \alpha, \beta$ and since the degree of the polynomial is even, $x=\frac{\alpha{m} +\beta{n}}{m+b}$ is a local maximum. hence, $f'(x) > 0 \; \text{for} \; x \in \left(\frac{\alpha{m} + \beta{n}}{m+n}, \infty\right)\setminus\{\beta\}$

m odd, n even (graph has similar shape to $y=(x-3)^2(x-5)^5$ )
by looking at the graph, there is a stationary point of inflection at $x = \beta$ , a local maximum at $x = \alpha$ and a local minimum at $x = \frac{\alpha{m} + \beta{n}}{m+n}$ and hence, $f'(x) > 0 \; \text{for} \; x \in (-\infty,\alpha) \cup \left(\frac{\alpha{m} + \beta{n}}{m+n},\infty\right)\setminus\{\beta\}$

in general, if $n \ge 2$ :
$y=(x-a)^n$ has a stationary point of inflection of n is odd, and a turning point if n is even

darklight · « **Reply #1389 on:** January 02, 2013, 05:26:53 pm »

You, my friend, are a genius! It seems so simple now, thanks for the help.

KevinooBz · « **Reply #1390 on:** January 02, 2013, 06:33:32 pm »

AB is one side of a regular n-sided polygon that circumscribes a circle, i.e. each edge of the polygon is tangent to the circle. The circle has a radius of 1.
Show that the area of the triangle OAB is tan(pi/n)
(O is the centre of the circle, can't post up the diagram)

BubbleWrapMan · « **Reply #1391 on:** January 02, 2013, 06:44:51 pm »

I feel like giving my take on this since it's an interesting question. Starting with $m$ and $n$ both being odd:

$(x-a)^{n-1}(x-b)^{m-1}((m+n)x - am - bn)$

If $m$ and $n$ are both odd, then $(x-b)^{m-1}$ and $(x-a)^{n-1}$ are both raised to even powers and are therefore positive, except where they are zero, which is when $x=b$ or when $x=a$

For the linear factor, you can simply solve the inequality:

$(m+n)x - am - bn>0$

$\implies (m+n)x >am + bn$

$\implies x>\frac{am+bn}{m+n}$

So the derivative is positive provided $x>\frac{am+bn}{m+n}$ , $x\neq a$ and $x\neq b$

For the case where $n$ is instead even, the factor $(x-b)^{m-1}$ is still positive except where $x=b$

For the remaining two factors, they either need to be both positive, or both negative, for their product to be positive.

If they are both positive, we require that $x-a>0$ (since it is raised to an odd power, $n-1$ ) i.e. $x>a$ , and also that $x>\frac{am+bn}{m+n}$ , from solving the same inequality as before. So we require that $x$ is greater than the larger of $a$ and $\frac{am+bn}{m+n}$

Using the same method, if they are both negative, then $x<a$ and $x<\frac{am+bn}{m+n}$ , so $x$ must be less than the smaller of the two.

So overall we require that $\left( (-\infty,\mathrm{min}\left\{{a,\frac{am+bn}{m+n}\right\})\cup(\mathrm{max}\left\{{a,\frac{am+bn}{m+n}\right\},\infty)\right)\setminus \left\{b\right\}$ if $n$ is even and $m$ is odd

BubbleWrapMan · « **Reply #1392 on:** January 02, 2013, 06:51:17 pm »

Quote from: KevinooBz on January 02, 2013, 06:33:32 pm

AB is one side of a regular n-sided polygon that circumscribes a circle, i.e. each edge of the polygon is tangent to the circle. The circle has a radius of 1.
Show that the area of the triangle OAB is tan(pi/n)
(O is the centre of the circle, can't post up the diagram)

The polygon can be split up into $n$ isosceles triangles, and the angles where they all meet at the centre (which includes the angle $AOB$ ) are $\frac{2\pi}{n}$

Let $M$ be the midpoint of $AB$ . Then $OMB$ is a right-angled triangle, with the right angle at $M$ .

The angle $MOB$ is half the angle $AOB$ , so it is $\frac{\pi}{n}$

Hence, $\frac{MB}{OM}=\tan\left(\frac{\pi}{n}\right)$ , and since $OM=1$ , we have $MB=\tan\left(\frac{\pi}{n}\right)$

Since $MB$ is half the length of $AB$ , we have $AB=2\tan\left(\frac{\pi}{n}\right)$

So the area of the triangle $OAB$ is $\frac{1}{2}\times OM \times AB=\frac{1}{2}\times 1 \times 2\tan\left(\frac{\pi}{n}\right)=\tan\left(\frac{\pi}{n}\right)$ , as required

darklight · « **Reply #1393 on:** January 02, 2013, 08:53:00 pm »

A car travels half the distance of a journey at an average speed of 80km/hr and half at an average speed of x km/hr.

Define a function, S, which gives the average speed for the total journey as a function of x.

b^3 · « **Reply #1394 on:** January 02, 2013, 09:00:21 pm »

Let $d$ be the total distance of the journey.

$\begin{alignedat}{1}s & =\frac{d}{t} \\ t & =\frac{d}{s} \\ t_{1} & =\frac{d/2}{80} \\ & =\frac{d}{160} \\ t_{2} & =\frac{d/2}{x} \\ & =\frac{d}{2x} \\ t_{total} & =t_{1}+t_{2} \\ & =\frac{d}{160}+\frac{d}{2x} \\ & =\frac{dx}{160x}+\frac{80d}{160x} \\ & =\frac{d\left(x+80\right)}{160x} \\ S_{avg} & =\frac{d_{total}}{t_{total}} \\ & =d\div\frac{d\left(x+80\right)}{160x} \\ & =d\times\frac{160x}{d\left(x+80\right)} \\ & =\frac{160x}{x+80} \end{alignedat} $

EDIT: Fixed the minor screw up

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