BOS Trials 2013 Extension 2 Discussion Thread (2 Viewers)

RealiseNothing · Oct 4, 2013

c) iii) This is just an integration by parts, I won't go through most of the working out as it is just straight forward IBP. However:

$I_{2n-1} = \lim_{a \to 0} \int_{a}^{\pi} \frac{x}{2} \frac{\sin(\frac{(4n-1)x}{2})}{\sin(\frac{x}{2})} dx$

Let $u = \frac{\frac{x}{2}}{\sin(\frac{x}{2})}}$ and thus $u' = g(x)$ (given)

Let $v' = \sin(\frac{(4n-1)x}{2})$ and thus $v = \frac{-cos(\frac{(4n-1)x}{2})}{\frac{(4n-1)}{2}}$

Put these into the IBP formula and evaluate the $uv$ , then factor out $\frac{2}{(4n-1)}$ to obtain the result of:

$I_{2n-1} = \frac{2}{(4n-1)}[1+ \lim_{a \to 0} \int_{a}^{\pi} g(x) \cos(\frac{(4n-1)x}{2}) dx]$

c)iv) Now we know that $-1 \leq \cos(\theta) \leq 1$ , hence we can deduce that:

$\lim_{a \to 0} \int_{a}^{\pi} -g(x) dx \leq \lim_{a \to 0} \int_{a}^{\pi} g(x) \cos(\frac{(4n-1)x}{2}) dx \leq \lim_{a \to 0} \int_{a}^{\pi} -g(x) dx$

Evaluating the upper and lower bounds gives:

$[\frac{\frac{-x}{2}}{\sin(\frac{x}{2})}] \leq \lim_{a \to 0} \int_{a}^{\pi} g(x) \cos(\frac{(4n-1)x}{2}) dx \leq [\frac{\frac{x}{2}}{\sin(\frac{x}{2})}]$

Now we know that $\lim_{a \to 0} \frac{\frac{a}{2}}{\sin(\frac{a}{2})} = 1$ so we evaluate using the limits and we get the required result:

$1 - \frac{\pi}{2} \leq \lim_{a \to 0} \int_{a}^{\pi} g(x) \cos(\frac{(4n-1)x}{2}) dx \leq \frac{\pi}{2} - 1$

c)v) As $n \to \infty$ we get $\frac{2}{4n-1} \to 0$ .

Now as we established above, $\lim_{a \to 0} \int_{a}^{\pi} g(x) \cos(\frac{(4n-1)x}{2} dx$ is a finite as it is bounded between two finite values.

Thus $I_{2n-1} \to 0$

c)vi) We know now that as $n \to \infty$ we get $\frac{1}{2} I_{2n-1} \to 0$ and so from part c)ii) we get:

$lim_{n \to \infty} \sum_{k=1}^{n} \frac{1}{(2k-1)^2} = \frac{\pi^2}{8}$

Also we have:

$\sum_{k=1}^{\infty} \frac{1}{k^2} = {\sum_{k=1}^{\infty} \frac{1}{(2k-1)^2}} + \sum_{k=1}^{\infty} \frac{1}{(2k)^2}$

Substituting in our known value for the sum of the reciprocal odd squares, and factorising out a quarter from the last summation gives:

$\sum_{k=1}^{\infty} \frac{1}{k^2} = \frac{\pi^2}{8} + \frac{1}{4} \sum_{k=1}^{\infty} \frac{1}{k^2}$

$\frac{3}{4} \sum_{k=1}^{\infty} \frac{1}{k^2} = \frac{\pi^2}{8}$

$\sum_{k=1}^{\infty} \frac{1}{k^2} = \frac{\pi^2}{6}$

Sy123 · Oct 4, 2013

RealiseNothing said:
b) $\int_0^\pi x\cos(kx) dx$

Let $u=x$ so $u' = 1$ and $v' = \cos(kx)$ and $v = \frac{\sin(kx)}{k}$

$= [\frac{x\sin(kx)}{k}] - \int_0^\pi \frac{\sin(kx)}{k} dx$

Now the first part is 0 and so we get:

$= [\frac{\cos(kx)}{k^2}]$ from $0 ~$to$~ \pi$

$= \frac{(-1)^k - 1}{k^2}$

c)i) Let $I_n = \lim_{a \to 0} \int_0^\pi \frac{x\sin(\frac{(2n+1)x}{2})}{2\sin(\frac{x}{2})} dx$

From part a)ii) we get:

$I_n = \lim_{a \to 0} \int_0^\pi \frac{x}{2} + \sum_{k=1}^{n} x\cos(kx) dx$

$I_n = [\frac{x^2}{4}] + \sum_{k=1}^{n} [\frac{(-1)^k - 1}{k^2}]$

Substituting in the limits for the first part gives the required result of:

$I_n = \frac{\pi^2}{4} + \sum_{k=1}^{n} [\frac{(-1)^k - 1}{k^2}]$

c)ii) Simply let $n \to 2n-1$

$I_{2n-1} = \frac{\pi^2}{4} + \sum_{k=1}^{2n-1} [\frac{(-1)^{2k-1} - 1}{(2k-1)^2}]$

But note that $(-1)^{2k-1} = -1$

$I_{2n-1} = \frac{\pi^2}{4} + \sum_{k=1}^{2n-1} [\frac{-2}{(2k-1)^2}]$

Divide everything by $\frac{1}{2}$ and take out the minus sign from the summation yields the result:

$\frac{1}{2}I_{2n-1} = \frac{\pi^2}{8} - \sum_{k=1}^{2n-1} [\frac{1}{(2k-1)^2}]$

I think there is a mistake here, when you do:

$I_{2n-1} = \frac{\pi^2}{4} + \sum_{k=1}^{2n-1} \frac{(-1)^{2k-1} - 1}{(2k-1)^2}$

The 'summand' value isn't correct, it should be:

$I_{2n-1} = \frac{\pi^2}{4} + \sum_{k=1}^{2n-1} \frac{(-1)^k - 1}{k^2}$

Then, when you sum the series out, all the even k cancel out, which leaves us with sum from k=1 to n 1/(2k-1)^2

So Makematics there isn't a typo there.

RealiseNothing · Oct 4, 2013

Sy123 said:
I think there is a mistake here, when you do:

$I_{2n-1} = \frac{\pi^2}{4} + \sum_{k=1}^{2n-1} \frac{(-1)^{2k-1} - 1}{(2k-1)^2}$

The 'summand' value isn't correct, it should be:

$I_{2n-1} = \frac{\pi^2}{4} + \sum_{k=1}^{2n-1} \frac{(-1)^k - 1}{k^2}$

Then, when you sum the series out, all the even k cancel out, which leaves us with sum from k=1 to n 1/(2k-1)^2

So Makematics there isn't a typo there.

Yep it isn't a typo (the top of the summation should be 'n', my bad I typed it up wrong).

I did what you are saying in the actual exam yesterday, but when I was talking to carrot about it afterwards he said just substituting it in like that will work.

Edit: Now that I think about it, maybe carrot was saying the exact same thing we both did, I just misinterpreted what he said. I'll fix it now anyway.

Carrotsticks · Oct 4, 2013

Realise, just to point out a small thing. You said that since it is bounded by two finite values, it is finite. The sine function is a basic counter example.

RealiseNothing · Oct 4, 2013

Carrotsticks said:
Realise, just to point out a small thing. You said that since it is bounded by two finite values, it is finite. The sine function is a basic counter example.

What would be a better way to explain why it is finite then?

RealiseNothing · Oct 4, 2013

Carrotsticks said:
Realise, just to point out a small thing. You said that since it is bounded by two finite values, it is finite. The sine function is a basic counter example.

Oh right, it is still finite, just not a finite value. It's just a problem with the wording right.

seanieg89 · Oct 5, 2013

If anyone needs solutions to a couple of particular questions before Carrot and Trebla release their official solutions, I am willing to write mine up.

hit patel · Oct 5, 2013

asianese · Oct 5, 2013

I am really interested in seeing the actual HSC paper this year after this bomb of a paper.

cutemouse · Oct 10, 2013

I don't think Q11(c) is really in the syllabus because it involves mappings (although it can be done by arguments/circle geom as well). I think, in fact, the syllabus explicitly excludes these types of locus questions.

Carrotsticks · Oct 13, 2013

cutemouse said:
I don't think Q11(c) is really in the syllabus because it involves mappings (although it can be done by arguments/circle geom as well). I think, in fact, the syllabus explicitly excludes these types of locus questions.

Not quite sure what you mean by involving mappings. Mappings (rotational, scaling etc) are most certainly in the syllabus. The problem does indeed require the substitution w=1/z, but students need not understand the concept of a mapping. They just need to know that |w|=|w-k| yields a straight line, which is most certainly in the syllabus as a standard locus problem. Once w=1/z is made (which is a fairly intuitive substitution to make), the rest is just complex number algebra and manipulations.

The following is taken from the syllabus:

That is very clearly a mapping of the unit circle (which is a curve, notice in my exam that we are merely mapping points, which is def. in the syllabus) via a Mobius transform.

tl;dr the syllabus 'forbids' mappings of curves -> curves, but it allows mappings points -> points, which is what Q11(c) was.

asianese · Oct 15, 2013

Lol. This paper.

Carrotsticks · Oct 17, 2013

Results and full solutions being released tonight!

asianese · Oct 17, 2013

Lookin' forward.

Makematics · Oct 17, 2013

I think i came last for 2u...

Carrotsticks · Oct 17, 2013

About half an hour or so left! Sorry for the delays!

cutemouse · Oct 17, 2013

Carrotsticks said:
Not quite sure what you mean by involving mappings.

I meant complex maps.

I still think there's serious question as to whether it is in the syllabus or not.

Anyway, isn't mapping curves -> curves the same thing as mapping points -> points? I.e. In the former case aren't we mapping the points of a curve to another point of a curve etc? Oo

ForOneEon · Oct 17, 2013

Oh boy, test scores ahoy!

Chlee1998 · Jan 21, 2015

What did Fus roh dah get for this paper?

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BOS Trials 2013 Extension 2 Discussion Thread (2 Viewers)

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