HSC Mathematics Marathon (1 Viewer)

apollo1 · Oct 21, 2011

largarithmic said:
you mean |x| < 1, negative values of x and zero still work

to make sure the GP converges, do it like this:

$S_n = 1+xcis(x)+x^2cis(2x)+...+x^ncis(nx) = \frac{1 - (xcisx)^n}{1-xcisx}$

So if we let $xcisx = z, S_n = \frac{1-z^n}{1-z}$
which converges as n->infinity if |z| < 1, and diverges if |z|>1. If |z|=1, i.e. x = 1 or -1, it neither converges nor diverges: it just sorta oscillates around the place (although, since 1 is not a rational multiple of pi, its not actually periodic but rather slightly chaotic). Clearly |z| = |x|, so it converges iff |x|<1, goes weird if |x| = 1 and diverges if |x| > 1.

Cool question!

EDIT: oh wait I kinda messed it up because I showed the cis sum diverges, not Re(cissum). Its pretty easy to do that though I think:

$S_n = Re\left(\frac{1-x^n(cos(nx)+isin(nx))}{1-x(cosx+isinx)}\right) = \frac{(1-x^ncos(nx))(1-xcosx)+x^{n+1}sinxsin(nx)}{(1-xcosx)^2+x^2sin^2x} = \frac{1-xcosx+x^n(xcos((n-1)x)-cos(nx))}{1-2xcosx+x^2}$

Now note that as n goes to infinity, the demoninator remains the same while the numerator converges if |x|<1. For |x|>=1, its a lot more complicated but it certainly doesnt converge; it doesnt necessarily "increase without bound though", it sorta oscillates whilst "diverging" at the same time (I dont actually know the technical definition of diverging so yeah, in this case a function like xsinx diverges even though it has zeroes for arbitrarily large x)

wouldnt it be z^n+1 becuase there are n+1 terms?

largarithmic · Oct 21, 2011

apollo1 said:
can someone help me with this question:

Okay um do it like this: Let $L_n = \sqrt{n^2+n}-n$ .

We're given that this sequence has a limit, also clearly as $n < \sqrt{n^2+n} < n+\frac{1}{2}$ , L_n is always less than half, and it is also clearly always positive.

Now rearrange that equation there to be in terms of n:
$(L_n + n)^2 = n^2+n$
$L_n^2 + 2nLn = n$
$n = \frac{L_n^2}{1-2L_n}$

Now send n to infinity: if L_n goes to limit L where L is NOT equal to a half (and clearly 0 ≤ L ≤ 1/2 anyway), then the RHS has limit $\frac{L^2}{1-2L}$ which is a finite limit as L=/=2: by contrast the LHS obviously does not have a finite limit. You then require the limit to be half.

You can get rid of the question's assumption that there is a limit by proving that the Ln sequence is monotonic increasing (not too hard, start with L_n+1 > L_n, which would be true if an only if blahhh, which would be true if an only if blahhh, and each time you get rid of the squares so that you get down to a fourth degree polynomial inequation which after expanding out is true. You then know Ln is monotonic and its bounded as well from what I showed earlier, so it has a limit

largarithmic · Oct 21, 2011

apollo1 said:
wouldnt it be z^n+1 becuase there are n+1 terms?

crap yeah, doesnt really cahnge the content of the proof though (just replace n with n+1 where necessary)

largarithmic · Oct 21, 2011

seanieg89 said:
Exactly, and your mention of the chaotic nature of the partial sums for certain x brings up an interesting point...consider the same problem if you replace the series by:

$\sum_{k=1}^n\frac{\sin(kx)}{k}$

(Considerably harder than the geometric series case)

That questions pretty similar to finding the integral of (sinx)/x isnt it?

Trebla · Oct 21, 2011

I think you guys are scaring some students a little bit with hardcore questions which are highly unlikely to appear in the HSC...lol keep it relatively simple so ordinary students can participate

hup · Oct 21, 2011

Some Vunt · Oct 21, 2011

Trebla said:
I think you guys are scaring some students a little bit with hardcore questions which are highly unlikely to appear in the HSC...lol keep it relatively simple so ordinary students can participate

.

largarithmic · Oct 21, 2011

hup said:
$\\it\ is\ given\ that\\\\ cos\ k\theta =2cos\thetacos(k-1)\theta-cos(k-2)\theta\\\\ show\ that\\ \\ \cos2\theta=2\cos^2\ \theta-1\\ \cos3\theta=4\cos^3\ \theta-3\ \cos\theta\\ \cos4\theta=8\cos^4\theta -8\cos^2\theta+1\\\\ The\ T\ polynomials\ are\ defined\ by\ the\ recurrence\ formula \\\\ t_k(x)=2x\ t_{k-1}(x)-t_{k-2}(x)\\ t_0(x)=1\\ t_1(x)= x\\\\ Find \\\\ t_2(x),\\ t_3(x),\\ t_4(x).\\\\ Let\ F(z)\ be\ the\ infinite\ series\ in\ z\ , with\ coefficient\ of\ z^k\ being\ t_k(x): \\\\ F(z)=1+xz+(2x^2-1)z^2+(4x^3-3x)z^3+(8x^4-8x^2+1)z^4+...+t_k(x)z^k+.....\\\\ For\ z\ sufficiently\ small,\ derive\ the\ formula\ for\ F(z) ;\\\\ F(z)=\frac{1-xz}{1-2xz+z^2}$

did you send me this question in a pm at one point? (its a good question!) but what about its later parts

hup · Oct 21, 2011

largarithmic said:
did you send me this question in a pm at one point? (its a good question!) but what about its later parts

a bit different

largarithmic · Oct 21, 2011

hup said:
a bit different

oh okay you took out some of the help

SpiralFlex · Oct 22, 2011

New question,

Prove:

$\frac{1}{1-\cos \theta +2i \sin \theta}=\frac{1-2i \cot\frac{\theta}{2}}{5+3\cos \theta}$

I like maths · Oct 22, 2011

hup said:
$\\it\ is\ given\ that\\\\ cos\ k\theta =2cos\thetacos(k-1)\theta-cos(k-2)\theta\\\\ show\ that\\ \\ \cos2\theta=2\cos^2\ \theta-1\\ \cos3\theta=4\cos^3\ \theta-3\ \cos\theta\\ \cos4\theta=8\cos^4\theta -8\cos^2\theta+1\\\\ The\ T\ polynomials\ are\ defined\ by\ the\ recurrence\ formula \\\\ t_k(x)=2x\ t_{k-1}(x)-t_{k-2}(x)\\ t_0(x)=1\\ t_1(x)= x\\\\ Find \\\\ t_2(x),\\ t_3(x),\\ t_4(x).\\\\ Let\ F(z)\ be\ the\ infinite\ series\ in\ z\ , with\ coefficient\ of\ z^k\ being\ t_k(x): \\\\ F(z)=1+xz+(2x^2-1)z^2+(4x^3-3x)z^3+(8x^4-8x^2+1)z^4+...+t_k(x)z^k+.....\\\\ For\ z\ sufficiently\ small,\ derive\ the\ formula\ for\ F(z) ;\\\\ F(z)=\frac{1-xz}{1-2xz+z^2}$

I remember seeing this question earlier this year (perhaps in a past SGS trial?) it is dealing with Chebyshev polynomials which makes it an intrinsically excellent question but perhaps slightly divorced from the approximation theory/differential equations that make them important. Anyway you have made a copyist error, cos(kx)=2cos(x)cos((k-1)x)-cos((k-2)x)

hup · Oct 22, 2011

cutemouse · Oct 23, 2011

hup said:
$\int_{1}^{2}\frac{1}{x\ \sqrt[]{2x-1}}\ dx$

Use the subs. x=1/u ...

hup · Oct 23, 2011

cutemouse said:
Use the subs. x=1/u ...

thats painful
look for an easier substitution

AAEldar · Oct 23, 2011

Did this one the other day. Pretty sure there were 2 substitutions that I got to work, $u=\sqrt{2x-1}$ and $u=2x-1$ .

cutemouse · Oct 23, 2011

hup said:
thats painful
look for an easier substitution

Yeah you could do something like x=(1/2) sec^2 theta, I guess... although I haven't tried that way for this q...

hup · Oct 23, 2011

AAEldar said:
Did this one the other day. Pretty sure there were 2 substitutions that I got to work, $u=\sqrt{2x-1}$

this is good
if you have a surd on bottom letting u = surd makes it so that when you differentiate it it easily goes away

slyhunter · Oct 23, 2011

You can either use a trigonometric or algebraic substitution. I personally found letting $u^2=2x-1$ the easiest.

hup · Oct 23, 2011

expand $(2+i)(3+i)$

and deduce that

$\tan^{-1}\frac{1}{2}+\tan^{-1}\frac{1}{3}=\frac{\pi}{4}$

HSC Mathematics Marathon (1 Viewer)

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