This is actually quite interesting, reminds me of something called inversion:Li0n said:
http://whistleralley.com/inversion/inversion.htm
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Non HSC Maths Marathon (1 Viewer)
- Thread starter acmilan
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http://whistleralley.com/inversion/inversion.htm
KeypadSDM
B4nn3d
This shouldn't be allowed, it's a 4-unit question. [Saw it in a '98 past paper, I can't find it right now though...]Li0n said:
vulgarfraction
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7 cubes can be added to the total number by dividing any existing cube into 8. Just prove it's possible for all remainders modulo 7 for a value equal to the lowest number of that remainder above/equal to 100.Affinity said:
You start off with 1 cube, and can add 7, 26, 63, 124 etc. You can also 'remove' 7, 26, etc cubes by refraining from cutting them when you're creating a larger number.
Congruent to (mod 7):
0: 105 = 63+ 6*7
1: 106 = 3*26 + 4*7
2: 100 = 27 + 2*26 + 3*7
3: 101 = 64 + 63 - 26
4: 102 = 27 + 26 + 7*7
5: 103 = 64 + 63 - 26 - 26 + 4*7
6: 104 = 64 + 26 + 2*7
KeypadSDM
B4nn3d
Assume they're both rational:acmilan said:
Note: e - pi = (e+pi)-2pi, hence trancendental (as pi is trancendental)
(e + pi)^2 - 4*e*pi = rational = (e - pi)^2
But as e - pi is trancendental, it's not the root of a rational polynomial
Hence (e - pi)^2 is also trancendental, and hence irrational.
Thus at least one of e + pi and e*pi is irrational.
Is there an easier way which just uses e&pi being irrational rather than trancendental?
KeypadSDM
B4nn3d
Ahh, very nice. Solutions to algebraic polynomials are themselves algebraic. Hence, since the roots are trancendental, the polynomial cannot be algebraic.
KeypadSDM
B4nn3d
I don't believe there's a simple way, so I'll just go ahead and do it the hard way.LottoX said:
Prove Gelfond's theorem over the complex domain.
Hence (-1)<sup>-i</sup> = e<sup>pi</sup> is irrational.
KeypadSDM
B4nn3d
It makes the most sense to do it this way, though. As the proof for a<sup>b</sup> being trancendental, except when it trivially isn't, is so well known, I feel it's a valid solution.
KeypadSDM
B4nn3d
Alright, I can't be arsed making a cool question up, so I'll just do a boring one.
Prove that given any 3 dimensional body, with arbitrary mass distribution, there is a set of coordinate axes which when defined around the centre of mass of the 3-d body such that one of the axes points in the direction of least moment of inertia, and one of the axes points in the direction of highest moment of inertia.
The x,y,z axes you use must be orthogonal.
The hint might be completely talking out of my ass. I don't actually know.
Prove that given any 3 dimensional body, with arbitrary mass distribution, there is a set of coordinate axes which when defined around the centre of mass of the 3-d body such that one of the axes points in the direction of least moment of inertia, and one of the axes points in the direction of highest moment of inertia.
The x,y,z axes you use must be orthogonal.
I'm not sure if this is correct but maybe:
Start with a generalised tensor for the moments of inertia about an arbitrary set of axes:
[Ixx,Ixy,Ixz]
[Iyx,Iyy,Iyz]
[Izx,Izy,Izz]
And diagonalise
Start with a generalised tensor for the moments of inertia about an arbitrary set of axes:
[Ixx,Ixy,Ixz]
[Iyx,Iyy,Iyz]
[Izx,Izy,Izz]
And diagonalise
The hint might be completely talking out of my ass. I don't actually know.
Li0n
spiKu
Err, well firstly i didn't do 4unit. And like i said i pulled it out of my complex analysis question booklet. Peter Brown (who sets questions for 2520/2620)writes 4-unit questions too afaik.KeypadSDM said:
KeypadSDM
B4nn3d
Score, that means I'm right about how to figure out the values.Affinity said: