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HSC 2015 MX2 Marathon ADVANCED (archive) (4 Viewers)

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abecina

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Re: HSC 2015 4U Marathon - Advanced Level

Hi seanieg89. I can get some sort of induction argument going, but was wondering if there is a proof by contradiction. It seems just right for one!?
 

seanieg89

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Re: HSC 2015 4U Marathon - Advanced Level

Hi seanieg89. I can get some sort of induction argument going, but was wondering if there is a proof by contradiction. It seems just right for one!?
I think my method was an induction, but might have involved contradiction in proving one of the steps.

Not sure about whether or not you can avoid induction.
 

simpleetal

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Re: HSC 2015 4U Marathon - Advanced Level

Assuming that the symbol means "for x between and including 0, and 1", I get an integer answer. Is it an integer answer? I'd like post my solution, but only if I'm sure that there's no sillies.
 

Trebla

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Re: HSC 2015 4U Marathon - Advanced Level

I think this question is beyond the Ext2 course (the whole idea of convex sets and the intersections of such sets).
 

seanieg89

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Re: HSC 2015 4U Marathon - Advanced Level

sorry but can you explain what the question is asking for? I don't know what that last symbol is supposed to mean.
Do you understand the definition of a convex set in the first sentence?

Then the second sentence is just asking:

If we have a finite collection of convex sets in the plane such that any three sets from this collection share a common point, then show that there exists a point common to ALL of the sets in this collection.
 

Sy123

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Re: HSC 2015 4U Marathon - Advanced Level

 

seanieg89

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Re: HSC 2015 4U Marathon - Advanced Level

This is only necessarily true if:
a) The polynomial has real coefficients. (Otherwise any three different complex numbers with the same imaginary part can be non-real roots of a polynomial with positive .)
b) The polynomial has distinct roots. (If any roots have multiplicity > 1, then . Still, all roots will be real in this case).

Under these assumptions, we now prove your claim.

The only if is trivial.

Now suppose such a cubic has not all roots real. As non-real roots come in conjugate pairs, we must have roots for some real and some non-real .
So



So any cubic polynomial with positive must have all roots real and distinct.

Interesting point: The obvious generalisation of this quantity alone doesn't tell us whether the roots are all real if we are talking about higher degree polynomials! (Eg for a quartic, you can have two pairs of conjugate roots, and so two negative terms in with positive product.) A potentially fun challenge problem is to construct a quantity in terms of a monic quartic's coefficients (maybe assume that the ^3 coefficient is zero to simplify the calculations. this can be arranged by a linear substitution anyway) that is positive if and only if it's roots are distinct reals.
 
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glittergal96

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Re: HSC 2015 4U Marathon - Advanced Level

Let

(Note that the evaluation at any three points uniquely determines a polynomial of degree <= 2, and that the conditions of the question imply that ).

Solving the resulting simultaneous equations gives a,b,c in terms of the .

We get





Now the triangle inequality tells us




So , and we can obtain equality with , that is for example.
 

glittergal96

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Re: HSC 2015 4U Marathon - Advanced Level

Okay, so let be the claim for a given positive integer .

Let's assume that we know and for some .

Then we will show that is true.

To see this, let be such a collection of convex sets.

Then write As the intersection of two convex sets is convex (I can write a separate proof for this if its not obvious enough for me to assume), we have that is a collection of convex sets.

Moreover, for any distinct , we have
where the last inequality follows from and our assumption that every triple of sets from has a common element.

In other words we have shown that every triple of sets from has a common point.

From we conclude that , which is precisely the statement .

This reduces the problem to proving , which can be tackled geometrically. I will do this in a separate post now to make the whole proof more readable.
 

glittergal96

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Re: HSC 2015 4U Marathon - Advanced Level

Suppose were not true.

Then given such convex sets , we could find distinct points in the plane such that is only in the three sets that AREN'T .

But any four points in the plane define a unique convex quadrilateral Q.

Without loss of generality suppose this quadrilateral has vertices in anti-clockwise order.

Then by convexity, the diagonal lies in and the diagonal lies in .

As the diagonals of a convex quadrilateral intersect, that means the point of intersection of these diagonals must lie in every .

This completes the proof of , and hence the whole problem.
 

Chlee1998

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Re: HSC 2015 4U Marathon - Advanced Level

Suppose were not true.

Then given such convex sets , we could find distinct points in the plane such that is only in the three sets that AREN'T .

But any four points in the plane define a unique convex quadrilateral Q.

Without loss of generality suppose this quadrilateral has vertices in anti-clockwise order.

Then by convexity, the diagonal lies in and the diagonal lies in .

As the diagonals of a convex quadrilateral intersect, that means the point of intersection of these diagonals must lie in every .

This completes the proof of , and hence the whole problem.
Can you post a problem which you found to be quite tough from when you were year 12?
 

glittergal96

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Re: HSC 2015 4U Marathon - Advanced Level

Can you post a problem which you found to be quite tough from when you were year 12?
I can't really remember off the top of my head. Try some of the problems from olympiads.
 

Chlee1998

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Re: HSC 2015 4U Marathon - Advanced Level

Prove that (n+1)^(n+1) + (-n)^n is not divisble by 9 for any natural number n.
 

RealiseNothing

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Re: HSC 2015 4U Marathon - Advanced Level

Define a function by:



Where is prime, is real, and is the highest integer power of that divides .

Note that doesn't have to be integer. i.e.

You are given that the function defined has the property that:



Use this function to prove that the square root of all non-square positive integers is irrational.
 
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InteGrand

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Re: HSC 2015 4U Marathon - Advanced Level

Define a function by:



Where is prime, is a positive integer, and is the highest power of that divides .

Note that doesn't have to be integer. i.e.

You are given that the function defined has t
he property that:



Use this function to prove that the square root of all non-square positive integers is irrational.
How can we have the example of ? Didn't you say needed to be integer?
 
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