HSC 2015 MX2 Marathon ADVANCED (archive) (2 Viewers)

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InteGrand

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Re: HSC 2015 4U Marathon - Advanced Level

I think you might have some quantifiers the wrong way around?

We want to find a real number a such that f(x) =< ax for all f satisfying the inequality in the original question.

In particular, we want to find the least a that works for every such f.

We know a = 1 works for the function f(x) = x, but it is perfectly conceivable that there are other functions which satisfy the conditions of the problem, but for which we don't have g(x) =< x.
 

dan964

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Re: HSC 2015 4U Marathon - Advanced Level

^ nice
that is a lot clearer.
It does also restrict the range of y between 0 and 1?
(to which the statement f(x+y)>=f(x)+f(y) holds true).

The domain of f is (given)
The range of f is as

Hence the maximum value of range between 0 and 1 is 1, which is also f(1). Therefore the curve is monotonically increasing.
 
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glittergal96

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Re: HSC 2015 4U Marathon - Advanced Level

It does also restrict the range of y between 0 and 1?
(to which the statement f(x+y)>=f(x)+f(y) holds true).
The statement is required to hold true for any pair of non-negative numbers x and y such that x+y =< 1.

(So their sum is still in the domain of the function.)

This condition was already included in the initial and revised wording of the question.
 

glittergal96

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Re: HSC 2015 4U Marathon - Advanced Level

The range of f is as

Hence the maximum value of range between 0 and 1 is 1, which is also f(1). Therefore the curve is monotonically increasing.
Uh, I think you are getting a bit confused, this quote makes very little sense.

Any sexy function f satisfies

f(x+y) >= f(x) + f(y)

for all non-negative x and y such that x+y =< 1.


x and y are just variables used for the sake of defining what it means for a function to be sexy, they don't have any relationship like y=f(x).

Monotonicity just comes from the fact that if x >= y then:

f(x) = f((x-y) + y) >= f(x-y) + f(y) >= f(y).

where the two inequalities follow from the definition of a sexy function.
 

dan964

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Re: HSC 2015 4U Marathon - Advanced Level

Uh, I think you are getting a bit confused, this quote makes very little sense.

Any sexy function f satisfies

f(x+y) >= f(x) + f(y)

for all non-negative x and y such that x+y =< 1.


x and y are just variables used for the sake of defining what it means for a function to be sexy, they don't have any relationship like y=f(x).

Monotonicity just comes from the fact that if x >= y then:

f(x) = f((x-y) + y) >= f(x-y) + f(y) >= f(y).

where the two inequalities follow from the definition of a sexy function.
ah right, x+y<=1 doesn't necessary apply to all values of the domain as f(1)=1 is an obvious exception.
 

dan964

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Re: HSC 2015 4U Marathon - Advanced Level

Uh, I think you are getting a bit confused, this quote makes very little sense.
Monotonicity just comes from the fact that if x >= y then:
f(x) = f((x-y) + y) >= f(x-y) + f(y) >= f(y).
where the two inequalities follow from the definition of a sexy function.
doesn't the statement x>=y imply that it must lie under the graph y=x for all values that occur with the region below (which is where the inequality holds true), and also even for values outside of this region (up to x=1)

 

dan964

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Re: HSC 2015 4U Marathon - Advanced Level

for (4) on the previous page, is a case that does not hold
as does not hold true.
while all functions y=x^n hold, whereby n is positive hold. as (x+y)^n >= x^n + y^n which could be proven by induction.
(all of the latter for all x in the domain lie have values where y<=x)
 

InteGrand

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Re: HSC 2015 4U Marathon - Advanced Level

doesn't the statement x>=y imply that it must lie under the graph y=x for all values that occur with the region below (which is where the inequality holds true), and also even for values outside of this region (up to x=1)

 

dan964

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Re: HSC 2015 4U Marathon - Advanced Level

that does help, thanks
this makes sense with relation to "convexity", since it involves I guess comparing the sum of two function values.
 
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glittergal96

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Re: HSC 2015 4U Marathon - Advanced Level

Here is a further hint.

If a function f satisfies f(0)=0 and is convex, then f(x+y) >= f(x) + f(y) for all x and y, as:

 

dan964

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Re: HSC 2015 4U Marathon - Advanced Level

Here is a further hint.

If a function f satisfies f(0)=0 and is convex, then f(x+y) >= f(x) + f(y) for all x and y, as:

*
where did the middle section come from?
I understand where the last section came from.

f(x+h) implies directly that the value (x+h) must occur in the domain 0 to 1
The definition of convex means the secant equation must lie above the graph of f(x)
The gradient of the secant is


Use the point , [otherwise the answer will f(x)]
 
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InteGrand

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Re: HSC 2015 4U Marathon - Advanced Level

where did the middle section come from?
I understand where the last section came from.

f(x+h) implies directly that the value (x+h) must occur in the domain 0 to 1
The definition of convex means the secant equation must lie above the graph of f(x)
The gradient of the secant is


Use the point , [otherwise the answer will f(x)]


(See this diagram from Wikipedia: https://upload.wikimedia.org/wikipedia/commons/c/c7/ConvexFunction.svg)
 
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dan964

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Re: HSC 2015 4U Marathon - Advanced Level

thanks. sorry didn't get to finish working it out.

I suspect the answer then is alpha=1.
 

glittergal96

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Re: HSC 2015 4U Marathon - Advanced Level

Nope, alpha is not 1. Try to find an upper bound first :).
 

dan964

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Re: HSC 2015 4U Marathon - Advanced Level

I got from using your substitution on the left hand side and comparing it with Glittergal96's inequality, that I originally asked about.

I understand how you derived it except for the relationship between the LHS and the actual inequality posed a couple of replies up.
 
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dan964

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Re: HSC 2015 4U Marathon - Advanced Level

Nope, alpha is not 1. Try to find an upper bound first :).
isn't f(1)=1 and f(0)=0, so thus it is secant (y=x), the join between that, that must be above the graph if it convex?
or does convexity not apply for this case of extremities?
 

InteGrand

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Re: HSC 2015 4U Marathon - Advanced Level

I got from using your substitution on the left hand side and comparing it with Glittergal96's inequality, that I originally asked about.

I understand how you derived it except for the relationship between the LHS and the actual inequality posed a couple of replies up.
 
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