Challenge for 2u peeps (1 Viewer)

HeroicPandas · May 11, 2013

darlking said:
I never learnt that. What r u on about. isnt that 3u?

It's my favourite topic in 2U!

http://www.boredofstudies.org/courses/maths/2u/1119956014_2004_Mathematics_Notes_Emily_Meers.pdf

fishrushed · May 11, 2013

Can't seem to get the answer by itself. I keep getting an extra bit on top of what I have to show (k< -25)
Must be bad news for me

fishrushed · May 11, 2013

darlking said:
I never learnt that. What r u on about. isnt that 3u?

It's a 2U topic. There is quadratic formula and discriminant, sum and product of roots and some other things in that topic.

Sy123 · May 11, 2013

fishrushed said:
Can't seem to get the answer by itself. I keep getting an extra bit on top of what I have to show (k< -25)
Must be bad news for me

The only thing you need to actually show is that k > 1.

The upper bound ( k < 25/24) comes much more simply than you might think.

darlking · May 11, 2013

Oh ok, well that was last year and don't expect me to remember my topic names last year.

darlking · May 11, 2013

Sy123 said:
The only thing you need to actually show is that k > 1.

How do you show k >1 when you can also show k < 25/24. I found the 25/24 one.

Sy123 · May 11, 2013

darlking said:
How do you show k >1 when you can also show k < 25/24. I found the 25/24 one.

By using the quadratic formula, we can find that:

$\alpha = \frac{-5 + \sqrt{25-24k}}{2k}$

$\beta = \frac{-5 - \sqrt{25-24k}}{2k}$

What do we get when alpha - beta?

We get an inequality in terms of k.

What is the solution to this inequality?
One of them is k > 1.

superSAIyan2 · May 11, 2013

Too get the other inequality use discriminant properties and your knowledge of real and unreal roots (i.e. what is the definite condition for there to be real roots)

omgiloverice · May 11, 2013

thank god, nobody solved it before I got back from my 7hr tutor -.-

Trebla · May 11, 2013

Sy123 said:
By using the quadratic formula, we can find that:

$\alpha = \frac{-5 + \sqrt{25-24k}}{2k}$

$\beta = \frac{-5 - \sqrt{25-24k}}{2k}$

What do we get when alpha - beta?

We get an inequality in terms of k.

What is the solution to this inequality?
One of them is k > 1.

Umm...doesn't that lead an inequality with an unknown in the denominator which is beyond the 2u course?

This is what I get without requiring an unknown in the denominator.

Suppose that $\alpha$ and $\beta$ are the roots where $\alpha > \beta$ . We are given that $\alpha-\beta < 1$

Sum of roots:

$\alpha+\beta = -\dfrac{5}{k}$

Product of roots:

$\alpha\beta = \dfrac{6}{k}$

But

$(\alpha - \beta)^2 \\\\= \alpha^2 - 2\alpha\beta + \beta^2 \\\\= \alpha^2 + 2\alpha\beta + \beta^2 - 4\alpha\beta \\\\= (\alpha + \beta)^2 - 4\alpha\beta \\\\ = \dfrac{25}{k^2} - \dfrac{24}{k}$

Since

$0 < \alpha-\beta < 1$

then

$0 < (\alpha-\beta)^2 < 1$

Substituting the result we get

$0 < \dfrac{25-24k}{k^2} < 1\\\\\Rightarrow 0 < 25 - 24k < k^2$

Note that since the denominator is always non-negative, the sign of the inequality is unchanged (whereas in your case you need to deal with cases where k is positive/negative etc).

Looking at the left inequality we immediately get the upper bound.

$k < \dfrac{25}{24}$

Looking at the right inequality.

$k^2 + 24k - 25 > 0\\\\\Rightarrow (k + 25)(k - 1) > 0\\\\\Rightarrow k < -25 $ or $ k > 1$

Tehnically speaking, putting the inequalities together we should get

$1 < k < \dfrac{25}{24} $ or $ k < -25$

Missing a solution set haya!

darlking · May 11, 2013

tHANk you Trebla!

hayabusaboston · May 11, 2013

omgiloverice said:
thank god, nobody solved it before I got back from my 7hr tutor -.-
View attachment 28102

Actually heroicpandas did b4 anyone LOL he just didnt post it here.

omgiloverice · May 11, 2013

hayabusaboston said:
Actually heroicpandas did b4 anyone LOL he just didnt post it here.

ahh crap i forgot about that... well I am the first person who doesn't do 4U to solve it

HeroicPandas · May 11, 2013

omgiloverice said:
ahh crap i forgot about that... well I am the first person who doesn't do 4U to solve it

Very nice!

"Now we can sacrifice the k inequalities..."

i like this

fishrushed · May 11, 2013

Sy123 said:
The only thing you need to actually show is that k > 1.

The upper bound ( k < 25/24) comes much more simply than you might think.

yea, I got k< 25/24 and k>1, but I happened to also have gotten k<-25 along with the k>1 and I just stopped there

fishrushed · May 11, 2013

Trebla said:
Tehnically speaking, putting the inequalities together we should get

$1 < k < \dfrac{25}{24} $ or $ k < -25$

Missing a solution set haya!

Oh good

at least the k<-25 i found wasn't a dud solution

hayabusaboston · May 11, 2013

Trebla said:
Umm...doesn't that lead an inequality with an unknown in the denominator which is beyond the 2u course?

This is what I get without requiring an unknown in the denominator.

Suppose that $\alpha$ and $\beta$ are the roots where $\alpha > \beta$ . We are given that $\alpha-\beta < 1$

Sum of roots:

$\alpha+\beta = -\dfrac{5}{k}$

Product of roots:

$\alpha\beta = \dfrac{6}{k}$

But

$(\alpha - \beta)^2 \\\\= \alpha^2 - 2\alpha\beta + \beta^2 \\\\= \alpha^2 + 2\alpha\beta + \beta^2 - 4\alpha\beta \\\\= (\alpha + \beta)^2 - 4\alpha\beta \\\\ = \dfrac{25}{k^2} - \dfrac{24}{k}$

Since

$0 < \alpha-\beta < 1$

then

$0 < (\alpha-\beta)^2 < 1$

Substituting the result we get

$0 < \dfrac{25-24k}{k^2} < 1\\\\\Rightarrow 0 < 25 - 24k < k^2$

Note that since the denominator is always non-negative, the sign of the inequality is unchanged (whereas in your case you need to deal with cases where k is positive/negative etc).

Looking at the left inequality we immediately get the upper bound.

$k < \dfrac{25}{24}$

Looking at the right inequality.

$k^2 + 24k - 25 > 0\\\\\Rightarrow (k + 25)(k - 1) > 0\\\\\Rightarrow k < -25 $ or $ k > 1$

Tehnically speaking, putting the inequalities together we should get

$1 < k < \dfrac{25}{24} $ or $ k < -25$

Missing a solution set haya!

Well thats certainly the most cheerie way anyone has addressed me in the past few days LOL
Indeed.
Well the intention was to make it neat, so I just left that extra one out in the question.

hayabusaboston · May 11, 2013

omgiloverice said:
ahh crap i forgot about that... well I am the first person who doesn't do 4U to solve it

Oh and

omgilovericetoo

Amiiiiiin · May 17, 2013

I found that k > 1 by finding K. but i cant get the relation between k 25/24

hayabusaboston · May 17, 2013

Amiiiiiin said:
I found that k > 1 by finding K. but i cant get the relation between k 25/24

Use discriminant and sum and product of roots.

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