harder 3 Unit Inequalities question (1 Viewer)

Hermes1 · Aug 16, 2011

it is given that for three positive real numbers a, b and c,
$\frac{a+b+c}{3}\geq \sqrt[3]{abc}$

if we also no that a+b+c = 1, prove that:

$(1-a)(1-b)(1-c)\geq 8abc$

new to inequalities, would someone be able to help me wiff this question.

and earlier in the question i proved:
$\frac{1}{abc}\geq 27$ - i dont no if this is relevant to above question.

Drongoski · Aug 16, 2011

This Q8 from Cambridge says: a, b, c > 0 and a+b+c = 1. Show that:

a) i) 1/a + 1/b + 1/c >= 9

ii) 1/(a^2) + 1/ (b^2) + 1/ (c^2) >= 27

b) ab + ac + ca >= 9abc

c) (1-a)(1-b)(1-c) >= 8abc

Hermes1 · Aug 16, 2011

kk tnks ill try it.

Drongoski · Aug 16, 2011

a) (i)

$\frac {a+b+c}{3} \geq \sqrt[3] {abc} \implies \frac{1}{3} \geq \sqrt[3]{abc} \implies \frac {1}{\sqrt[3]{abc}} \geq 3$

$\frac {\frac {1}{a} + \frac {1}{b} + \frac {1}{c}}{3} \geq \sqrt[3]{\frac{1}{a} \times \frac {1}{b} \times \frac {1}{c}} = \frac {1}{\sqrt[3] {abc}}$

$\therefore \frac{1}{a} + \frac {1}{b} + \frac {1}{c} \geq 3 \times \frac {1}{\sqrt[3] {abc}} \geq 3 \times 3 = 9$

(ii)

$\frac {\frac{1}{a^2} + \frac {1}{b^2} + \frac {1}{c^2}}{3} \geq \sqrt[3] {\frac {1}{a^2} \times \frac {1}{b^2} \times \frac {1}{c^2}} = \frac {1}{\sqrt[3]{abc}} \times \frac {1}{\sqrt[3]{abc}} \geq 3 \times 3$

$\therefore \frac {1}{a^2} + \frac {1}{b^2} + \frac {1}{c^2} \geq 27$

Now you carry on from here.

Hermes1 · Aug 16, 2011

so with this topic u r just trying to manipulate expressions to suit the condition given?

Omnipotence · Aug 16, 2011

Drongoski · Aug 16, 2011

Hermes1 said:
so with this topic u r just trying to manipulate expressions to suit the condition given?

You have to be very manipulative!

largarithmic · Aug 16, 2011

You dont need all that stuff listed earlier, you can do this question almost straight out using the AM-GM for two variables.

$\noindent (1-a)(1-b)(1-c) = (b+c)(a+c)(a+b) \ge (2\sqrt{bc})(2\sqrt{ac})(2\sqrt{ab}) = 8abc$

The first step is just using the $a+b+c=1$ condition, whereas the second step is just using $x+y \ge 2\sqrt{xy}$ .

Hermes1 · Aug 16, 2011

largarithmic said:
You dont need all that stuff listed earlier, you can do this question almost straight out using the AM-GM for two variables.

$\noindent (1-a)(1-b)(1-c) = (b+c)(a+c)(a+b) \ge (2\sqrt{bc})(2\sqrt{ac})(2\sqrt{ab}) = 8abc$

The first step is just using the $a+b+c=1$ condition, whereas the second step is just using $x+y \ge 2\sqrt{xy}$ .

am i allowed to just use the AM-GM inequality without proving it?

Omnipotence · Aug 17, 2011

I went on google and saw Fermat's 'Last Theorem' and what is it?

Hermes1 · Aug 17, 2011

Omnipotence said:
I went on google and saw Fermat's 'Last Theorem' and what is it?

Fermat's last theorem states that no three positive integers a, b and c can satisfy the equation $a^{n}+b^{n}=c^{n}$ for any integer value of n greater that 2.

Omnipotence · Aug 17, 2011

I see.

Drongoski · Aug 17, 2011

largarithmic said:
You dont need all that stuff listed earlier, you can do this question almost straight out using the AM-GM for two variables.

$\noindent (1-a)(1-b)(1-c) = (b+c)(a+c)(a+b) \ge (2\sqrt{bc})(2\sqrt{ac})(2\sqrt{ab}) = 8abc$

The first step is just using the $a+b+c=1$ condition, whereas the second step is just using $x+y \ge 2\sqrt{xy}$ .

Brilliant. Didn't see that.

Hermes1 · Aug 17, 2011

Drongoski am i allowed to just pull out this AM-GM thing without proving it?

Drongoski · Aug 17, 2011

Yes. One of the important basic inequalities for harder 3u.

Hermes1 · Aug 17, 2011

Drongoski said:
Yes. One of the important basic inequalities for harder 3u.

nice. tnks for ur help.

Drongoski · Aug 17, 2011

Omnipotence said:
I went on google and saw Fermat's 'Last Theorem' and what is it?

You are right to have cited in quotes "Last Theorem" because it should have been called Fermat's Last Conjecture. But because it has been referred to as such it has become known as "Fermat's Last Theorem". Why conjecture? Because until (now Sir) Andrew Wiles proved it in 1994/1995, over 350 years later, it was not established for sure whether that proposition was true or false.

Omnipotence · Aug 17, 2011

Didn't Andrew Wiles prove the Modularity Theorem (Taniyama-Shimura) rather than directly Fermat's?

cutemouse · Aug 17, 2011

Hermes1 said:
it is given that for three positive real numbers a, b and c,
$\frac{a+b+c}{3}\geq \sqrt[3]{abc}$

if we also no that a+b+c = 1, prove that:

$(1-a)(1-b)(1-c)\geq 8abc$

new to inequalities, would someone be able to help me wiff this question.

and earlier in the question i proved:
$\frac{1}{abc}\geq 27$ - i dont no if this is relevant to above question.

Where did you get this q from?

Hermes1 · Aug 17, 2011

cutemouse said:
Where did you get this q from?

2009 Shore Maths Extension 2 Trial Paper

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