Part B/C - Algebraic Inequalities (1 Viewer)

mmmmmmmmaaaaaaa · Jan 14, 2022

I completed part a
a) a^4+b^4 ≥ 2a^2b^2 etc.
for part b though, I'm unsure what it would be following the same logic

Screen Shot 2022-01-14 at 2.03.03 am.png

Trebla · Jan 14, 2022

From the result in part (a)
- Replace a with $\sqrt{ab}$
- Replace b with $\sqrt{ac}$
- Replace c with $\sqrt{bc}$

Run hard@thehsc · Jan 17, 2022

For part b, not sure, but you could do a = b = c and then sub it in - Could someone verify!

5uckerberg · Jan 20, 2022

Run hard@thehsc said:
For part b, not sure, but you could do a = b = c and then sub it in - Could someone verify!

No, because if you do that you will have both sides being equal which is no longer an inequality.

5uckerberg · Jan 31, 2022

mmmmmmmmaaaaaaa said:
I completed part a
a) a^4+b^4 ≥ 2a^2b^2 etc.
for part b though, I'm unsure what it would be following the same logic
View attachment 34637

For part b I have an antidote. Do you notice how part b started with "Hence ... "
So using the same idea as part a you will see that
$\left(ab-bc\right)^{2}\geq{0}$
$\left(bc-ac\right)^{2}\geq{0}$
$\left(ac-ab\right)^{2}\geq{0}$

Expanding they become
$a^{2}b^{2}-2ab^{2}c+b^{2}c^{2}\geq{0}$
$b^{2}c^{2}-2bc^{2}a+a^{2}c^{2}\geq{0}$
$a^{2}c^{2}-2ba^{2}c+b^{2}a^{2}\geq{0}$

Add them all together it becomes $2a^{2}b^{2}+2a^{2}c^{2}+2b^{2}c^{2}\geq{2\left(ab^{2}c+bc^{2}a+ba^{2}c\right)}$
Divide by 2 we will have the required answer for part b.

@Run hard@thehsc & @mmmmmmmmaaaaaaa here is your solution to part b

When you see the word "Hence ... " you tend to follow the same logic because hence implies that you are using one statement to prove the other. Works just like "Similiarly ... " but for the question. Reasoning being similiarly, is used when you do not want to write the same statement twice.

5uckerberg · Feb 1, 2022

I have made a small mistake in part c from my previous post but instead part c can be done very easily because of one reason. Since $a+b+c=d$ then we can exploit the fact that $a^{2}bc+b^{2}ac+c^{2}ab=abc\left(a+b+c\right)$ . Well that is simply $abcd$ .

Once that is out of the way we can now combine parts a and b and formulate an inequality. As shown it becomes
$a^{4}+b^{4}+c^{4}\geq{a^{2}b^{2}+a^{2}c^{2}+b^{2}c^{2}}\geq{abc\left(a+b+c\right)}$ . This is simply just
$a^{4}+b^{4}+c^{4}\geq{a^{2}b^{2}+a^{2}c^{2}+b^{2}c^{2}}\geq{abcd}$
So to finish it off
$a^{4}+b^{4}+c^{4}\geq{abcd}$

This response correct.

mmmmmmmmaaaaaaa · Feb 1, 2022

5uckerberg said:
Part c will be a walk in the inequalities forest. Are you ready for that? So the first step will be to start with $a+b\geq{2\sqrt{ab}$ and $c+d\geq{2\sqrt{cd}}$ .

Next, we will have to start with the fact that $\frac{a+b}{2}\geq{\sqrt{ab}}, \frac{c+d}{2}\geq{\sqrt{cd}}$ .
There we divide by 2 and using the inequalities that are known we will have $\frac{\frac{a+b}{2}+\frac{c+d}{2}}{2}\geq{\sqrt{\sqrt{ab}\sqrt{cd}}$
Noting that $\sqrt{ab}+\sqrt{cd}\geq{2\sqrt{\sqrt{ab}\sqrt{cd}}=\sqrt{ab}+\sqrt{cd}\geq{2{\sqrt[4]{abcd}}}$

At this momwnt our goal will be to multiply by 2 and then multiply by 2 and in doing so we actually multiply by 4. There you will have
$a+b+c+d\geq{4\sqrt[4]{abcd}}$ .

Now the question starts.

Do you recall that $a+b+c=d$
Well, on the LHS of the inequality it will become $2\left(a+b+c\right)\geq{4\sqrt[4]{abcd}}$
There, $a+b+c\geq{2\sqrt[4]{abcd}}$ .
I imagine what happens is that out of the rabbit's hat $a\rightarrow{a^{4}}, b\rightarrow{b^{4}}, c\rightarrow{c^{4}}$ and in doing so it will give us $a^{4}+b^{4}+c^{4}\geq{2abcd}$ . I assume that $d\rightarrow{d^{4}}$ out of nowhere. I could sense that either this is a typo or something shady is happening. If it is the latter please show us.
Thus, we have proven that $a^{4}+b^{4}+c^{4}\geq{abcd}$

Thanks!

Part B/C - Algebraic Inequalities (1 Viewer)

mmmmmmmmaaaaaaa

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Trebla

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Run hard@thehsc

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5uckerberg

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5uckerberg

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mmmmmmmmaaaaaaa

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