Polynomial Proofs (1 Viewer)

khorne · Jul 20, 2011

Which proofs relating to polynomials would be beneficial to know? i.e which ones would be likely to pop up in an exam?

I can think of maybe proving if a polynomial nth degree is equal to another for more than n values, they are the same polynomial. And proving conjugate root theorem.

Trebla · Jul 20, 2011

I've hardly seen any exam questions requiring a proof of a polynomials theorem. The only one that really gets asked occasionally is to prove the multiple root theorem.

Hermes1 · Jul 20, 2011

This one comes up quite a lot, I have seen it in a few trial papers:

Prove that $1+x+\frac{x^{2}}{2!}+\frac{x^{3}}{3!}....+\frac{x^{n}}{n!}=0$

has no multiple roots for n is greater than or equal to 1.

Hermes1 · Jul 20, 2011

Trebla said:
I've hardly seen any exam questions requiring a proof of a polynomials theorem. The only one that really gets asked occasionally is to prove the multiple root theorem.

the multiple root theorem is that this one:

let $P(x) = (x-\alpha )^{n}Q(x)$
and then you diffentiate and show P(alpha) is also equal to zero.

Timothy.Siu · Jul 20, 2011

arj1 said:
This one comes up quite a lot, I have seen it in a few trial papers:

Prove that $1+x+\frac{x^{2}}{2!}+\frac{x^{3}}{3!}....+\frac{x^{n}}{n!}=0$

has no multiple roots for n is greater than or equal to 1.

taylor expansion of $e^x$ with $n+1$ terms!
and i remember doing that question too lol.

Hermes1 · Jul 20, 2011

Timothy.Siu said:
taylor expansion of $e^x$ with $n+1$ terms!
and i remember doing that question too lol.

i dont know what that taylor expansion thing is, but u definitely dont need that to solve that question

khorne · Jul 20, 2011

Yeah that's straight forward proof there. Off the top of my head, you differentiate, then the condition of them being multiple roots is p(0) = 0, but in the initial thing p(0) =/= 0? SOmething like that?

Drongoski · Jul 20, 2011

arj1 said:
This one comes up quite a lot, I have seen it in a few trial papers:

Prove that $1+x+\frac{x^{2}}{2!}+\frac{x^{3}}{3!}....+\frac{x^{n}}{n!}=0$

has no multiple roots for n is greater than or equal to 1.

$P(x) = 1 + x + \frac {x^2}{2!} + \frac {x^3}{3!} + \dots + \frac {x^n}{n!}$

$P'(x) = 1 + x + \frac {x^2}{2!} + \dots + \frac {x^{n-1}}{(n-1)!}$

If $\alpha$ is a multiple root of P(x) = 0 then:

$P(\alpha) = 1 + \alpha + \frac {\alpha ^2}{2!} + \dots + \frac {\alpha^{(n-1)}}{(n-1)!} + \frac {\alpha ^ n}{n!} = 0$

$P'(\alpha) = 1 + \alpha + \frac {\alpha ^2}{2!} + \dots + \frac {\alpha ^{(n-1)}}{(n-1)!} = 0$

$\therefore \frac {\alpha ^ n}{n!} = 0 \implies \alpha = 0$

But

$P(0) = 1 \neq 0$

$\therefore \alpha \neq 0$

a contradiction

Note: above requires n >= 1

Edit

In what sense a contradiction? - the assumption there is a multiple root $\alpha$ .

jeel · Jul 20, 2011

arj1 said:
This one comes up quite a lot, I have seen it in a few trial papers:

Prove that $1+x+\frac{x^{2}}{2!}+\frac{x^{3}}{3!}....+\frac{x^{n}}{n!}=0$

has no multiple roots for n is greater than or equal to 1.

how do you do it?

Drongoski · Jul 20, 2011

khorne said:
Which proofs relating to polynomials would be beneficial to know? i.e which ones would be likely to pop up in an exam?

I can think of maybe proving if a polynomial nth degree is equal to another for more than n values, they are the same polynomial. And proving conjugate root theorem.

Why don't you put up proof for this to make sure it's set out right.

Hermes1 · Jul 20, 2011

Drongoski said:
$P(x) = 1 + x + \frac {x^2}{2!} + \frac {x^3}{3!} + \dots + \frac {x^n}{n!}$

$P'(x) = 1 + x + \frac {x^2}{2!} + \dots + \frac {x^{n-1}}{(n-1)!}$

If $\alpha$ is a multiple root of P(x) = 0 then:

$P(\alpha) = 1 + \alpha + \frac {\alpha ^2}{2!} + \dots + \frac {\alpha^{(n-1)}}{(n-1)!} + \frac {\alpha ^ n}{n!} = 0$

$P'(\alpha) = 1 + \alpha + \frac {\alpha ^2}{2!} + \dots + \frac {\alpha ^{(n-1)}}{(n-1)!} = 0$

$\therefore \frac {\alpha ^ n}{n!} = 0 \implies \alpha = 0$

But

$P(0) = 1 \neq 0$

$\therefore \alpha \neq 0$

a contradiction

Note: above requires n >= 1

nice work. i had actually forgotten how to do this question, but luckily u posted

khorne · Jul 22, 2011

P(x) = a0 + a1x +...+ anx^n
Let z be a root, such that a0 + a1z +...+anz^n = 0
Now, if z is a root, that conjugate of both sides noting 0* = 0
(P(x)*) = 0* = 0
a0* + a1*z* + ...+an*z^n*
Conjugate of constants is constant, and conjugate of power is the same as power of conjugate
therefore a0 + a1z* +...+anz*^n = 0, i.e z* is a root.

Drongoski · Jul 22, 2011

khorne said:
P(x) = a0 + a1x +...+ anx^n
Let z be a root, such that a0 + a1z +...+anz^n = 0
Now, if z is a root, that conjugate of both sides noting 0* = 0
(P(x)*) = 0* = 0
a0* + a1*z* + ...+an*z^n*
Conjugate of constants is constant, and conjugate of power is the same as power of conjugate
therefore a0 + a1z* +...+anz*^n = 0, i.e z* is a root.

Good. You have the key ideas correct. Would have been helpful if you'd given your proof the LaTeX treatment.

funnytomato · Jul 24, 2011

Drongoski said:
Good. You have the key ideas correct. Would have been helpful if you'd given your proof the LaTeX treatment.

that's gonna take ages...

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