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KGS math club/solution 5 1

Revision as of 20:40, 2 May 2009 by Pontrjagin (talk | contribs) (New page: Proof: Let n be the degree of the polynomial P. Since P has nonzero degree, n>0. The Taylor polynomial of P about the point a is <math>F(x)=P(a)+P'(a)(x-a)+\dotsb +\dfrac{P^{(n)}(a)(x...)
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Proof:

Let n be the degree of the polynomial P. Since P has nonzero degree, n>0. The Taylor polynomial of P about the point a is

$F(x)=P(a)+P'(a)(x-a)+\dotsb +\dfrac{P^{(n)}(a)(x-a)^n}{n!}=P(x)$.

The Taylor polynomial of P about the point b is

$G(x)=P(b)+P'(b)(x-b)+\dotsb +\dfrac{P^{(n)}(b)(x-b)^n}{n!}=P(x))$.

Note that $F(x)=G(x)$ for all real numbers x, because $F=P=G$. Also, since $P^{(i)}(a)=P^{(i)}(b)$ for all i, we can rewrite G as $G(x)=P(a)+P'(a)(x-b)+\dotsb +\dfrac{P^{(n)}(a)(x-b)^n}{n!}=P(x))$.

Now suppose that $a\neq b$. Let $c=|a-b|$. Then c is greater than zero. Let $y,z\in\Re$ such that $|y-z|=c$. Then $P(y)=P(z)$; since P is a nonconstant polynomial this implies that there is a turning point in the interval (z,y). Hence, between any two real numbers x,y with $|x-y|=c$, there exists a turning point. So P has infinitely many turning points. This is a contradiction, since a polynomial only has finitely many turning points. Therefore, $a=b$.

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