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I happen to read a book, in which it states that,

if $P_n(x)$ is the $n+1$ th Taylor polynomial (that is, $P_n(x)=a_0+a_1x+\cdots+a_{n}x^n$) of the function $\sqrt{x+a}$ (a>0)at $x=0$, then there is a polynomial $Q_n(x)$ such that

$P_n^2(x)=x+a+x^{n+1}Q_n(x).$

I have tried to calculate for small $n$, it shows the claim is right.

But I cannot find an easy way to prove it, or understand the result clearly. And is there a more general result for other functions, like $\sqrt[3]{x+a}$?

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    @joriki, th$a$nks. I refered to J.M.'s comment. I mean I know the $b$inomi$a$l theorem.2011-08-29

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Since $P_n$ is the $(n+1)$-th Taylor polynomial of the function, the error term is of order $x^{n+1}$:

$\sqrt{x+a}=P_n(x)+R(x)$

with $R(x)\in O(x^{n+1})$. Squaring that yields

$x+a=P_n(x)^2+2P_n(x)R(x)+R(x)^2=P_n(x)^2+S(x)$

with $S(x)\in O(x^{n+1})$. But $S(x)$ is the difference of two polynomials, and thus itself a polynomial, so if it's in $O(x^{n+1})$ it must be of the form $-x^{n+1}Q_n(x)$ with $Q_n(x)$ a polynomial.

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    Thanks for your answer. I have not tried this way before(I just tried to calculate the coefficients of terms of $P_n(x)^2-x-a$, but it does not work).2011-08-29