How do I compute the taylor series for $\cos(x)^{\sin(x)}$ ? I tried using the $e^x$ rule but I still am not getting to the result:
$\cos(x)^{\sin(x)}=1-\frac{x^3}{2}+\frac{x^6}{8}+o(x^6).$
How do I compute the taylor series for $\cos(x)^{\sin(x)}$ ? I tried using the $e^x$ rule but I still am not getting to the result:
$\cos(x)^{\sin(x)}=1-\frac{x^3}{2}+\frac{x^6}{8}+o(x^6).$
Very informally:
Noting $\bigl(\cos x \bigr)^{\sin x } =\exp\bigl ( \sin (x) \ln (\cos x) \bigr)$.
Start with $\cos x = 1-{x^2\over 2!}+{x^4\over 4!}-\cdots$.
Then use the Taylor series $\ln(1+z)=z-{z^2\over2}+{z^3\over3}-\cdots$ with $z=-{x^2\over 2!}+{x^4\over 4!}-\cdots$ to obtain the first few terms of the expansion of $\ln(\cos x)$.
Multiply this by the first few terms of the Taylor series for $\sin x$.
This will give you some polynomial expression $P(x)$; which you would then substitute into the Taylor series for $e^x$.
Your formula ($\cos(x)^{\sin(x)}=1-\frac{x^3}{2}+\frac{x^6}{8}+o(x^6).$) has been achieved from the definition of The Taylor Series: $f(x) = \sum_{i=0}^{\infty}\frac{f^{(n)}(x_0)}{n!}(x-x_0)^n$ Where $f^{(n)}(x)$ is $n$th derivative of $f(x)$ with respect to $x$.
(Notice that $f\in c^{\infty}$)
put $x_0=0$ and calculate the coefficients of $x^0$, $x^1$, ... $x^6$.