Answer
\[\begin{align}
& \left. a \right)-1+\frac{1}{2!}{{\left( x-\pi \right)}^{2}}-\frac{1}{4!}{{\left( x-\pi \right)}^{4}}+\frac{1}{6!}{{\left( x-\pi \right)}^{6}} \\
& \left. b \right)\sum\limits_{k=0}^{\infty }{\frac{{{\left( -1 \right)}^{k+1}}}{\left( 2k \right)!}{{\left( x-\pi \right)}^{2k}}} \\
\end{align}\]
Work Step by Step
\[\begin{align}
& f\left( x \right)=\cos x,\text{ }a=\pi \\
& \text{Using the definition of Taylor series for a function}\left( page\,685 \right) \\
& \sum\limits_{k=0}^{\infty }{\frac{{{f}^{\left( k \right)}}\left( a \right)}{k!}{{\left( x-a \right)}^{k}}}\text{ }\left( \mathbf{1} \right) \\
& =f\left( a \right)+f'\left( a \right)\left( x-a \right)+\frac{f''\left( a \right)}{2!}{{\left( x-a \right)}^{2}}+\cdots \\
& \text{First}\text{, we calculate some derivatives and their value at }x=\pi \\
& f\left( x \right)=\cos x\to f\left( \pi \right)=\cos \left( \pi \right)=-1 \\
& f'\left( x \right)=-\sin x\to f'\left( \pi \right)=-\sin \left( \pi \right)=0 \\
& f''\left( x \right)=-\cos x\to f''\left( \pi \right)=-\cos \left( \pi \right)=1 \\
& f'''\left( x \right)=\sin x\to f'''\left( \pi \right)=\sin \left( \pi \right)=0 \\
& {{f}^{\left( 4 \right)}}\left( x \right)=\cos x\to {{f}^{\left( 4 \right)}}\left( \pi \right)=\cos \left( \pi \right)=-1 \\
& {{f}^{\left( 5 \right)}}\left( x \right)=-\sin x\to {{f}^{\left( 5 \right)}}\left( \pi \right)=-\sin \left( \pi \right)=0 \\
& {{f}^{\left( 6 \right)}}\left( x \right)=-\cos x\to {{f}^{\left( 6 \right)}}\left( \pi \right)=-\cos \left( \pi \right)=1 \\
& \\
& \left. a \right)\text{ Substituting the previous result into the formula }\left( \mathbf{1} \right). \\
& \left( \text{Using the nonzero coefficients} \right) \\
& =-1+\frac{\left( 1 \right)}{2!}{{\left( x-\pi \right)}^{2}}+\frac{\left( -1 \right)}{4!}{{\left( x-\pi \right)}^{4}}+\frac{\left( 1 \right)}{6!}{{\left( x-\pi \right)}^{6}} \\
& =-1+\frac{1}{2!}{{\left( x-\pi \right)}^{2}}-\frac{1}{4!}{{\left( x-\pi \right)}^{4}}+\frac{1}{6!}{{\left( x-\pi \right)}^{6}} \\
& \\
& \left. b \right)\text{ Rewrite the power series} \\
& =\frac{{{\left( -1 \right)}^{0+1}}}{\left( 2\cdot 0 \right)!}{{\left( x-\pi \right)}^{\left( 2\cdot 0 \right)}}+\frac{{{\left( -1 \right)}^{1+1}}}{\left( 2\cdot 1 \right)!}{{\left( x-\pi \right)}^{\left( 2\cdot 1 \right)}}+\frac{{{\left( -1 \right)}^{2+1}}}{\left( 2\cdot 2 \right)!}{{\left( x-\pi \right)}^{\left( 2\cdot 2 \right)}} \\
& +\frac{{{\left( -1 \right)}^{3+1}}}{\left( 2\cdot 3 \right)!}{{\left( x-\frac{\pi }{2} \right)}^{\left( 2\cdot 3 \right)}} \\
& \text{Using summation notation}\text{, we obtain} \\
& \sum\limits_{k=0}^{\infty }{\frac{{{\left( -1 \right)}^{k+1}}}{\left( 2k \right)!}{{\left( x-\pi \right)}^{2k}}} \\
\end{align}\]
