$\"\"$

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The function is $\"\"$ where $\"\"$ .

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Definition of Taylor series:

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If a function $\"\"$ has derivatives of all orders at $\"\"$ then the series

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$\"\"$ is called Taylor series for $\"\"$ at $\"\"$ .

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Find consecutive derivatives of the function to know the pattern of the n th derivative of the function.

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$\"\"$

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Apply derivative on each side with respect to $\"\"$ .

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$\"\"$

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Since $\"\"$ .

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$\"\"$ .

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$\"\"$

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$\"\"$

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$\"\"$ for $\"\"$

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Find the values of the above functions at $\"\"$ .

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$\"\"$

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$\"\"$

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$\"\"$

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$\"\"$ .

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$\"\"$

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The Taylors series $\"\"$ .

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Substitute the corresponding values in the Maclaurin series formula.

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$\"\"$

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$\"\"$ .

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Taylors series of the function $\"\"$ is $\"\"$ .

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Find the radius of convergence using ratio test.

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Taylors series of the function $\"\"$ is $\"\"$ .

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The series is a finite number of terms becaues $\"\"$ for $\"\"$ .

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Therefore, the series is convergence for all values of $\"\"$ .

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Hence the radius of convergence is $\"\"$ .

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$\"\"$

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Taylors series of the function $\"\"$ is $\"\"$ .

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Radius of convergence is $\"\"$ .