Understanding Maclaurin Series - Math

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Question

Give the term of the Maclaurin series expansion of the function $f(x) = x $\tan^{-1}$ x$ .

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Answer

This can most easily be answered by recalling that the Maclaurin series for is

Multiply by to get:

$x $\tan^{-1}$ $x=x^{2 }$ - $\frac{1}{3}$ $x^{4 }$ + $\frac{1}{5}$ $x^{6 }$...$

The term is therefore $- $\frac{1}{3}$ $x^{4 }$$ .

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Question

Give the $x^ {3}$ term of the Maclaurin series of the function $f(x) = \sinh 3x$ .

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Answer

The $x^ {3}$ term of a Maclaurin series expansion has coefficient

$\frac{f ' '' (0)}{3!}$ = $\frac{f ' '' (0)}{6}$ .

We can find by differentiating three times in succession:

$f(x) = \sinh 3x$

$f'(x) = 3 \cosh 3x$

$f''(x) = 3\cdot 3\sinh 3x = 9\sinh 3x$

$f'''(x) = 9 \cdot 3\cosh 3x = 27 \cosh 3x$

$f'''(0) = 27 \cosh \left (3 \cdot 0 \right ) = 27 \cosh 0 = 27\cdot 1 = 27$

The term we want is therefore

$\frac{f ' '' (0)}{6}$ \cdot $x^{3}$ = $\frac{27}{6}$ \cdot $x^{3}$ = $\frac{9}{2}$ $x^{3}$

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Question

Give the term of the Maclaurin series expansion of the function $f(x) = x $\tan^{-1}$ x$ .

Tap to reveal answer

Answer

This can most easily be answered by recalling that the Maclaurin series for is

Multiply by to get:

$x $\tan^{-1}$ $x=x^{2 }$ - $\frac{1}{3}$ $x^{4 }$ + $\frac{1}{5}$ $x^{6 }$...$

The term is therefore $- $\frac{1}{3}$ $x^{4 }$$ .

← Didn't Know|Knew It →

Question

Give the $x^ {3}$ term of the Maclaurin series of the function $f(x) = \sinh 3x$ .

Tap to reveal answer

Answer

The $x^ {3}$ term of a Maclaurin series expansion has coefficient

$\frac{f ' '' (0)}{3!}$ = $\frac{f ' '' (0)}{6}$ .

We can find by differentiating three times in succession:

$f(x) = \sinh 3x$

$f'(x) = 3 \cosh 3x$

$f''(x) = 3\cdot 3\sinh 3x = 9\sinh 3x$

$f'''(x) = 9 \cdot 3\cosh 3x = 27 \cosh 3x$

$f'''(0) = 27 \cosh \left (3 \cdot 0 \right ) = 27 \cosh 0 = 27\cdot 1 = 27$

The term we want is therefore

$\frac{f ' '' (0)}{6}$ \cdot $x^{3}$ = $\frac{27}{6}$ \cdot $x^{3}$ = $\frac{9}{2}$ $x^{3}$

← Didn't Know|Knew It →

Question

Give the term of the Maclaurin series expansion of the function $f(x) = x $\tan^{-1}$ x$ .

Tap to reveal answer

Answer

This can most easily be answered by recalling that the Maclaurin series for is

Multiply by to get:

$x $\tan^{-1}$ $x=x^{2 }$ - $\frac{1}{3}$ $x^{4 }$ + $\frac{1}{5}$ $x^{6 }$...$

The term is therefore $- $\frac{1}{3}$ $x^{4 }$$ .

← Didn't Know|Knew It →

Question

Give the $x^ {3}$ term of the Maclaurin series of the function $f(x) = \sinh 3x$ .

Tap to reveal answer

Answer

The $x^ {3}$ term of a Maclaurin series expansion has coefficient

$\frac{f ' '' (0)}{3!}$ = $\frac{f ' '' (0)}{6}$ .

We can find by differentiating three times in succession:

$f(x) = \sinh 3x$

$f'(x) = 3 \cosh 3x$

$f''(x) = 3\cdot 3\sinh 3x = 9\sinh 3x$

$f'''(x) = 9 \cdot 3\cosh 3x = 27 \cosh 3x$

$f'''(0) = 27 \cosh \left (3 \cdot 0 \right ) = 27 \cosh 0 = 27\cdot 1 = 27$

The term we want is therefore

$\frac{f ' '' (0)}{6}$ \cdot $x^{3}$ = $\frac{27}{6}$ \cdot $x^{3}$ = $\frac{9}{2}$ $x^{3}$

← Didn't Know|Knew It →

Question

Give the term of the Maclaurin series expansion of the function $f(x) = x $\tan^{-1}$ x$ .

Tap to reveal answer

Answer

This can most easily be answered by recalling that the Maclaurin series for is

Multiply by to get:

$x $\tan^{-1}$ $x=x^{2 }$ - $\frac{1}{3}$ $x^{4 }$ + $\frac{1}{5}$ $x^{6 }$...$

The term is therefore $- $\frac{1}{3}$ $x^{4 }$$ .

← Didn't Know|Knew It →

Question

Give the $x^ {3}$ term of the Maclaurin series of the function $f(x) = \sinh 3x$ .

Tap to reveal answer

Answer

The $x^ {3}$ term of a Maclaurin series expansion has coefficient

$\frac{f ' '' (0)}{3!}$ = $\frac{f ' '' (0)}{6}$ .

We can find by differentiating three times in succession:

$f(x) = \sinh 3x$

$f'(x) = 3 \cosh 3x$

$f''(x) = 3\cdot 3\sinh 3x = 9\sinh 3x$

$f'''(x) = 9 \cdot 3\cosh 3x = 27 \cosh 3x$

$f'''(0) = 27 \cosh \left (3 \cdot 0 \right ) = 27 \cosh 0 = 27\cdot 1 = 27$

The term we want is therefore

$\frac{f ' '' (0)}{6}$ \cdot $x^{3}$ = $\frac{27}{6}$ \cdot $x^{3}$ = $\frac{9}{2}$ $x^{3}$

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