Explanation Consider a function f and expand the function f in a fourth Taylor polynomial about a point x 0 and evaluate x 0 − h and x 0 + h . f ( x 0 + h ) = f ( x 0 ) + f ′ ( x 0 ) h + 1 2 f ″ ( x 0 ) h 2 + 1 6 f ‴ ( x 0 ) h 3 + 1 24 f ( 4 ) ( x 0 ) h 4 + 1 120 h 5 f ( 5 ) ( ξ ) f ( x 0 − h ) = f ( x 0 ) − f ′ ( x 0 ) h + 1 2 f ″ ( x 0 ) h 2 − 1 6 f ‴ ( x 0 ) h 3 + 1 24 f ( 4 ) ( x 0 ) h 4 + 1 120 h 5 f ( 5 ) ( ξ − 1 ) Where x 0 − h < ξ − 1 < x 0 < ξ 1 < x 0 + h . It is know that the Taylor polynomial of f ‴ ( x 0 ) is given as follows. f ‴ ( x 0 ) = 1 h 3 ( − 1 2 f ( x 0 − 2 h ) + f ( x 0 − h ) − f ( x 0 + h ) + 1 2 f ( x 0 + 2 h ) ) − h 2 4 f 5 ( ξ ) Where ξ lies between x 0 − 2 h and x 0 + 2 h . Add these two equations and cancel like terms as shown below

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ISBN: 9781305253667

Author: Richard L. Burden, J. Douglas Faires, Annette M. Burden

Publisher: Cengage Learning

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Chapter 4.1, Problem 2DQ

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To derive: A method for approximating f(x0) whose error term is of order h2, by expanding the function f in a fourth Taylor polynomial about x0 and evaluating at x0+2h.

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Chapter 4.1, Problem 1DQ

Chapter 4.2, Problem 1ES

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Chapter 4 Solutions

Numerical Analysis

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To derive: A method for approximating f ( x 0 ) whose error term is of order h 2 , by expanding the function f in a fourth Taylor polynomial about x 0 and evaluating at x 0 + 2 h .

Solution Summary: The author explains a method for approximating f(x_0) whose error term is of order h2.

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To derive: A method for approximating f(x0) whose error term is of order h2, by expanding the function f in a fourth Taylor polynomial about x0 and evaluating at x0+2h.

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Chapter 4 Solutions