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5: Power Series

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    A power series (in one variable) is an infinite series. Any polynomial can be easily expressed as a power series around any center c, although most of the coefficients will be zero since a power series has infinitely many terms by definition. One can view power series as being like "polynomials of infinite degree," although power series are not polynomials. The content in this Textmap's chapter is complemented by Guichard's Calculus Textmap.

    • 5.1: Power Series and Functions
      This section introduces power series, expressing functions as infinite series in terms of powers of \(x\). It covers convergence intervals, techniques to find these intervals, and how to represent functions using power series. Examples illustrate how to build power series representations for various functions, setting the stage for using series in calculus applications like function approximation and solving differential equations.
    • 5.2: Properties of Power Series
      Power series can be combined, differentiated, or integrated to create new power series. This capability is particularly useful for a couple of reasons. First, it allows us to find power series representations for certain elementary functions, by writing those functions in terms of functions with known power series. Second, it allows us to define new functions that cannot be written in terms of elementary functions. This capability is particularly useful for solving differential equations.
    • 5.3: Taylor and Maclaurin Series
      Here we discuss power series representations for other types of functions. In particular, we address the following questions: Which functions can be represented by power series and how do we find such representations? If we can find a power series representation for a particular function ff and the series converges on some interval, how do we prove that the series actually converges to f?
    • 5.4: Working with Taylor Series
      In this section we show how to use those Taylor series to derive Taylor series for other functions. We then present two common applications of power series. First, we show how power series can be used to solve differential equations. Second, we show how power series can be used to evaluate integrals when the antiderivative of the integrand cannot be expressed in terms of elementary functions.
    • 5.5: Chapter 5 Review Exercises

    Thumbnail: The graph shows the function \(\displaystyle y=sinx\) and the Maclaurin polynomials \(\displaystyle p_1,p_3\) and \(\displaystyle p_5\). (CC BY-SA 3.0; OpenStax).

    This page titled 5: Power Series is shared under a CC BY-NC-SA 4.0 license and was authored, remixed, and/or curated by Roy Simpson.

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      Roy Simpson
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