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12: Solving Differential Equations

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    121145

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    In Chapter 11, we introduced differential equations to keep track of continuous changes in the growth of a population or the decay of radioactivity. We encountered a differential equation that tracks changes in cell mass due to nutrient absorption and consumption. Finally, we learned that the solutions to a differential equation is a function. In applications studied, that function can be interpreted as predictions of the behavior of the system or process over time.

    In this chapter, we further develop some of these ideas. We explore several techniques for finding and verifying that a given function is a solution to a differential equation. We then examine a simple class of differential equations that have many applications to processes of production and decay, and find their solutions. Finally, we show how an approximation method provides for numerical solutions of such problems.

    • 12.1: Verifying that a Function is a Solution
      In this section we concentrate on analytic solutions to a differential equation. By analytic solution, we mean a "formula" such as y=f(x) that satisfies the given differential equation. We saw in Chapter 11 that we can check whether a function satisfies a differential equation by simple differentiation. In this section, we further demonstrate this process.
    • 12.2: Equations of the Form- y'(t) = a−by
      In this section we introduce an important class of differential equations that have many applications in physics, chemistry, biology, and other applications.
    • 12.3: Euler’s Method and Numerical Solutions
      We sometimes need a method for computing an approximation for the desired solution - referred to as a "numerical solution". The idea is to harness a computational device to find numerical values of points along the solution curve, rather than attempting to determine the formula for the solution as a function of time. We illustrate this process using a technique called Euler’s method, which is based on an approximation of a derivative by the slope of a secant line.
    • 12.4: Summary
    • 12.5: Exercises

    This page titled 12: Solving Differential Equations is shared under a CC BY-NC-SA 4.0 license and was authored, remixed, and/or curated by Leah Edelstein-Keshet via source content that was edited to the style and standards of the LibreTexts platform.