3: Applications of First Order Equations

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Page ID: 153567

Hung Dinh
Chabot College

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In this chapter, we consider applications of first order differential equations.

3.1: Growth and Decay
This section begins with a discussion of exponential growth and decay, which you have probably already seen in calculus. We consider applications to radioactive decay, carbon dating, and compound interest. We also consider more complicated problems where the rate of change of a quantity is in part proportional to the magnitude of the quantity, but is also influenced by other other factors for example, a radioactive susbstance is manufactured at a certain rate, but decays at a rate proportional
- 3.1E: Growth and Decay (Exercises)
3.2: Cooling and Mixing
This section deals with applications of Newton's law of cooling and with mixing problems.
- 3.2E: Cooling and Mixing (Exercises)
3.3: Elementary Mechanics
This section discusses applications to elementary mechanics involving Newton's second law of motion. The problems considered include motion under the influence of gravity in a resistive medium, and determining the initial velocity required to launch a satellite.
- 3.3E: Elementary Mechanics (Exercises)
3.4: Autonomous Second Order Equations
This section deals with methods for dealing with a type of second order equation that often arises in applications of Newton's second law of motion, by reformulating it as first order equation with a different independent variable. Although the method doesn't usually lead to an explicit solution of the given equation, it does provide valuable insights into the behavior of the solutions.
- 3.4E: Autonomous Second Order Equations (Exercises)
3.5: Applications to Curves
This section deals with applications of differential equations to curves.
- 3.5E: Applications to Curves (Exercises)

Thumbnail: False color time-lapse video of E. coli colony growing on microscope slide. This growth can be model with first order logistic equation. Added approximate scale bar based on the approximate length of 2.0 μm of E. coli bacteria. (CC BY-SA 4.0 International; Stewart EJ, Madden R, Paul G, Taddei F).

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