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Ordinary Differential Equations MA26600 Spring 2026

Jakayla Robbins

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Handout Lesson 4, Separable Differential Equations and Applications

Textbook Section(s).

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This lesson is based on Section 1.4 of your textbook by Edwards, Penney, and Calvis.
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What is a separable differential equation?

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Definition 23.

A separable differential equation is a first-order differential equation that can be written in the form
\begin{equation*} \frac{dy}{dx}=g(x)f(y)\text{.} \end{equation*}
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Example 24. Identifying separable differential equations.

Which of the following differential equations are separable?
  1. \(\displaystyle \frac{dy}{dx}=2xy^2\)
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  2. \(\displaystyle \frac{dy}{dx}=x+y\)
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  3. \(\displaystyle \frac{dy}{dx}=e^{x+3y}\)
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  4. \(\displaystyle \frac{dy}{dx}=\ln(xy)\)
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Solving separable differential equations.

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\begin{gather} \frac{dy}{dx}=k(y)g(x)\tag{✢} \end{gather}
Claim For \(k(y) \neq 0\text{,}\)
\begin{equation*} \int \frac{1}{k(y)} \, dy = \int g(x) \, dx \end{equation*}
is a solution to (✢).
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Justification:
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Some things to keep in mind:
  • Make sure you add a constant to one side of the equation after you integrate to find a general solution to the differential equation.
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  • To write the general solution explicitly, solve for \(y\) after you integrate AND add a constant.
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Example 25. Solve a separable differential equation.

Solve the differential equation. (Be sure to find both general solutions and any singular solutions.)
\begin{equation*} \frac{dy}{dx} = (y+1)\sin(x) \end{equation*}
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Applications.

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Several applications have DE models of the form
\begin{equation*} \frac{dx}{dt}=kx \end{equation*}
where \(k\) is a constant.
  • If \(k\) is positive, then \(x\) is .
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  • If \(k\) is negative, then \(x\) is .
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Here are some examples,
  1. Populations with constant birth and death rates follow the model:
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  2. If an amount of money is accruing continuously compounded interest, the model
    \begin{equation*} \frac{dA}{dt}=rA \end{equation*}
    applies where
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  3. If a radioactive element is decaying, then the amount, \(N\text{,}\) of the original element remaining at time \(t\) follows the model:
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Definition 27.

A quantity \(x\) grows exponentially if it satisfies the differential equation
\begin{equation*} \frac{dx}{dt}=kx \end{equation*}
and \(k\) is .
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A quantity \(x\) decays exponentially if it satisfies the differential equation
\begin{equation*} \frac{dx}{dt}=kx \end{equation*}
and \(k\) is .
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Example 28. Population growth.

A population has size 20 at time \(t=0\) and size 50 at time \(t=10\text{.}\) Find the size of the population at time \(t=30\text{,}\) assuming that the population grows exponentially.
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Newton’s Law of Cooling.

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If \(T\) is the temperature of an object at time \(t\) in a room with a constant temperature \(A\text{,}\) then the temperature of the object is modeled by
\begin{equation*} \frac{dT}{dt}=k(A-T) \end{equation*}
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Example 29. Newton’s Law of Cooling.

Assume that the normal body temperature of a human is 98.6 degrees Fahrenheit. A corpse is found in a 70Β°F room at noon. The temperature of the corpse was 80Β°F. At 1:00 pm, the temperature of the corpse was 75Β°F. Estimate the time of death.
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