A basic understanding of differential equations has already been established through our introduction to integration. In addition, rates of change have also been linked to our brief study of differential calculus. Students now require a period of time to work through basic problem solving scenarios relating to both differentiation and integration to develop an acceptable degree of fluency.

Every now and then, a diversion from the “daily grind” can be well-received. Separable differential equations and an introduction to slope fields will be one such “diversion” and will be shared with students when deemed appropriate. Since students are very familiar with quadratic functions, will we begin there.

The equation dy/dx=x will be presented and analyzed from a “rate of change” perspective at various positions on the Cartesian plane. Once this slope field has been sketched, the shape of the parent function becomes readily apparent; the need for initial conditions arises to uniquely define each member from the family.

The image directly below sees through the completion of the scenario described above. This procedure is then repeated for other basic separable differential equations, all of which produce slope fields that are recognizable to students; these appear below our parabola example.

**Differential Equation: dy/dx=kx, where k=2**

*Constant of Proportionality Given*

**Differential Equation: dy/dx=kx^2, where k=3**

*Constant of Proportionality Given*

*Constant of Proportionality Not Given*

**Differential Equation: dy/dx=-x/y**

For the circle above, I’ve included two acceptable treatments.

The **indefinite integrals** require that initial conditions be substituted in after the fact to solve for the constant of integration. The second version has the initial conditions included as bounds of integration, resulting in **definite integrals**; same result.

Solving these differential equations tie together quite nicely the two sides of calculus to which students have been introduced. These examples also set up other such equations and problems that will be presented in the not too distant future, such as Quadratic vs Exponential Growth.

Thanks for reading.

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