Table of contents
- 0. Functions(0)
- 1. Limits and Continuity(0)
- 2. Intro to Derivatives(0)
- 3. Techniques of Differentiation(0)
- 4. Derivatives of Exponential & Logarithmic Functions(0)
- 5. Applications of Derivatives(0)
- 6. Graphical Applications of Derivatives(0)
- 7. Antiderivatives & Indefinite Integrals(0)
- 8. Definite Integrals(0)
- 9. Graphical Applications of Integrals(0)
- 10. Integrals of Inverse, Exponential, & Logarithmic Functions(0)
- 11. Techniques of Integration(0)
- 12. Trigonometric Functions(0)
- Angles(0)
- Trigonometric Functions on Right Triangles(0)
- Solving Right Triangles(0)
- Trigonometric Functions on the Unit Circle(0)
- Graphs of Sine & Cosine(0)
- Graphs of Other Trigonometric Functions(0)
- Trigonometric Identities(0)
- Derivatives of Trig Functions(0)
- Integrals of Basic Trig Functions(0)
- Integrals of Other Trig Functions(0)
- 13: Intro to Differential Equations(0)
- 14. Sequences & Series(0)
- 15. Power Series(0)
- 16. Probability & Calculus(0)
13: Intro to Differential Equations
Separable Differential Equations
13: Intro to Differential Equations
Separable Differential Equations: Videos & Practice Problems
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Problem 78Multiple Choice
A small object is dropped into a viscous fluid. The forces acting on the object are gravity pulling it downward and a resistance force from the fluid opposing the motion. According to Newton's Second Law, the velocity of the object satisfies the differential equation , where is the mass of the object, is the gravitational acceleration, and is the drag force exerted by the fluid, with positive velocity defined downward. Assume the drag force is proportional to the velocity and acts opposite to the direction of motion, modeled by , where is the drag coefficient. Find the velocity function given the initial condition , and assume the velocity satisfies .
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