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)
6. Graphical Applications of Derivatives
Applied Optimization
6. Graphical Applications of Derivatives
Applied Optimization: Videos & Practice Problems
35 of 0
Problem 35Multiple Choice
The shaded region in the figure is called an arbelos, formed by three mutually tangent semicircles. The incircle is the largest circle that can fit inside the arbelos, and it is tangent to all three semicircles. If the largest semicircle has a diameter of , what should be the diameter of one of the smaller semicircles to maximize the radius of the incircle ? Note that the radius of the incircle can be expressed in terms of the diameters of the two smaller semicircles as follows:

0 Comments