1 / 23

Simple Rules for Differentiation

Simple Rules for Differentiation. Objectives. Students will be able to Apply the power rule to find derivatives. Calculate the derivatives of sums and differences. Rules. Power Rule For the function , for all arbitrary constants a. Rules.

orrick
Download Presentation

Simple Rules for Differentiation

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Simple Rules for Differentiation

  2. Objectives Students will be able to • Apply the power rule to find derivatives. • Calculate the derivatives of sums and differences.

  3. Rules Power Rule • For the function , for all arbitrary constants a.

  4. Rules Sums and Differences Rule • If both f and g are differentiable at x, then the sum and the difference are differentiable at x and the derivatives are as follows.

  5. Rules Sums and Differences Rule • If both f and g are differentiable at x, then the sum and the difference are differentiable at x and the derivatives are as follows.

  6. Example 1 Use the simple rules of derivatives to find the derivative of

  7. Example 2 Use the simple rules of derivatives to find the derivative of

  8. Example 3 Use the simple rules of derivatives to find the derivative of

  9. Example 4 Use the simple rules of derivatives to find the derivative of

  10. Example 5 Use the simple rules of derivatives to find the derivative of

  11. Example 6 Find the slope of the tangent line to the graph of the function at x = 9. Then find the equation of the tangent line.

  12. Example 7 Find all value(s) of x where the tangent line to the function below is horizontal.

  13. Example 8 Assume that a demand equation is given by Find the marginal revenue for the following levels (values of q). (Hint: Solve the demand equation for p and use the revenue equation R(q) = qp .) • q = 1000 units • q = 2500 units • q = 3000 units

  14. Example 9-1 An analyst has found that a company’s costs and revenues in dollars for one product are given by the functions and respectively, where x is the number of items produced. a. Find the marginal cost function.

  15. Example 9-2 An analyst has found that a company’s costs and revenues in dollars for one product are given by the functions and respectively, where x is the number of items produced. b. Find the marginal revenue function.

  16. Example 9-3 An analyst has found that a company’s costs and revenues in dollars for one product are given by the functions and respectively, where x is the number of items produced. c. Using the fact that profit is the difference between revenue and costs, find the marginal profit function.

  17. Example 9-4 An analyst has found that a company’s costs and revenues in dollars for one product are given by the functions and respectively, where x is the number of items produced. d. What value of x makes the marginal profit equal 0?

  18. Example 9-5 An analyst has found that a company’s costs and revenues in dollars for one product are given by the functions and respectively, where x is the number of items produced. e. Find the profit when the marginal profit is 0.

  19. Example 10-1 The total amount of money in circulation for the years 1915-2002 can be closely approximated by where t represents the number of years since 1900 and M(t) is in millions of dollars. Find the derivative of M(t) and use it to find the rate of change of money in circulation in the following years. a. 1920

  20. Example 10-2 The total amount of money in circulation for the years 1915-2002 can be closely approximated by where t represents the number of years since 1900 and M(t) is in millions of dollars. Find the derivative of M(t) and use it to find the rate of change of money in circulation in the following years. b. 1960

  21. Example 10-3 The total amount of money in circulation for the years 1915-2002 can be closely approximated by where t represents the number of years since 1900 and M(t) is in millions of dollars. Find the derivative of M(t) and use it to find the rate of change of money in circulation in the following years. c. 1980

  22. Example 10-4 The total amount of money in circulation for the years 1915-2002 can be closely approximated by where t represents the number of years since 1900 and M(t) is in millions of dollars. Find the derivative of M(t) and use it to find the rate of change of money in circulation in the following years. d. 2000

  23. Example 10-5 The total amount of money in circulation for the years 1915-2002 can be closely approximated by where t represents the number of years since 1900 and M(t) is in millions of dollars. Find the derivative of M(t) and use it to find the rate of change of money in circulation in the following years. e. What do your answers to parts a-d tell you about the amount of money in circulation in those years?

More Related