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3.2

3.2. Demana, Waits, Foley, Kennedy. Exponential and Logistic Modeling. What you’ll learn about. Constant Percentage Rate and Exponential Functions Exponential Growth and Decay Models Using Regression to Model Population Other Logistic Models … and why

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3.2

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  1. 3.2 Demana, Waits, Foley, Kennedy Exponential and Logistic Modeling

  2. What you’ll learn about • Constant Percentage Rate and Exponential Functions • Exponential Growth and Decay Models • Using Regression to Model Population • Other Logistic Models … and why Exponential functions model many types of unrestricted growth; logistic functions model restricted growth, including the spread of disease and the spread of rumors.

  3. Constant Percentage Rate Suppose that a population is changing at a constant percentage rate r, where r is the percent rate of change expressed in decimal form. Then the population follows the pattern shown.

  4. Exponential Population Model

  5. Example: Finding Growth and Decay Rates

  6. Solution

  7. Example: Finding an Exponential Function Determine the exponential function with initial value = 10, increasing at a rate of 5% per year.

  8. Solution Determine the exponential function with initial value = 10, increasing at a rate of 5% per year.

  9. Example: Modeling Bacteria Growth

  10. Solution

  11. Atmospheric pressure • Scientists have established that atmospheric pressure at sea level is 14.7 lb/in^2, and the pressure reduces by half for each 3.6 miles above sea-level. This rule holds for up to 50 miles above sea-level. • Find the altitude for which the atmospheric pressure is 4 lb/in^2

  12. Example: Modeling U.S. Population Using Exponential Regression Use the population data in the table to predict the population for the year 2000. Compare with the actual 2000 population of approximately 281 million.

  13. Solution Let x = 0 represent 1890, x = 1 represent 1900, and so on. The year 2000 is represented by x = 11. Create a scatter plot of the data following the steps below.

  14. Solution Enter the data into the statistical memory of your grapher.

  15. Solution Set an appropriate window for the data, letting x correspond to the year and y to the population (in millions). Note that the year 1980 corresponds to x = 9.

  16. Solution Make a scatter plot.

  17. Solution Choose the ExpReg option from your grapher’s regression menu, using L1 for the x-values and L2 as y-values.

  18. Solution The regression equation is f(x) = 66.99(1.15x).

  19. Solution Graph both the scatter plot and the regression equation. Use the CALC-VALUE option to find f (11).

  20. Solution The year 2000 is represented by x =11, and f (11) = 311.66. Interpret This exponential model estimates the 2000 population to be 311.66 million, an overestimate of approximately 31 million.

  21. Maximum Sustainable Population Exponential growth is unrestricted, but population growth often is not. For many populations, the growth begins exponentially, but eventually slows and approaches a limit to growth called the maximum sustainable population.

  22. Example: Modeling a Rumor

  23. Solution

  24. Solution

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