holt algebra 2 9-6 modeling real-world data warm up quadratic: y ≈ 2.13x 2 – 2x + 6.12 x35813...

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Holt Algebra 2 9-6 Modeling Real-World Data Warm Up quadratic: y ≈ 2.13x 2 – 2x + 6.12 x 3 5 8 13 y 19 50 126 340 1. Use a calculator to perform quadratic and exponential regressions on the following data. exponential: y ≈ 10.57(1.32) x

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Page 1: Holt Algebra 2 9-6 Modeling Real-World Data Warm Up quadratic: y ≈ 2.13x 2 – 2x + 6.12 x35813 y1950126340 1. Use a calculator to perform quadratic and

Holt Algebra 2

9-6 Modeling Real-World Data

Warm Up

quadratic: y ≈ 2.13x2 – 2x + 6.12

x 3 5 8 13

y 19 50 126 340

1. Use a calculator to perform quadratic and exponential regressions on the following data.

exponential: y ≈ 10.57(1.32)x

Page 2: Holt Algebra 2 9-6 Modeling Real-World Data Warm Up quadratic: y ≈ 2.13x 2 – 2x + 6.12 x35813 y1950126340 1. Use a calculator to perform quadratic and

Holt Algebra 2

9-6 Modeling Real-World Data

Apply functions to problem situations.

Use mathematical models to make predictions.

Objectives

Page 3: Holt Algebra 2 9-6 Modeling Real-World Data Warm Up quadratic: y ≈ 2.13x 2 – 2x + 6.12 x35813 y1950126340 1. Use a calculator to perform quadratic and

Holt Algebra 2

9-6 Modeling Real-World Data

Use constant differences or ratios to determine which parent function would best model the given data set.

Example 1A: Identifying Models by Using Constant Differences or Ratios

Notice that the time data are evenly spaced.

Check the first differences between the heights to see if the data set is linear.

Time (yr) 5 10 15 20 25

Height (in.) 58 93 128 163 198

Page 4: Holt Algebra 2 9-6 Modeling Real-World Data Warm Up quadratic: y ≈ 2.13x 2 – 2x + 6.12 x35813 y1950126340 1. Use a calculator to perform quadratic and

Holt Algebra 2

9-6 Modeling Real-World Data

Example 1A Continued

Because the first differences are a constant 35, a linear model will best model the data.

Height (in.) 58 93 128 163 198

First differences 35 35 35 35 .

Page 5: Holt Algebra 2 9-6 Modeling Real-World Data Warm Up quadratic: y ≈ 2.13x 2 – 2x + 6.12 x35813 y1950126340 1. Use a calculator to perform quadratic and

Holt Algebra 2

9-6 Modeling Real-World DataExample 1B: Identifying Models by Using Constant Differences or

Ratios

Time (yr) 4 8 12 16 20

Population 10,000 9,600 9,216 8,847 8,493

First differences –400 –384 –369 –354

Notice that the time data are evenly spaced. Check the first differences between the populations.

Population 10,000 9,600 9,216 8,847 8,493

Second differences 16 15 15

Neither the first nor second differences are constant. SOOOOO…..Check ratios between the volumes.

Page 6: Holt Algebra 2 9-6 Modeling Real-World Data Warm Up quadratic: y ≈ 2.13x 2 – 2x + 6.12 x35813 y1950126340 1. Use a calculator to perform quadratic and

Holt Algebra 2

9-6 Modeling Real-World DataExample 1B Continued

Neither the first nor second differences are constant. Check ratios between the volumes.

Population 10,000 9,600 9,216 8,847 8,493

960010,000

92169600

88479216

84938847

.96 .96 .96 .96

Because the ratios between the values of the dependent variable are constant, an exponential function would best model the data.

Page 7: Holt Algebra 2 9-6 Modeling Real-World Data Warm Up quadratic: y ≈ 2.13x 2 – 2x + 6.12 x35813 y1950126340 1. Use a calculator to perform quadratic and

Holt Algebra 2

9-6 Modeling Real-World DataExample 1B Continued

Check A scatter plot reveals a shape similar to an exponential decay function.

Write an equation

Page 8: Holt Algebra 2 9-6 Modeling Real-World Data Warm Up quadratic: y ≈ 2.13x 2 – 2x + 6.12 x35813 y1950126340 1. Use a calculator to perform quadratic and

Holt Algebra 2

9-6 Modeling Real-World Data

Example 1C: Identifying Models by Using Constant Differences or Ratios

Time (s) 1 2 3 4 5

Height (m) 132 165 154 99 0

First differences 33 –11 –55 –99

Notice that the time data are evenly spaced. Check the first differences between the heights.

Height (m) 132 165 154 99 0

Second differences –44 –44 –44

Page 9: Holt Algebra 2 9-6 Modeling Real-World Data Warm Up quadratic: y ≈ 2.13x 2 – 2x + 6.12 x35813 y1950126340 1. Use a calculator to perform quadratic and

Holt Algebra 2

9-6 Modeling Real-World Data

Example 1C Continued

Because the second differences of the dependent variables are constant when the independent variables are evenly spaced, a quadratic function will best model the data.Check A scatter reveals a

shape similar to a quadratic parent function f(x) = x2.

Page 10: Holt Algebra 2 9-6 Modeling Real-World Data Warm Up quadratic: y ≈ 2.13x 2 – 2x + 6.12 x35813 y1950126340 1. Use a calculator to perform quadratic and

Holt Algebra 2

9-6 Modeling Real-World Data

Use constant differences or ratios to determine which parent function would best model the given data set.

Notice that the data for the y-values are evenly spaced. Check the first differences between the x-values.

x 12 48 108 192 300

y 10 20 30 40 50

Check It Out! Example 1a

Page 11: Holt Algebra 2 9-6 Modeling Real-World Data Warm Up quadratic: y ≈ 2.13x 2 – 2x + 6.12 x35813 y1950126340 1. Use a calculator to perform quadratic and

Holt Algebra 2

9-6 Modeling Real-World Data

x 12 48 108 192 300

First differences 36 60 84 108

Check It Out! Example 1a Continued

Second differences 24 24 24

Because the second differences of the independent variable are constant when the dependent variables are evenly spaced, a square-root function will best model the data.

Page 12: Holt Algebra 2 9-6 Modeling Real-World Data Warm Up quadratic: y ≈ 2.13x 2 – 2x + 6.12 x35813 y1950126340 1. Use a calculator to perform quadratic and

Holt Algebra 2

9-6 Modeling Real-World Data

x 21 22 23 24

y 243 324 432 576

First differences 81 108 144

Notice that x-values are evenly spaced. Check the differences between the y-values.

y 243 324 432 576

Second differences 27 36

Check It Out! Example 1b

Page 13: Holt Algebra 2 9-6 Modeling Real-World Data Warm Up quadratic: y ≈ 2.13x 2 – 2x + 6.12 x35813 y1950126340 1. Use a calculator to perform quadratic and

Holt Algebra 2

9-6 Modeling Real-World Data

Neither the first nor second differences are constant. Check ratios between the values.

Check It Out! Example 1b Continued

324243

432324

576432

1.33 1.33 1.33

Page 14: Holt Algebra 2 9-6 Modeling Real-World Data Warm Up quadratic: y ≈ 2.13x 2 – 2x + 6.12 x35813 y1950126340 1. Use a calculator to perform quadratic and

Holt Algebra 2

9-6 Modeling Real-World Data

Because the ratios between the values of the dependent variable are constant, an exponential function would best model the data.

Check A scatter reveals a shape similar to an exponential decay function.

Check It Out! Example 1b Continued

Page 15: Holt Algebra 2 9-6 Modeling Real-World Data Warm Up quadratic: y ≈ 2.13x 2 – 2x + 6.12 x35813 y1950126340 1. Use a calculator to perform quadratic and

Holt Algebra 2

9-6 Modeling Real-World Data

To display the correlation coefficient r on some calculators, you must turn on the diagnostic mode.

Press , and choose DiagnosticOn.

Helpful Hint

Page 16: Holt Algebra 2 9-6 Modeling Real-World Data Warm Up quadratic: y ≈ 2.13x 2 – 2x + 6.12 x35813 y1950126340 1. Use a calculator to perform quadratic and

Holt Algebra 2

9-6 Modeling Real-World Data

A printing company prints advertising flyers and tracks its profits. Write a function that models the given data.

Example 2: Economic Application

Flyers Printed 100 200 300 400 500 600

Profit ($) 10 70 175 312 500 720

Step 1 Make a scatter plot of the data. The data appear to form a quadratic or exponential pattern.

Page 17: Holt Algebra 2 9-6 Modeling Real-World Data Warm Up quadratic: y ≈ 2.13x 2 – 2x + 6.12 x35813 y1950126340 1. Use a calculator to perform quadratic and

Holt Algebra 2

9-6 Modeling Real-World Data

Example 2 Continued

Profit ($) 10 70 175 312 500 720

Step 1 Analyze differences.

First differences 60 105 137 188 220

Second differences 45 32 51 32

Because the second differences of the dependent variable are close to constant when the independent variables are evenly spaced, a quadratic function will best model the data.

Page 18: Holt Algebra 2 9-6 Modeling Real-World Data Warm Up quadratic: y ≈ 2.13x 2 – 2x + 6.12 x35813 y1950126340 1. Use a calculator to perform quadratic and

Holt Algebra 2

9-6 Modeling Real-World DataExample 2 Continued

Step 3 Use your graphing calculator to perform a quadratic regression.

A quadratic function that models the data is f(x) = 0.002x2 + 0.007x – 11.2. The correlation r is very close to 1, which indicates a good fit.

Page 19: Holt Algebra 2 9-6 Modeling Real-World Data Warm Up quadratic: y ≈ 2.13x 2 – 2x + 6.12 x35813 y1950126340 1. Use a calculator to perform quadratic and

Holt Algebra 2

9-6 Modeling Real-World Data

Write a function that models the given data.

x 12 14 16 18 20 22 24

y 110 141 176 215 258 305 356

Step 1 Make a scatter plot of the data. The data appear to form a quadratic or exponential pattern.

Check It Out! Example 2

Page 20: Holt Algebra 2 9-6 Modeling Real-World Data Warm Up quadratic: y ≈ 2.13x 2 – 2x + 6.12 x35813 y1950126340 1. Use a calculator to perform quadratic and

Holt Algebra 2

9-6 Modeling Real-World Data

Step 1 Analyze differences.

First differences 31 35 39 43 47 51

Second differences 4 4 4 4 4

Because the second differences of the dependent variable are constant when the independent variables are evenly spaced, a quadratic function will best model the data.

Check It Out! Example 2 Continued

y 110 141 176 215 258 305 356

Page 21: Holt Algebra 2 9-6 Modeling Real-World Data Warm Up quadratic: y ≈ 2.13x 2 – 2x + 6.12 x35813 y1950126340 1. Use a calculator to perform quadratic and

Holt Algebra 2

9-6 Modeling Real-World Data

Step 3 Use your graphing calculator to perform a quadratic regression.

A quadratic function that models the data is f(x) = 0.5x2 + 2.5x + 8. The correlation r is 1, which indicates a good fit.

Check It Out! Example 2 Continued

Page 22: Holt Algebra 2 9-6 Modeling Real-World Data Warm Up quadratic: y ≈ 2.13x 2 – 2x + 6.12 x35813 y1950126340 1. Use a calculator to perform quadratic and

Holt Algebra 2

9-6 Modeling Real-World Data

When data are not ordered or evenly spaced, you may to have to try several models to determine which best approximates the data. Graphing calculators often indicate the value of the coefficient of determination, indicated by r2 or R2. The closer the coefficient is to 1, the better the model approximates the data.

Page 23: Holt Algebra 2 9-6 Modeling Real-World Data Warm Up quadratic: y ≈ 2.13x 2 – 2x + 6.12 x35813 y1950126340 1. Use a calculator to perform quadratic and

Holt Algebra 2

9-6 Modeling Real-World Data

The data shows the population of a small town since 1990. Using 1990 as a reference year, write a function that models the data.

Example 3: Application

The data are not evenly spaced, so you cannot analyze differences or ratios.

Year 1990 1993 1997 2000 2002 2005 2006

Population 400 490 642 787 901 1104 1181

Page 24: Holt Algebra 2 9-6 Modeling Real-World Data Warm Up quadratic: y ≈ 2.13x 2 – 2x + 6.12 x35813 y1950126340 1. Use a calculator to perform quadratic and

Holt Algebra 2

9-6 Modeling Real-World Data

Example 3 Continued

Pop

ulat

ion

year1990

20061997

20022005

1993

400

800

1200

2000

••

••

• •

Create a scatter plot of the data.

Use 1990 as year 0.

The data appear to be quadratic, cubic or exponential.

Page 25: Holt Algebra 2 9-6 Modeling Real-World Data Warm Up quadratic: y ≈ 2.13x 2 – 2x + 6.12 x35813 y1950126340 1. Use a calculator to perform quadratic and

Holt Algebra 2

9-6 Modeling Real-World Data

Use the calculator to perform each type of regression.

Example 3 Continued

Compare the value of r2. The exponential model seems to be the best fit. The function f(x) ≈ 399.94(1.07)x models the data.

Page 26: Holt Algebra 2 9-6 Modeling Real-World Data Warm Up quadratic: y ≈ 2.13x 2 – 2x + 6.12 x35813 y1950126340 1. Use a calculator to perform quadratic and

Holt Algebra 2

9-6 Modeling Real-World Data

Write a function that models the data.

The data are not evenly spaced, so you cannot analyze differences or ratios.

Fertilizer/Acre (lb) 11 14 25 31 40 50

Yield/Acre (bushels) 245 302 480 557 645 705

Check It Out! Example 3

Page 27: Holt Algebra 2 9-6 Modeling Real-World Data Warm Up quadratic: y ≈ 2.13x 2 – 2x + 6.12 x35813 y1950126340 1. Use a calculator to perform quadratic and

Holt Algebra 2

9-6 Modeling Real-World Data

Check It Out! Example 3 Continued

Create a scatter plot of the data.

The data appear to be quadratic, cubic or exponential.

Page 28: Holt Algebra 2 9-6 Modeling Real-World Data Warm Up quadratic: y ≈ 2.13x 2 – 2x + 6.12 x35813 y1950126340 1. Use a calculator to perform quadratic and

Holt Algebra 2

9-6 Modeling Real-World Data

Use the calculator to perform each type of regression.

The function f(x) ≈ –9.3x3 –0.2x2 + 23.97x + 5.46.

Check It Out! Example 3 Continued

Compare the value of r2

The cubic model seems to be the best fit.

Quadratic ExponentialCubic

Page 29: Holt Algebra 2 9-6 Modeling Real-World Data Warm Up quadratic: y ≈ 2.13x 2 – 2x + 6.12 x35813 y1950126340 1. Use a calculator to perform quadratic and

Holt Algebra 2

9-6 Modeling Real-World DataLesson Quiz

quadratic; C(l) = 2.5x2 + 40

1. Use finite differences or ratios to determine which parent function would best model the given data set, and write a function that models the data.

Length (ft) 5 10 15 20 25

Cost ($) 102.50 290.00 602.50 1040.00 1602.50

f(x) = 1.085(1.977)x

2. Write a function that models the given data.Time (min) 0 2 4 6 8 10

Volume (cm2) 1.2 3.9 15.7 64.2 256.5 1023.8