# Linear Growth Models - population scenarios

Develop four different population scenarios for a town. As a group, you will decide on the name of the town and the initial population. You will graph the function for each population scenario and use your model to make some decisions about the population.

1) Decide on a name of a rural town.

2) Decide on an initial population, , of the town in the year 2010. Choose an initial population between 5,000��"10,000. Use this value of for each of the scenarios.

3) You will investigate four different scenarios of population growth or decline in this town.

- Linear growth

- Growth modeled by a quadratic equation

- Growth modeled by a radical equation

- Population decline modeled by a rational equation

I. Linear Growth:

Suppose that the amount that your town’s population grows each year is fixed (or constant).

Choose the amount of population growth each year = _______

(Hint: Choose a whole number for your growth rate, rather than a percent.)

a) Fill in the following chart:

Year (t) Population (P)

t = 0

(2010) ______

t = 1

(2011)

t = 2

(2012)

t = 3

(2013)

t = 6

(2016)

b) Find a linear equation in the form P = mt + b (y = mx + b), which gives the population, P, t years from 2010.

Answer:

Show your work here:

c) Use your equation in part b to approximate the population in the year 2020.

Answer:

Show your work here:

d) Use your equation in part b to approximate how many years it will take the population to reach 12,000. Round to the nearest whole year when necessary.

Answer:

Show your work here:

e) Graph this function in MS Excel by plotting the points found in your chart in part a. You may also use another web-based graphing utility. Label your axes with time on the x-axis and population on the y-axis. Copy and paste your graph here:

Answer:

II. Quadratic Growth:

Suppose instead that the town experiences quadratic growth of the form

where t is the time in years from 2010.

a) Insert the value of that your group has decided upon into the equation. Use t^2 to type t-squared.

Answer:

b) Fill in the following chart.

Year (t) Population (P)

t = 0

(2010) _______

t = 1

(2011)

t = 2

(2012)

t = 3

(2013)

t = 6

(2016)

c) Use your equation from part a to approximate how many years it will take for the population to reach 12,000. Round to the nearest whole year when necessary.

Answer:

Show your work here:

d) Graph this function in MS Excel by plotting the points found in your chart in part b. You may also use another web-based graphing utility. Label your axes with time on the x-axis and population on the y-axis. Copy and paste your graph here:

Answer:

III. Growth Modeled by a Radical Equation:

Suppose instead that the town experiences growth that can be modeled by the following: where t is the number of years from 2010.

a) Insert the value of that your group has decided upon into the equation above. Use the Equation Editor or type square root of t as sqrt(t).

Answer:

b) Fill in the following chart. Round to the nearest whole person when necessary.

Year (t) Population (P)

t = 0

(2010) _______

t = 1

(2011)

t = 2

(2012)

t = 3

(2013)

t = 6

(2016)

c) Use your equation from part a) to approximate how many years it would take for the population to reach 12,000. Round the nearest whole year when necessary.

Answer:

Show your work here:

d) Graph this function in MS Excel by plotting the points found in your chart in part b. You may also use another web-based graphing utility. Label your axes with time on the x-axis and population on the y-axis. Copy and paste your graph here:

Answer:

IV. Population Decline Modeled by a Rational Equation:

Suppose instead that the town experiences population decline that can be modeled by the following: where t is the number of years from 2010.

a) Insert the value of that your group has agreed to use.

Type as ( ) / (t + 1) or use the Equation Editor.

Answer:

b) Fill in the following chart. Round to the nearest whole person when necessary.

Year (t) Population (P)

t = 0

(2010) ________

t = 1

(2011)

t = 2

(2012)

t = 3

(2013)

t = 6

(2016)

c) Use your equation from part a) to approximate how many years it would take for the population to reach 400. Round to two decimal places if necessary.

Answer:

Show your work here:

d) Graph this function in MS Excel by plotting the points in the chart in part b. You may also use another web-based graphing utility. Label your axes with time on the x-axis and population on the y-axis. Copy and paste graph here:

Answer:

V. Suppose that the mayor of the town you have chosen has built a new factory in hopes of drawing as many new people to the town as possible. Which one of the four models would the mayor hope that the population would follow? Explain.

© BrainMass Inc. brainmass.com October 25, 2018, 2:42 am ad1c9bdddfhttps://brainmass.com/math/basic-algebra/311520

#### Solution Summary

A complete, neat and step-by-step solution is provided in the attached file.

Modeling Population Growth

Your group will develop four different population scenarios for a town. As a group, you will decide on the name of the town and the initial population. You will graph the function for each population scenario and use your model to make some decisions about the population.

1) Decide on a name of a rural town.

2) Decide on an initial population, , of the town in the year 2010. Choose an initial population between 5,000-10,000. Use this value of for each of the scenarios.

3) You will investigate four different scenarios of population growth or decline in this town.

? Linear growth

? Growth modeled by a quadratic equation

? Growth modeled by a radical equation

? Population decline modeled by a rational equation

I. Linear Growth:

Suppose that the amount that your town's population grows each year is fixed (or constant).

Choose the amount of population growth each year = _______

(Hint: Choose a whole number for your growth rate, rather than a percent.)

a) Fill in the following chart:

Year (t) Population (P)

t = 0

(2010) ______

t = 1

(2011)

t = 2

(2012)

t = 3

(2013)

t = 6

(2016)

b) Find a linear equation in the form P = mt + b (y = mx + b), which gives the population, P, t years from 2010.

Answer:

Show your work here:

c) Use your equation in part b to approximate the population in the year 2020.

Answer:

Show your work here:

d) Use your equation in part b to approximate how many years it will take the population to reach 12,000. Round to the nearest whole year when necessary.

Answer:

Show your work here:

e) Graph this function in MS Excel by plotting the points found in your chart in part a. You may also use another web-based graphing utility. Label your axes with time on the x-axis and population on the y-axis. Copy and paste your graph here:

Answer:

II. Quadratic Growth:

Suppose instead that the town experiences quadratic growth of the form

where t is the time in years from 2010.

a) Insert the value of that your group has decided upon into the equation. Use t^2 to type t-squared.

Answer:

b) Fill in the following chart.

Year (t) Population (P)

t = 0

(2010) _______

t = 1

(2011)

t = 2

(2012)

t = 3

(2013)

t = 6

(2016)

c) Use your equation from part a to approximate how many years it will take for the population to reach 12,000. Round to the nearest whole year when necessary.

Answer:

Show your work here:

d) Graph this function in MS Excel by plotting the points found in your chart in part b. You may also use another web-based graphing utility. Label your axes with time on the x-axis and population on the y-axis. Copy and paste your graph here:

Answer:

III. Growth Modeled by a Radical Equation:

Suppose instead that the town experiences growth that can be modeled by the following: where t is the number of years from 2010.

a) Insert the value of that your group has decided upon into the equation above. Use the Equation Editor or type square root of t as sqrt(t).

Answer:

b) Fill in the following chart. Round to the nearest whole person when necessary.

Year (t) Population (P)

t = 0

(2010) _______

t = 1

(2011)

t = 2

(2012)

t = 3

(2013)

t = 6

(2016)

c) Use your equation from part a) to approximate how many years it would take for the population to reach 12,000. Round the nearest whole year when necessary.

Answer:

Show your work here:

Answer:

IV. Population Decline Modeled by a Rational Equation:

Suppose instead that the town experiences population decline that can be modeled by the following: where t is the number of years from 2010.

a) Insert the value of that your group has agreed to use.

Type as ( ) / (t + 1) or use the Equation Editor.

Answer:

b) Fill in the following chart. Round to the nearest whole person when necessary.

Year (t) Population (P)

t = 0

(2010) ________

t = 1

(2011)

t = 2

(2012)

t = 3

(2013)

t = 6

(2016)

c) Use your equation from part a) to approximate how many years it would take for the population to reach 400. Round to two decimal places if necessary.

Answer:

Show your work here:

d) Graph this function in MS Excel by plotting the points in the chart in part b. You may also use another web-based graphing utility. Label your axes with time on the x-axis and population on the y-axis. Copy and paste graph here:

Answer:

V.

Suppose that the mayor of the town you have chosen has built a new factory in hopes of drawing as many new people to the town as possible. Which one of the four models would the mayor hope that the population would follow? Explain.