Review: exponential growth and Decay functions
Feb 23, 2016
Review: exponential growth and Decay
functions
In this lesson, you will review how to write an exponential growth and decay function modeling a percent of increase situation or decrease situation by interpreting the percent of increase as a growth factor or percent of decrease as a decay factor.
Review: exponential growth functions
Exponential growth happens by repeated multiplication by the same number.
Review: exponential growth functions
A certain species of bacteria will double in population each week in a laboratory.
Review: exponential growth functions
A certain species of bacteria will double in population each week in a laboratory.
review: exponential growth functions
A certain species of bacteria will double in population each week in a laboratory.
(ππ°πππ€π¬ ,πππππππ«π’π )
review: exponential growth functions
A certain species of bacteria will double in population each week in a laboratory.
(ππ°πππ€π¬ ,πππππππ«π’π)
review: exponential growth functions
A certain species of bacteria will double in population each week in a laboratory.
(ππ°πππ€π¬ ,πππππππ«π’π)
review: exponential growth functions
A certain species of bacteria will double in population each week in a laboratory.
(ππ°πππ€π¬ ,πππππππ«π’π )
review: exponential growth functions
A certain species of bacteria will double in population each week in a laboratory.
(ππ°πππ€π¬ ,ππππππππ«π’π)
review: exponential growth functions
A certain species of bacteria will double in population each week in a laboratory.
(ππ°πππ€π¬ ,ππππππππ«π’π)
A certain species of bacteria will double in population each week in a laboratory.
review: exponential growth functions
(ππ°πππ€π¬ ,ππππππππ«π’π)
review: exponential growth functions
A certain species of bacteria will double in population each week in a laboratory.
Review: exponential growth functions
A certain species of bacteria will double in population each week in a laboratory.
The growth factor is 2.
review: exponential growth functions
A certain species of bacteria will double in population each week in a laboratory. Suppose you initially have 25 specimens of this bacteria.
review: exponential growth functions
A certain species of bacteria will double in population each week in a laboratory. Suppose you initially have 25 specimens of this bacteria.
review: exponential growth functions
A certain species of bacteria will double in population each week in a laboratory. Suppose you initially have 25 specimens of this bacteria.
(ππ°πππ€π¬ ,ππππππππ«π’π )
review: exponential growth functions
A certain species of bacteria will double in population each week in a laboratory. Suppose you initially have 25 specimens of this bacteria.
(ππ°πππ€π¬ ,ππππππππ«π’π )
review: exponential growth functions
A certain species of bacteria will double in population each week in a laboratory. Suppose you initially have 25 specimens of this bacteria.
(ππ°πππ€π¬ ,πππππππππ«π’π)
review: exponential growth functions
A certain species of bacteria will double in population each week in a laboratory. Suppose you initially have 25 specimens of this bacteria.
(ππ°πππ€π¬ ,πππππππππ«π’π)
review: exponential growth functions
A certain species of bacteria will double in population each week in a laboratory. Suppose you initially have 25 specimens of this bacteria.
(ππ°πππ€π¬ ,πππππππππ«π’π)
The initial value is 25.
review: exponential growth functions
A certain species of bacteria will double in population each week in a laboratory. Suppose you initially have 25 specimens of this bacteria.
(ππ°πππ€π¬ ,πππππππππ«π’π)π₯ π¦
review: exponential growth functions
A certain species of bacteria will double in population each week in a laboratory. Suppose you initially have 25 specimens of this bacteria.
(ππ°πππ€π¬ ,πππππππππ«π’π)
Let x = number of time periods since growth began
π π¦
review: exponential growth functions
A certain species of bacteria will double in population each week in a laboratory. Suppose you initially have 25 specimens of this bacteria.
(ππ°πππ€π¬ ,πππππππππ«π’π)
Let x = number of time periods since growth beganLet y = amount of the growing quantity
ππ₯
review: exponential growth functions
A certain species of bacteria will double in population each week in a laboratory. Suppose you initially have 25 specimens of this bacteria.
(ππ°πππ€π¬ ,πππππππππ«π’π)
Let x = number of time periods since growth beganLet y = amount of the growing quantity
π¦π₯
review: exponential growth functions
A certain species of bacteria will double in population each week in a laboratory. Suppose you initially have 25 specimens of this bacteria.
(π ,πππ)
Let x = number of time periods since growth beganLet y = amount of the growing quantity
review: exponential growth functions
A certain species of bacteria will double in population each week in a laboratory. Suppose you initially have 25 specimens of this bacteria.
Let x = number of time periods since growth beganLet y = amount of the growing quantity
π=()()πgrowth factorinitial value (π ,πππ)
review: exponential growth functions
A certain species of bacteria will double in population each week in a laboratory. Suppose you initially have 25 specimens of this bacteria.
Let x = number of time periods since growth beganLet y = amount of the growing quantity
π=()()πgrowth factorinitial value (π ,πππ)
review: exponential growth functions
A certain species of bacteria will double in population each week in a laboratory. Suppose you initially have 25 specimens of this bacteria.
Let x = number of time periods since growth beganLet y = amount of the growing quantity
π=()()πinitial value (π ,πππ)
2
review: exponential growth functions
A certain species of bacteria will double in population each week in a laboratory. Suppose you initially have 25 specimens of this bacteria.
Let x = number of time periods since growth beganLet y = amount of the growing quantity
π=()()πinitial value (π ,πππ)
2
review: exponential growth functions
A certain species of bacteria will double in population each week in a laboratory. Suppose you initially have 25 specimens of this bacteria.
Let x = number of time periods since growth beganLet y = amount of the growing quantity
π=()()π(π ,πππ)
225
review: exponential growth functions
A certain species of bacteria will double in population each week in a laboratory. Suppose you initially have 25 specimens of this bacteria.
Let x = number of time periods since growth beganLet y = amount of the growing quantity
π=(ππ)(π)π(π ,πππ)
π=(ππ)(π)π(π ,πππ)
π=(ππ)(π)π
(π ,πππ)
π=(ππ)(π)π
(π ,πππ)
π=(ππ)(π)π
(π ,πππ)
π=(ππ)(π)π
(π ,πππ)
π=(ππ)(π)π
(π ,πππ)
π=(ππ)(π)π
(π ,πππ)
interpreting a percent of increase as a growth factor
interpreting a percent of increase as a growth factor The amount of money in your savings account increased by 3% last year.
interpreting a percent of increase as a growth factor The amount of money in your savings account increased by 3% last year.
What does it mean to grow by 3%?
interpreting a percent of increase as a growth factor The amount of money in your savings account increased by 3% last year.
What does it mean to grow by 3%?
interpreting a percent of increase as a growth factor The amount of money in your savings account increased by 3% last year.
What does it mean to grow by 3%?
1
interpreting a percent of increase as a growth factor The amount of money in your savings account increased by 3% last year.
What does it mean to grow by 3%?
1 2 3
interpreting a percent of increase as a growth factor The amount of money in your savings account increased by 3% last year.
What does it mean to grow by 3%?
1
interpreting a percent of increase as a growth factor The amount of money in your savings account increased by 3% last year.
What does it mean to grow by 3%?
3%=0.03
1
interpreting a percent of increase as a growth factor The amount of money in your savings account increased by 3% last year.
What does it mean to grow by 3%?
13%=0.03
interpreting a percent of increase as a growth factor The amount of money in your savings account increased by 3% last year.
What does it mean to grow by 3%?
0.033%=0.03
interpreting a percent of increase as a growth factor The amount of money in your savings account increased by 3% last year.
What does it mean to grow by 3%?
13%=0.03
interpreting a percent of increase as a growth factor The amount of money in your savings account increased by 3% last year.
What does it mean to grow by 3%?
13%=0.03
interpreting a percent of increase as a growth factor The amount of money in your savings account increased by 3% last year.
What does it mean to grow by 3%?
13%=0.03
interpreting a percent of increase as a growth factor The amount of money in your savings account increased by 3% last year.
What does it mean to grow by 3%?
0.03
13%=0.03
interpreting a percent of increase as a growth factor The amount of money in your savings account increased by 3% last year.
What does it mean to grow by 3%?
0.03
13%=0.03
interpreting a percent of increase as a growth factor The amount of money in your savings account increased by 3% last year.
What does it mean to grow by 3%?
0.03
13%=0.03
interpreting a percent of increase as a growth factor The amount of money in your savings account increased by 3% last year.
What does it mean to grow by 3%?
0.03
13%=0.03
interpreting a percent of increase as a growth factor The amount of money in your savings account increased by 3% last year.
What does it mean to grow by 3%?
0.031
3%=0.03
interpreting a percent of increase as a growth factor The amount of money in your savings account increased by 3% last year.
What does it mean to grow by 3%?
0.0313%=0.03
interpreting a percent of increase as a growth factor The amount of money in your savings account increased by 3% last year.
What does it mean to grow by 3%?
0.0313%=0.03
interpreting a percent of increase as a growth factor The amount of money in your savings account increased by 3% last year.
What does it mean to grow by 3%?
1+0.033%=0.03
interpreting a percent of increase as a growth factor The amount of money in your savings account increased by 3% last year.
What does it mean to grow by 3%?
1 .033%=0.03
interpreting a percent of increase as a growth factor The amount of money in your savings account increased by 3% last year.
What does it mean to grow by 3%?
is the growth factor!3%=0.03
an example
an exampleA certain savings account pays 2% interest per year. You open one of these accounts and put $300 into the account. Assume you do not take out or put in any money from the account after the initial $300. Write a two-variable equation modeling the situation. Be sure to define the variables.
an exampleA certain savings account pays 2% interest per year. You open one of these accounts and put $300 into the account. Assume you do not take out or put in any money from the account after the initial $300. Write a two-variable equation modeling the situation. Be sure to define the variables.
an exampleA certain savings account pays 2% interest per year. You open one of these accounts and put $300 into the account. Assume you do not take out or put in any money from the account after the initial $300. Write a two-variable equation modeling the situation. Be sure to define the variables.
an exampleA certain savings account pays 2% interest per year. You open one of these accounts and put $300 into the account. Assume you do not take out or put in any money from the account after the initial $300. Write a two-variable equation modeling the situation. Be sure to define the variables.
Growth factor:
an exampleA certain savings account pays 2% interest per year. You open one of these accounts and put $300 into the account. Assume you do not take out or put in any money from the account after the initial $300. Write a two-variable equation modeling the situation. Be sure to define the variables.
Growth factor:
In this lesson, you will learn to write an exponential decay function modeling a percent of decrease situation by interpreting the percent of decrease as a decay factor.
Review: exponential growth and exponential decay
π¦=ΒΏ
Review: exponential growth and exponential decay
π¦=ΒΏ
If the change factor is greater than 1:
Review: exponential growth and exponential decay
π¦=ΒΏ
If the change factor is greater than 1:
exponential growth
Review: exponential growth and exponential decay
π¦=ΒΏ
If the change factor is greater than 1:
exponential growth(growth factor)
Review: exponential growth and exponential decay
π¦=ΒΏ
If the change factor is greater than 1:
If the change factor is between 0 and 1:
exponential growth(growth factor)
Review: exponential growth and exponential decay
π¦=ΒΏ
If the change factor is greater than 1:
If the change factor is between 0 and 1:
exponential growth(growth factor)
exponential decay
Review: exponential growth and exponential decay
π¦=ΒΏ
If the change factor is greater than 1:
If the change factor is between 0 and 1:
exponential growth(growth factor)
exponential decay(decay factor)
Review: exponential growth and exponential decay
growth factor (greater than 1)
decay factor (less than 1)
Review: exponential growth and exponential decay
growth factor (greater than 1)
decay factor (less than 1)
Example: 2
review: exponential growth and exponential decay
growth factor (greater than 1)
decay factor (less than 1)
Example: 2
Review: exponential growth and exponential decay
1
growth factor (greater than 1)
decay factor (less than 1)
Example: 2 becomes
Review: exponential growth and exponential decay
1
growth factor (greater than 1)
decay factor (less than 1)
Example: 2 becomes
Review: exponential growth and exponential
decay
1 2
growth factor (greater than 1)
decay factor (less than 1)
Example: 2
Example:
becomes
Review: exponential growth and exponential
decay
1 2
growth factor (greater than 1)
decay factor (less than 1)
Example: 2
Example:
becomes
Review: exponential growth and exponential
decay
1 2
1
growth factor (greater than 1)
decay factor (less than 1)
Example: 2
Example:
becomes
becomes
Review: exponential growth and exponential
decay
1 2
1
growth factor (greater than 1)
decay factor (less than 1)
Example: 2
Example:
becomes
becomes
Review: exponential growth and exponential
decay
1 2
1
growth factor (greater than 1)
decay factor (less than 1)
Example: 2
Example:
becomes
becomes
Review: exponential growth and exponential
decay
1 2
1
growth factor (greater than 1)
decay factor (less than 1)
Example: 2
Example:
becomes
becomes
Review: exponential growth and exponential
decay
1 2
1 34
percent of decrease as a decay factor
percent of decrease as a decay factor
The population of a country decreases by 3%.
percent of decrease as a decay factor
The population of a country decreases by 3%.
percent of decrease as a decay factor
The population of a country decreases by 3%.
3%=0.03
percent of decrease as a decay factor
The population of a country decreases by 3%.
3%=0.03
percent of decrease as a decay factor
The population of a country decreases by 3%.
3%=0.031
percent of decrease as a decay factor
The population of a country decreases by 3%.
3%=0.031
percent of decrease as a decay factor
The population of a country decreases by 3%.
3%=0.031
0.03
percent of decrease as a decay factor
The population of a country decreases by 3%.
3%=0.031
0.03
percent of decrease as a decay factor
The population of a country decreases by 3%.
3%=0.031
0.03
percent of decrease as a decay factor
The population of a country decreases by 3%.
3%=0.03
1β0.03=0.971
0.03
percent of decrease as a decay factor
The population of a country decreases by 3%.
3%=0.03
1β0.03=0.971
0.03
percent of decrease as a decay factor
The population of a country decreases by 3%.
3%=0.03
1β0.03=0.9710.03
percent of decrease as a decay factor
The population of a country decreases by 3%.
3%=0.03
1β0.03=0.97
percent of decrease as a decay factor
The population of a country decreases by 3%.
3%=0.03
1β0.03=0.97
percent of decrease as a decay factor
The population of a country decreases by 3%.
3%=0.03
becomes1 0.97
percent of decrease as a decay factor
The population of a country decreases by 3%.
3%=0.03
The decay factor is 0.97!becomes1 0.97
an example The value of a car depreciates 15% per year after it is purchased. The value of the car at the time of its purchase was $20,000. Write a two-variable equation to model this situation.
an example The value of a car depreciates 15% per year after it is purchased. The value of the car at the time of its purchase was $20,000. Write a two-variable equation to model this situation.
an example The value of a car depreciates 15% per year after it is purchased. The value of the car at the time of its purchase was $20,000. Write a two-variable equation to model this situation.
π¦=ΒΏ
an example The value of a car depreciates 15% per year after it is purchased. The value of the car at the time of its purchase was $20,000. Write a two-variable equation to model this situation.
π¦=ΒΏ
15%=0.15
1
an example The value of a car depreciates 15% per year after it is purchased. The value of the car at the time of its purchase was $20,000. Write a two-variable equation to model this situation.
π¦=ΒΏ
15%=0.15
an example The value of a car depreciates 15% per year after it is purchased. The value of the car at the time of its purchase was $20,000. Write a two-variable equation to model this situation.
π¦=ΒΏ
15%=0.15
an example The value of a car depreciates 15% per year after it is purchased. The value of the car at the time of its purchase was $20,000. Write a two-variable equation to model this situation.
π¦=ΒΏ
1β0.15=0.85
an example The value of a car depreciates 15% per year after it is purchased. The value of the car at the time of its purchase was $20,000. Write a two-variable equation to model this situation.
π¦=ΒΏ1
0.85
becomes
an example The value of a car depreciates 15% per year after it is purchased. The value of the car at the time of its purchase was $20,000. Write a two-variable equation to model this situation.
π¦=ΒΏ1
0.85
becomes
an example The value of a car depreciates 15% per year after it is purchased. The value of the car at the time of its purchase was $20,000. Write a two-variable equation to model this situation.
π¦=ΒΏ1
0.85
becomes
0.85
an example The value of a car depreciates 15% per year after it is purchased. The value of the car at the time of its purchase was $20,000. Write a two-variable equation to model this situation.
π¦=ΒΏ0.85
an example The value of a car depreciates 15% per year after it is purchased. The value of the car at the time of its purchase was $20,000. Write a two-variable equation to model this situation.
π¦=ΒΏ0.85
an example The value of a car depreciates 15% per year after it is purchased. The value of the car at the time of its purchase was $20,000. Write a two-variable equation to model this situation.
π¦=ΒΏ0.85
an example The value of a car depreciates 15% per year after it is purchased. The value of the car at the time of its purchase was $20,000. Write a two-variable equation to model this situation.
π¦=ΒΏ0.8520000
an example The value of a car depreciates 15% per year after it is purchased. The value of the car at the time of its purchase was $20,000. Write a two-variable equation to model this situation.
π¦=ΒΏ0.8520000
Now you know how to write an exponential decay function modeling a percent of decrease situation!