Question

need help

Answer 1

Iris has been studying an invasive population of snails. This particular snail has no local predators so the population grows wildly. She has observed that the population follows an exponential rate of growth for fifteen years.

Create your own exponential function, f(x), which models the snail population. You will need to identify the principal population of the snails and the rate of growth each year. Explain to Iris how your function shows the principal population and the rate of growth, in complete sentences.


A local snail population grows according to the function g(x) = 200(1.03)2x. Demonstrate the steps to convert g(x) into an equivalent function with only x as the exponent. Then explain to Iris how the key features of this local snail population compares to the key features of the invasive population.


Iris wants to graph the invasive snail population to show the city council. Justify what the appropriate domain and range would be for the function f(x), what the y-intercept would be, and if the function is increasing or decreasing.


In five years, a garden festival plans on using the park where Iris has been studying the invasive snails. Explain to the garden festival committee how to find the average rate of change for the snail population between years 2 and 5. Describe what this average rate of change represents.

Answer 2

are you in FLVS?

Answer 3

yes

Answer 4

algebra 2?

Answer 5

no algebra 1 honers

Answer 6

oh i remember having a problem similar to this but I'm in algebra 2 and don't really remember all of that

Answer 7

For the first thing do you want to population to double, triple, quadruple, etc?

Answer 8

and how many snails do you want to start with?

Answer 9

15
right

Answer 10

you want to start with 15?

Answer 11

if so I would suggest having the population double as exponential functions can increase quickly

Answer 12

so what would you start with

Answer 13

The exponential equation with the population starting at 15 and doubling each year would be f(x)=15(2)^x where x is the year

Answer 14

\[f(x)=15(2^{x})\]

Answer 15

is the equation in the second question supposed to be \[g(x)=200(1.03)^{2x}\]

Answer 16

yes it is

Answer 17

I think for that part you would do 1.03^2 which would give you 200(1.0609)^x

Answer 18

but I'm not positive

Answer 19

@phi

Answer 20

from what I'm seeing on other things that should be correct

Answer 21

ok

Answer 22

Domain would be \[x \ge 15\] because your population starts at 15 the range would be \[x \ge 0\]

Answer 23

can you figure out what the y-intercept would be from that information?

Answer 24

1.0609 not exactly sure to be honest

Answer 25

that is the rate that the local snails are growing
the y-intercept would be the starting number of snails

Answer 26

oh so 15

Answer 27

yes (0,15)

Answer 28

for the last one do you know how to make the graph?

Answer 29

or the slope? i have the points for year 2 and 5

Answer 30

no i dont

Answer 31

\[y_{2}-y _{1}/x _{2}-x _{1}\]
is the equation for the slope
the points are 2, 60 and 5, 480
can you substitute the values in?

Answer 32

480-60/5-2

Answer 33

yes which would simplify to?

Answer 34

140

Answer 35

yes so the slope will be 140/1 this represents that the average number of snails coming into the area between years 2 and 5 is 140 snails a year

Answer 36

oh ok thank you

Answer 37

You guys are way off...Here you go for those who are looking for the right answers. (If you can't view the document then the Q&A's are below. Although it is recommended you view the document for better understanding. I will also attach it as a pdf file.)

Iris has been studying an invasive population of snails. This particular snail has no local predators, so the population grows wildly. She has observed that the population follows an exponential rate of growth for fifteen years.
Create your own exponential function, f(x), which models the snail population. You will need to identify the principal population of the snails and the rate of growth each year. Explain to Iris how your function shows the principal population and the rate of growth, in complete sentences.

This is the formula that is used to show exponential growth over time: f(x) = P(1 + r)x.
Now I need to create an equation based off of the information given, and in the form of the equation above.
Because I wasn't told what the initial population of the snails was I need to make a value for the initial population of the snails; an appropriate value. So let’s say that the initial population of snails was 150. Let’s also say that the rate of growth is 50%; because we weren't given this information to begin with. Now that we have a value for P and r we can plug in the values.
F(x) = 150(1 + 0.5)x
P represents the initial population.
R represents the rate of growth.
X represents the number of years.

A local snail population grows according to the function g(x) = 200(1.03)2x. Demonstrate the steps to convert g(x) into an equivalent function with only x as the exponent. Then, explain to Iris how the key features of this local snail population compares to the key features of the invasive population.

G(x) = 200(1.03)2x
G(x) = 200(1.032)x
G(x) = 200(1.0609)x

First let’s start off by mentioning the key features. As you can see the local snails initial population is 200, whereas the initial population for the invasive snails is 150. Also, if you take a look at the exponential function above you may notice that g(x) = 200(1.0609)x can also mean g(x) = 200(1 + 0.0609)x. This means that the rate of growth for the local snails is 6.9%, whereas the growth rate for the invasive snails is 50%. So the local snails began with a larger population than the invasive snails, but the invasive snail’s growth rate is much larger than the local snail’s growth rate.





Iris wants to graph the invasive snail population to show the city council. Justify what the appropriate domain and range would be for the function f(x), what the y-intercept would be, and if the function is increasing or decreasing.

F(x) = 150(1 + .5)x
Let’s plug in some values for x! Earlier Iris mentioned that she observed the snail’s growth for 15 years. So we can graph the population of the snails for all 15 of those years using the exponential function we made earlier. Starting at year 0, and ending at year 15.
F(0) = 150(1 + .5)0
F(0) = 150(1.5)0
F(0) = 150(1)
F(0) = 150
This means that at year 0, or the beginning, the snail population was 150. Now all we have to do is the same thing for year 1 to year 15. These should be our results:
F(0) = 150
F(1) = 225
F(2) = 337
F(3) = 506
F(4) = 759
F(5) = 1139
F(6) = 1708
F(7) = 2562
F(8) = 3844
F(9) = 5766
F(10) = 8649
F(11) = 12974
F(12) = 19461
F(13) = 29192
F(14) = 43789
F(15) = 65684
What those mean is after 15 years [f(15)], the population of invasive snails is 65, 684. Now that we know what these represent and their values we can start to set their ordered pairs and plot them on a coordinate plane. These are the ordered pairs:
(0, 150) (1, 225) (2, 337) (3, 506) (4, 759) (5, 1139) (6, 1708) (7, 2562) (8, 3844) (9, 5766)
(10, 8649) (11, 12974) (12, 19461) (13, 29192) (14, 43789) (15, 65684)
The domain for this function would be 0≤x≤15 and the range for this function is 150≤y≤65684. The y-intercept of this function is 150. This function is increasing.


In five years, a garden festival plans on using the park where Iris has been studying the invasive snails. Explain to the garden festival committee how to find the average rate of change for the snail population between years 2 and 5. Describe what this average rate of change represents.

So, to find the average rate of change for a function you use this formula.
(F(b)-F(a))/(b-a)
When f(b) and f(a) represent the output values, and b and a represent the input values. So this is how it would look for this scenario.

(F(5)-F(2))/(5-2)
(1139 -337)/3
802/3
267/1
This means that the average rate of change in this function from year 2 to year 5 is about 267. What the means is the population of invasive snails, on average, increased by 267 each year from year 2 to year 5.

Answer 38

Wow thanks this is exactly what I'm doing sooo helpful!!

Answer 39

@CatalystDuzIt