5.02 Exponential growth

f(x)=3\left(1.725\right)^x

This function is in the form y=ab^x. We can identify the y-intercept and the growth factor, but then we need to use b=1+r to solve for the growth rate.

The growth factor, b, is 1.725.

\begin{aligned} 1.725 &= 1+r \\ r &= 0.725 \end{aligned}

The y-intercept is (0, 3), and the growth rate is 72.5\%.

In the formula, the growth rate is represented as a decimal. When we are discussing the rate outside of the formula, it is best to state it as a percentage.

f(x)=2^{x-1}

This is not in either of the forms discussed above because the exponent is not just an x. We need to use the properties of exponents to manipulate the equation until it is in one of the forms mentioned above.

Now, it is in the form y=ab^x, so we can identify the y-intercept and growth factor.

a=\dfrac{1}{2},\, b=2

Last, we need to find the growth rate:

\begin{aligned} 2 &= 1+r \\ r &= 1 \end{aligned}

The y-intercept is \left(0,\dfrac{1}{2}\right) and the growth rate is 1 or 100\%.

When something grows by 100\%, it is being increased by its own value. In other words, we are doubling the output each time.

Explain how we know the function represents exponential growth.

To classify an exponential function, we want to identify the constant factor, b, and determine if b>1 or 0<b<1.

In this function, b=4. Since 4>1, we would classify this function as exponential growth.

We can validate this answer by building a table of values to show that the y-values increase as the x-values increase.

The y-values are growing at an increasing rate, so this does represent exponential growth.

Identify the growth rate.

According to the formula, the growth rate can be found by subtracting 1 from the growth factor.

The growth factor is 4.

4-1=3

The growth rate is 300\%, so each term is increased by 300\%.

We can check by finding 300\% of each output. We can start from the y-intercept and find the following points from there.

\dfrac{1}{2}\times \dfrac{300}{100}=\dfrac{3}{2}

Now, we increase \dfrac{1}{2} by \dfrac{3}{2}.

\dfrac{1}{2}+\dfrac{3}{2}=2

This would be the output associated with x=1, so let's check by plugging in x=1.

f(1)=\dfrac{1}{2}(4)^1=2

Write a function, V, to represent the value of the piece of sports memorabilia after t years.

Since the memorabilia is predicted to increase in value by a percentage, we will use the growth rate form of the function, y=a(1+r)^x or with the given variables V=a(1+r)^t.

The initial value of the memorabilia is \$2900. This represents the value when t=0, so this is the y-intercept. The growth rate is 9\% which is 0.09 as a decimal, so the function is V=2900(1+0.09)^t.

In many exponential growth functions, the independent variable represents time. Since time cannot be negative, the domain will begin from zero as it did in this problem. When this happens, the y-intercept is called the initial value.

Evaluate the function for t=8 and interpret the meaning in context.

In this context, t represents the time in years, and the output, V, represents the value of Justin's sports memorabilia. We will evaluate the function and apply these units to interpret the meaning of the solution.

V=2900(1+0.09)^8\approx 5778.43 which tells us that the memorabilia will be worth approximately \$5778.43 after 8 years have passed.

Estimate the growth rate to one decimal place.

To estimate the growth rate, we will create data points from the given information. If we let x=0 represent 2015, then x=1 will be the first year. The associated data point is (1,46). The data point for the third year is (3,66).

These are not consecutive outputs, so we need to set up an equation and solve for r.

To get from the first year to the third year, we multiplied the population by the growth factor twice. The equation would be 46\cdot b \cdot b = 66 which simplifies to 46b^2=66.

This represents the growth factor, so now we must solve for the growth rate.

\begin{aligned} 1.198 &= 1+r \\ r &= 0.198 \end{aligned}

Next, we can convert to a percentage and round it to one decimal place.

\begin{aligned} r&=19.8\% \\ &= 20\% \end{aligned}

Estimate the initial population.

The initial population will be the number of rabbits present in 2015. Now that we know the growth rate, we can use the number of rabbits in the first year, 2016, to help us solve for the initial population.

To set up the equation, we begin by substituting the known values r=0.2 from part (a), x=1, and y=46 into the equation y=a(1+r)^x.

The initial population of rabbits in 2015 was approximately 38.

Write the equation that models this situation.

Since we discussed the percentage growth, we will use the growth rate form of the equation, y=a\left(1+r\right)^x.

We found r=20\%, a=38 in parts (a) and (b), so we can simply plug them into the formula.

y=38\left(1+0.2\right)^x

Because we rounded the percentage in part (a), the values will not be exact when we check our answers. But since we are working with rabbits and we cannot have a decimal of a rabbit, it makes sense to round to the nearest whole rabbit.

Year 1: y=38(1+0.2)^1=45.6 \approx 46 rabbits

Year 2: y=38(1+0.2)^2=54.72 \approx 55 rabbits

Year 3: y=38(1+0.2)^3=65.664\approx66 rabbits

These answers match the information given in the problem.