To determine if a set of data represents an exponential function, we want to compare successive y-values, and determine if there is a constant multiplying factor.

We can see that f\left(-1\right)=\dfrac{5}{3} and f\left(0\right)=5, so we want to calculate the multiplying factor that takes us from \dfrac{5}{3} to 5. \frac{5}{3} \cdot b=5 \longrightarrow b=5 \cdot \frac{3}{5} = 3 So the multiplying factor is 3. We now want to check if this factor works for the remaining y-values: 5 \cdot 3=15 and 15 \cdot 3 = 45, as expected. We can similarly check the other values.

The function represents an exponential function.

The function has an initial value, when x=0, of 5 and a growth factor of 3.

An equation that represents this exponential function is: f\left(x\right)=5\left(3^x\right)

The given function is of the form f\left(x\right)=a\left(1+r\right)^x, where a is the initial value of the function.

The initial population is a=100 bacterial cells.

The given function is of the form f\left(x\right)=a\left(1+r\right)^x, where r is the constant percent rate of change, expressed as a decimal.

The constant percent rate of change is 3.5\%. This means the population will increase by 3.5\% every minute.

In this case the constant percent rate is positive as we have exponential growth. For exponential decay with a function of the form f\left(x\right)=a(1-r)^x, the constant percent rate of change would be a negative percentage.

To find the population after 4 hours, we want to find N\left(240\right), as the function gives us the population after t minutes, not hours, so we need to convert 4 hours into minutes, by multiplying by 60.

There will be 385\,198 bacterial cells after 4 hours.

To graph the population, we can fill out a table of values and then sketch the curve that passes through these points. Finding the population after every 30 minutes will give us enough values to sketch the graph accurately enough. All values will be rounded to the nearest integer.

We can now plot the points on a coordinate plane. As the numbers get very large, we will make the y-axis values be multiples of 1000.

We can see from the table and the graph that the population almost triples every 30 minutes. This makes sense, as \left(1+0.35\right)^{30}\approx 2.8 which is close to 3.

The initial population was 100 bacterial cells, so we want to find how long it takes for the population to reach 100 \cdot 1\,000=100\,000

We can draw a horizontal line from y=100\,000 on the y-axis across to the curve, and then draw a vertical line down to the x-axis to find the value of t.

We can see from the graph that the population reaches 1000 times the original population after approximately 200 minutes or 3 hours and 20 minutes.

The population is growing exponentially 'continuously' so we can use the function f\left(x\right)=ae^{kx} to model the population. The housing is growing linearly so we can use f(x)=mx+b to model the available housing.

The population can be modeled with f\left(x\right)=5000(e)^{.05x} and the housing can be modeled with f\left(x\right)=1000x+8000.

We can use a table of values to get an idea of how the population and the housing grows over time:

This table shows us that the population exceeds the available housing between 40 and 50 years and also gives us an idea of the scale needed to graph the relationship.

The population exceeds the available housing between 48 and 50 years.