4.06 Geometric series

We can use a strategy similar to what we did in previous question 1, but replace the common ratio with r and the number of terms being added with n. The series would be S_n=a+ar+ar^2+ar^3+\cdots +ar^{n-1}.

If we multiply both sides by the common ratio, r, we get rS_n=ar+ar^2+ar^3+ar^4+\cdots +ar^{n}Subtracting this from the original expression, we see that the middle terms eliminate each other \begin{aligned}S_{n}&=a+ar+ar^2+ar^3+ar^4+\cdots+ar^{n-1}\\-rS_{n}&=\text{ }\text{ }-ar-ar^2-ar^3-ar^4-ar^5-\cdots-ar^{n}\\\hline S_{n}-rS_{n}&=a-ar^{n}\end{aligned} Factoring S_n from the lefthand side and a from the righthand side, we get S_n\left(1-r\right)=a\left(1-r^{n}\right) Finally, we can restrict the domain so that r\neq 1 and divide both sides by 1-r to get S_n=\dfrac{a\left(1-r^n\right)}{1-r} where a is the initial term, r is the common ratio, and n is the number of terms being added.

Another way to derive the formula is by using an identity we learned in  3.03 Polynomial identities  . If we factor a from the right side of the equation, we get S_n=a\left(1+r+r^2+r^3+\cdots +r^{n-1}\right) Next, we will multiply both sides by r-1 in order to use the identity x^{n}-1=\left(x-1\right)\left(x^{n-1}+x^{n-2}+\ldots+x+1\right).

To use the geometric series formula, we need to know the first term, the common ratio, and the number of terms being added. The first term and the number of terms being added is given to us. The common ratio can be found by dividing any term by the previous term.

The common ratio is

Now, we can find the sum of the first 9 terms using the geometric series formula.

Using a calculator, we can approximate the sum to be about 1.229.

This geometric sequence has the rule a_n=2\left(-\dfrac{3}{4}\right)^{n-1} If we want to add the first 9 terms, the sigma notation would be \sum_{n=1}^{9} 2\left(-\dfrac{3}{4}\right)^{n-1}

This notation allows us to see each individual term, but we can identify the key information from this notation and use the geometric series formula instead.

To see how the caffeine accumulates during the first day, we can write out the first 3 terms of the series.

In the morning, Erin has 35\text{ mg} of caffeine in her coffee. After 8 hours, 20\% of that caffeine is left in her body and she adds 35\text{ mg} more by drinking a cola. 35\left(0.2\right)+35 In the evening, 20\% of the 20\% of caffeine from her morning coffee remains, 20\% of her mid-afternoon cola remains, and she drinks another 35\text{ mg} in her tea. 35\left(0.2\right)^2+35\left(0.2\right)+35

This pattern will continue, and we can see that the terms form a geometric sequence defined by {a_n= 35\left(0.2\right)^{n-1}} where n represents the number of 8-hour periods that have passed.

To find out how much caffeine is in Erin's body after 3 days, we will need to use n=9 since there are nine 8-hour periods in 3 days. Using a_1=35,r=0.2,n=9 with the geometric series formula, we get:

About 43.75\text{ mg} of caffeine is left in Erin's body after 3 days of drinking 35\text{ mg} every 8 hours.

In reality, there is likely less than this amount of caffeine in Erin's body after 3 days. Caffeine can be completely flushed from your body after about 10 hours if you drink enough water. In this model, the caffeine from the coffee on the first day will never entirely leave Erin's body.