10. Geometric number sequences

Geometric number sequences

The sequence [[$ 1, 2, 4, 8, 16, 32,… $]] is an example of a geometric number sequence. In it, each term is obtained by multiplying the previous number by [[$ 2 $]]. Such a sequence, in which the term is obtained from the former by multiplying it by the same constant, is called a geometric sequence.

Consider the representation of the general term [[$ a_n $]] in a geometric sequence, using the first term in the sequence [[$ a_1 $]] and the constant [[$ q $]].


​[[$ \quad \begin{align*} a_2 &= a_1 q \ \\ a_3 &= a_2 q = a_1 qq = a_1 q^2 \ \\ a_4 &= a_3 q = a_1 qqq = a_1 q^3 \ \\ a_n &= a_1 q^{n-1} \end{align*} $]]​


In a geometric number sequence, the ratio of two consecutive terms is constant.

The general term for a geometric sequence is [[$ a_n = a_1q^{n - 1}, $]]​where [[$ a_1 $]]​ is the first term and [[$ q $]]​ is the ratio.


Example 1

Bacteria multiply by dividing in two. Some bacteria initially are [[$ 10 $]] and their number doubles every hour. The number of bacteria can be described with the following number sequence:

[[$ 10, 20, 40, 80, 160, … $]]​

This is a geometric number sequence with the first term of [[$ a_1 = 10 $]] and a ratio of [[$ q = 2 $]].

a) Let's form a general term for the sequence

[[$ a_n = 10 \cdot 2 ^{n - 1} $]]​

b) Calculate the number of bacteria after [[$ 20 $]] hours

[[$ a_{20} = 10 \cdot 2 ^{20 - 1} = 5 242 880 $]]

Example 2

Henry deposited [[$ 1500 $]] QAR in his account. The annual interest rate on the account was [[$ 3,0\% $]], so the deposit will increase by [[$ 1,03 $]] times each year. The amount of money in the account can be described as a geometric sequence:

[[$ 1500 \: \text {QAR} \cdot 1,03 $]]​, [[$ 1500 \: \text {QAR}\cdot 1,03^2 $]][[$ 1500 \: \text {QAR} \cdot 1,03^3 $]]​,[[$ 1500 \: \text {QAR} \cdot 1,03^4 $]], ... , [[$ 1500 \: \text {QAR} \cdot 1,03^n $]]

The first term in the sequence is [[$ a_1 = 1500 \: \text {QAR} \cdot 1,03 = 1545 \: \text {QAR} $]],​ and the ratio of the sequence is [[$ q = 1,03 $]]​.

a) Let's form a general term for the sequence.

[[$ a_n = 14514 \: \text {QAR} \cdot 1,03 ^{n - 1} $]]​ 

b) Let’s calculate how much savings Henry has in 10 years.

[[$ a_{10} = 14514 \: \text {QAR} \cdot 1,03 ^{10 - 1} = 2015,87 \: \text {QAR} $]]