The ratio of consecutive terms in a geometric sequence is always the same. That is, if the sequence a_1,\,a_2,\,a_3,\,a_4,\,\ldots is geometric, then \dfrac{a_2}{a_1}=\dfrac{a_3}{a_2}=\dfrac{a_4}{a_3}=\ldots

From the given sequence: a_1=3.1,\,a_2=5.6,\,a_3=8.1,\,a_4=10.6,\, \ldots

Observe that \dfrac{a_2}{a_1}=\dfrac{5.6}{3.1}=1.81 and \dfrac{a_3}{a_2}=\dfrac{8.1}{5.6}=1.45. So we have \dfrac{a_2}{a_1} \neq\dfrac{a_3}{a_2}. Because the ratio of consecutive terms for this sequence is not always the same this sequence is not geometric.

Notice that a_2-a_1=5.6-3.1=2.5,\,a_3-a_2=8.1-5.6=2.5,\,a_4-a_3=10.6-8.1=2.5. The sequence has a common difference of 2.5. This tells us that the sequence is actually an arithmetic sequence.

If the sequence a_1,\,a_2,\,a_3,\,a_4,\,\ldots is geometric, then \dfrac{a_2}{a_1}=\dfrac{a_3}{a_2}=\dfrac{a_4}{a_3}=\ldots

The explicit rule for the geometric sequence is given by a_n = a_1 r^{n - 1} where a_1 is the first term in the sequence and r is the common ratio.

From the given sequence: a_1=6,\,a_2=18,\,a_3=54,\,a_4=162,\, \ldots

Check each ratio: \dfrac{a_2}{a_1}=\dfrac{18}{6}=3,\quad\dfrac{a_3}{a_2}=\dfrac{54}{18}=3,\quad\dfrac{a_4}{a_3}=\dfrac{162}{54}=3

This sequence is geometric since each ratio is equal.

To write the explicit rule we can substitute a_1=6 and r=3 into a_n = a_1 r^{n - 1} which gives us a_n = 6(3)^{n - 1}

Use parentheses around the common ratio to separate it from the first term: 6(3)^{n-1} vs. 63^{n-1}

From the given sequence: a_1=-4,\,a_2=20,\,a_3=-100,\,a_4=500,\, \ldots

Check each ratio: \dfrac{a_2}{a_1}=\dfrac{20}{-4}=-5,\quad\dfrac{a_3}{a_2}=\dfrac{-100}{20}=-5,\quad\dfrac{a_4}{a_3}=\dfrac{500}{-100}=-5

This sequence is geometric since each ratio is equal.

To write the explicit rule we can substitute a_1=-4 and r=-5 into a_n = a_1 r^{n - 1} which gives us a_n = -4(-5)^{n - 1}

When the common ratio is negative, there is not a single related exponential function with a restricted domain as the graph alternates back and forth above and below the x-axis which exponential models do not do.

We can use the explicit rule for a geometric sequence a_n=a_1r^{n-1} to identify the first term and common ratio and then substitute those into the recursive formula.

From the equation we see that: a_1=64 and r=\dfrac{1}{2}

Substituting into the recursive formula we get: a_n=\dfrac{1}{2}a_{n-1} and a_1=64

Without stating the first term, we cannot uniquely identify a sequence, if we just say the recursive formula is a_n=\dfrac{1}{2}a_{n-1}, this describes any sequence with common ratio of \dfrac{1}{2}, not necessarily the one described by the explicit formula.

We can use our explicit rule to find the tenth term, a_{10}.

If we wanted, we could also continue the pattern using the recursive rule in a table to find the tenth term:

The first term is a_1, so we can go to n=1 on the horizontal axis to find the value from the vertical axis.

To find the common ratio, we can find \dfrac{a_2}{a_1} or any other consecutive pair of values.

The first term is a_1=3 and the common ratio is r=2.

We can use any pair of consecutive points to find the common ratio:

\frac{a_3}{a_2}=\frac{12}{6}=2

\frac{a_4}{a_3}=\frac{24}{12}=2

If it is hard to read some points due to scale, we could work backwards to identify the first term, by dividing larger terms by the common ratio repeatedly.

In this case, starting with a_4=24, we would need to divide three times: \dfrac{24}{2}=12, then \dfrac{12}{2}=6, then \dfrac{6}{2}=3.

The general rule will start in the form a(n)=a(1)\cdot r^{n-1}, where a(1) represents the first term, so we need to find a(1) and r and then substitute and simplify.

We already know both of these values from part (a), so we just need to substitute them in and simplify.

Equation in function notation: a(n)=3\cdot 2^{n-1} or fully simplified a(n)=\dfrac{3}{2}\cdot 2^n.

The simplified version a(n)=\dfrac{3}{2} \cdot 2^n we can see the growth factor for the related exponential function is 2 and the value of the y-intercept is y=\dfrac{3}{2}. This form can be particularly helpful for connecting the geometric sequence to an exponential model.

We will assume that the first term given has n=1 and can see which values of n are graphed.

The domain is all positive integers, which can be written as n \in \{1, 2, 3, 4, \ldots \} or more precisely as n \in \Z^+.

Sometimes we will be given a sequence with a 0th term, in which case we would need to include 0 in the domain.

This could be represented by giving a_0 in the recursive formula or having a point at n=0 on the graph.