The explicit formula is of the form: a_n=a_1 + d\left(n-1\right), where a_1 is the first term and d is the common difference. We just need to match the values in the given explicit rule to find a_1 and d.

The constant when in this form is the first term, so we can say that a_1=4.

The coefficient of \left(n-1\right) is the common difference, so we can say that d=3.

Using this we can fill in the recursive formula a_n=a_{n-1}+d with a_1 to get:

a_n=a_{n-1}+3 and a_1=4.

We could also have found the values of a_1 and d by generating terms of the sequence. For example, to find a_1:

This means we are looking for when n=10, or in other words a_{10}. Since we have both the explicit and recursive formulas, we could use either, but the explicit will be much quicker as we don't need to find all of the terms up to a_{10} like we do with the recursive formula.

The 10th term of the sequence is 31.

To fill in a_n= a_{n-1}+d and a_1, we need both d and a_1.

From the given sequence, a_1= 3 and d=4.2-3=1.2.

The recursive equation for an arithmetic sequence is a_n= a_{n-1}+d

Substituting the values to the equation gives:

a_n= a_{n-1}+1.2, \, a_1=3

Assuming that the first term in the list is a_1, we could also say: a_n= a_{n-1}+1.2, \, a_0=1.8

We could actually say any of the following and they would all represent the same sequence:

• a_n= a_{n-1}+1.2, \, a_1=3
• a_n= a_{n-1}+1.2, \, a_0=1.8
• a_{n+1}= a_{n}+1.2, \, a_1=3
• a_{n+1}= a_{n}+1.2, \, a_0=1.8

In some contexts, we may be given a_0 instead of a_1. In particular, the y-intercept of a graphed sequence corresponds to a_0.

To find a term, our recursive rule says to "add 1.2 to the previous term", we can use this to find the next four terms.

Repeatedly adding 1.2 we get:

3,\, 4.2,\, 5.4,\, 6.6,\, 7.8,\, 9.0,\, 10.2,\, 11.4,\, 12.6\ldots

Notice that finding the "next" terms in the sequence is efficient using the recursive rule, but finding the nth term such as a_{20} could be very tedious using this rule instead of the explicit rule.

We can use that the slope of the linear function which goes through the points will be the common difference.

Alternatively, we can create a table of values and identify it from there.

From the graph we can identify that between each term we go down 3 units, so d=-3.

Notice that if we write the coordinates of the points from the graph in a table of values we can confirm the difference between consecutive values is d=-3.

The general rule will start in the form a(n)=a(1)+(n-1)d, so we need to find a(1) and d and then substitute and simplify.

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^+.