This lesson will work with arithmetic sequences, their recursive and explicit formulas and finding terms in a sequence. In this lesson, it is assumed that you know what an arithmetic sequence is and can find a common difference. If you need to review these topics, click here. Let’s look at the arithmetic sequence 20, 24, 28, 32, 36, . . . This arithmetic sequence has a common difference of 4, meaning that we add 4 to a term in order to get the next term in the sequence. The recursive formula for an arithmetic sequence is written in the form For our particular sequence, since the common difference (d) is 4, we would write So once you know the common difference in an arithmetic sequence you can write the recursive form for that sequence. However, the recursive formula can become difficult to work with if we want to find the 50 ^{th} term. Using the recursive formula, we would have to know the first 49 terms in order to find the 50 ^{th}. This sounds like a lot of work. There must be an easier way. And there is! Rather than write a recursive formula, we can write an explicit formula. The explicit formula is also sometimes called the closed form. To write the explicit or closed form of an arithmetic sequence, we use a_{n} is the nth term of the sequence. When writing the general expression for an arithmetic sequence, you will not actually find a value for this. It will be part of your formula much in the same way x’s and y’s are part of algebraic equations.
a_{1} is the first term in the sequence. To find the explicit formula, you will need to be given (or use computations to find out) the first term and use that value in the formula.
n is treated like the variable in a sequence. For example, when writing the general explicit formula, n is the variable and does not take on a value. But if you want to find the 12th term, then n does take on a value and it would be 12.
d is the common difference for the arithmetic sequence. You will either be given this value or be given enough information to compute it. You must substitute a value for d into the formula. You must also simplify your formula as much as possible. Let's Practice: Write the explicit formula for the sequence that we were working with earlier.
20, 24, 28, 32, 36, . . . The first term in the sequence is 20 and the common difference is 4. This is enough information to write the explicit formula. Now we have to simplify this expression to obtain our final answer. So the explicit (or closed) formula for the arithmetic sequence is .
Notice that a_{n} the and n terms did not take on numeric values. They are a part of the formula, again like x’s and y’s in algebraic expressions.
If we wanted to find the 50 ^{th} term of the sequence, we would use n = 50. Look at the example below to see what happens.  Given the sequence 20, 24, 28, 32, 36, . . . find the 50^{th} term.
To find the 50^{th} term of any sequence, we would need to have an explicit formula for the sequence. Since we already found that in Example #1, we can use it here. If we do not already have an explicit form, we must find it first before finding any term in a sequence.
Use the explicit formula and let n = 50. This will give us Notice how much easier it is to work with the explicit formula than with the recursive formula to find a particular term in a sequence. What happens if we know a particular term and the common difference, but not the entire sequence? Let’s see in the next example.  Find the explicit formula for a sequence where d = 3 and a_{12} = 58.
The formula says that we need to know the first term and the common difference. We have d, but do not know a_{1}. However, we have enough information to find it. We know that when n = 12, the 12^{th} term in the sequence is 58. If we simplify that equation, we can find a_{1}. Now that we know the first term along with the d value given in the problem, we can find the explicit formula. Notice this example required making use of the general formula twice to get what we need. The first time we used the formula, we were working backwards from an answer and the second time we were working forward to come up with the explicit formula.  Find the explicit formula for an arithmetic sequence where a_{1} = 4 and a_{2} = 10.
In this situation, we have the first term, but do not know the common difference. However, we do know two consecutive terms which means we can find the common difference by subtracting.
10  4 = 6 means that d = 6
Now we use the formula to get Notice that writing an explicit formula always requires knowing the first term and the common difference. If neither of those are given in the problem, you must take the given information and find them.  Is 623 a term in the sequence 4, 10, 16, 22, . . . ?
The way to solve this problem is to find the explicit formula and then see if 623 is a solution to that formula.
We already found the explicit formula in the previous example to be . To find out if 623 is a term in the sequence, substitute that value in for a_{n}. What does this mean? Well, if 623 is a term in the sequence, when we solve the equation, we will get a whole number value for n. Since we did not get a whole number value, then 623 is not a term in the sequence. Look at it this way. There can be a 103^{rd} term or a 104^{th} term, but not one in between. 

