What happens when problems involve **both** addition and subtraction? Addition is both associative and commutative, and subtraction is neither…

One solution is to follow the order of operations (parentheses, exponents, multiplication, division, addition, subtraction) working from left to right in the event of a “tie”. This will always produce the intended result.

However, the order of operations does not provide any guidance about how an expression might be re-arranged without changing the result… which is what algebra is all about. Re-arranging an expression is often useful, as it can make the expression either look simpler, or easier to evaluate without a calculator.

### Subtraction As The Addition Of A Negative

Let’s briefly revisit addition, but this time with the full set of integers in mind instead of only the counting numbers. What happens when a positive number is added to a negative number?

This corresponds to saying we wish join five “owned candy bars” with three “owed candy bars”. If I use three of my five owned candy bars to pay off the debt, that will leave me with two candy bars… which is the “difference” between 5 and 3. In other words, **subtracting a number is the same as adding the “opposite” number**, or the negative of the number.

### Rearranging Subtraction

Turning subtraction into the addition of a negative turns out to be a very useful concept, as it allows us to rewrite **any** subtraction then use the associative and commutative properties of addition to rearrange the expression:

Notice that all four of the above expressions produce the same -1 as a result. Rearranging has not changed the result now that we have rewritten all subtractions as addition of a negative.

If you wish to rearrange an expression that involves only addition and subtraction (and nothing else)*, *you may do so after changing all subtractions to the addition of the opposite number.

But rewriting things consumes time and ink. It is easier and faster to take this approach: you are welcome to rearrange addition and subtraction **as long as you move the sign before each number with it**. Note that this is exactly what was done above. If a number does not have a sign before it, you should use a plus sign for it.

### Terms

You will find the word “term” very handy in algebra. **Terms are separated by “+” and “-” signs** in an expression**.** The expression

has three terms: 6, 3, and 4.

has four terms: 2, y, x, and 4. Two are variables and two are constants.

Revisiting the approach stated above for rewriting expressions, but this time using the word “term”: **you are welcome to rearrange addition and subtraction as long as you move the sign before each TERM with it. If there is no sign before a term, use “+”**:

### Why Bother Rearranging?

Rearranging expressions can be useful for two reasons: it is a critical step in “simplifying” them (make them shorter and faster to read or evaluate), and it can make them easier to evaluate without resorting to writing instruments or calculators.

Simplifying expressions is a topic that will be covered in detail later, so for now I will show how rearranging can make it easier to do sums and differences in our heads. Rearranging allows us to:

- Combine easy pairs of numbers first
- Divide a problem into parts, which can help us avoid making errors

Suppose we have been asked to compute the following:

If we wish to combine “easy pairs” first, we could rearrange things as:

The two eights will sum to zero, the 4 and -14 will sum to -10, and finally we can add 6 and subtract 7 for a final result of -11.

Alternatively, we could first combine all the positive numbers to arrive at our maximum positive value, then compute the remaining differences:

The first two numbers sum to 10, plus an 8 is 18. Take away a 14 to get to 4, take away an 8 to get to -4, and finally take away a 7 to get to -11.

Or, we could compute a positive total, then the negative total, then combine the two:

The first two numbers sum to 10, plus the 8 produces 18. The negative total will be -14 less 8, which is -22, less 7, which gets us to -29. Combining the two totals: 18-29 = -11. This approach can be less error-prone because we are able to add a series of absolute values for most of our thinking, and only need to compute one difference: our very last step. (Thanks to Michael Goldenberg for suggesting this approach) .

More approaches than the three I have described are possible, however the above should be enough to make the point: rearranging terms can make it easier to compute in your head accurately. Note that all three approaches described above produced the same final result… as guaranteed by the commutative and associative properties of addition.

The “best” approach will usually be the one that **you** find most intuitive and reliable. A room full of people might each prefer a slightly different approach to computing the above problem, yet they will all end up with the same result if they avoid making errors.

Algebra provides us with an infinite number of paths to a problem’s solution. Some will be more efficient, others more easily remembered, and others more reliable when doing “mental math”. We each can choose our preferred approach when the time comes.

Earlier posts in this series:

Algebra Intro 1: Numbers and Variables

Algebra Intro 2: Addition

Algebra Intro 3: Subtraction

Algebra Intro 4: Negative Numbers, Zero, Absolute Values, and Opposites

Posts that continue this series:

Algebra Intro 6: Multiplication

Algebra Intro 7: Properties of Multiplication

Algebra Intro 8: Division

Algebra Intro 9: Fractions, Reciprocals, and Properties of Division

Algebra Intro 10: Fractions and Multiplication

Algebra Intro 11: Dividing Fractions, Equivalent Fractions

Algebra Intro 12: Adding and Subtracting Fractions

My immediate reaction is that by thinking of all addition and subtraction as the addition of signed numbers, we get to group all the positive terms and add, group all the negative terms and add, and finally add the results of the two subtotals. Perhaps you made that point and I missed it in haste. If so, my apologies. If not, it’s the way I try to help students think about doing tedious computations that either consist only of addition and subtraction or have been reduced to such a problem after performing higher-order operations. Of course, it can be PROVED that this sort of thing must work using the properties of the integers.

Good point. I do that too (depending on the circumstances), and had not thought about it while writing this – I’ll work the point in (with credit given where credit is due, of course).

No worries. Just seems like a way to minimize the damage, though I also like the notion you used of showing all the equivalent expressions.

Thank you so much for this article. After 10+ years being out of school I have gone back to college and am forced to take two algebra courses. I was sooooo confused by the lack of what I call “normal speak” in the textbook. You put this into simple terms I could grasp and relate to instead of just example after example of numbers, numbers, letters, numbers, and more letters…. I commend you and sincerely thank you!