Foundations Unit F8
Introduction to Variables
Evaluating expressions, combining like terms, and the distributive property.
A variable is just a placeholder for a number you don't know yet. Learn the vocabulary — term, coefficient, constant — then the three moves that tidy any linear expression — evaluate (substitute a number and compute), combine like terms (only same-variable pieces merge), and distribute (a number outside parentheses multiplies every term inside). The trap that costs the most points is a minus sign in front of parentheses, which flips every sign inside.
Builds on: F1 · Operations & Integers
A bill that isn’t one number
Your phone plan costs $ a month, plus $ per gigabyte of data. What’s the bill? There’s no single answer — it depends on the data. But the pattern is fixed, and you can write it down once: , where stands for however many gigabytes you use. That little letter is the entire leap into algebra. A variable is a placeholder for a number you don’t know yet — and an expression built around one isn’t a question waiting for an answer, it’s a machine: feed in any month’s usage, out comes that month’s bill.
The machine runs on grammar you already own: obeys the exact same priority ladder as F1’s expressions — multiply by first, then add — the only novelty is a blank where one number used to be.
The vocabulary, from the phone bill
Each piece of an expression has a name, and the bill makes them concrete. A term is one chunk glued by multiplication: and are the two terms here. A coefficient is the number riding a variable — the in , and it means something: three dollars per gigabyte. A constant is a term with no variable — the , the part of the bill that never changes. Almost everything in this unit is tidying expressions built from these pieces.
Evaluating — feed the machine
Suppose you used gigabytes. Evaluate the expression by substituting the value and computing with the usual order of operations: dollars. That’s all “plugging in” is — the moment a variable’s value is known, the whole expression collapses to a number.
The widget opens on with . Predict the result, then check. Now try the same expression with — careful, the coefficient multiplies the whole — and then type with your own “data usage.”
Like terms — you can only count matching kinds
Simplify . The -terms count together ( ‘s plus ‘s is ), the constants count together (), and the answer is . What you may not do is merge with into one number — and the itch to do it anyway is worth understanding. Arithmetic spent years training you that a finished answer is a single number, so feels unfinished, and "" scratches the itch. But -terms and constants are different units — means “three ‘s,” the way inches can’t merge with miles (the same unit-thinking from F3). The lie shows up the moment a value arrives: at , is , while would be . An expression like is a finished answer — a number-in-waiting.
The distributive property — multiply across
You already distribute in your head. Asked for , you’d never stack the long multiplication — you’d split it: plus , so . Letters just make the split official: a number outside parentheses multiplies every term inside, . The picture is a rectangle’s area: height , width split into and — the total area is the two panels added.
The box opens on . Predict both terms of the answer before you look, then make the outside number negative and watch what happens to each panel of the rectangle.
The negative-sign trap
That last experiment is the single most costly slip in early algebra. In , the outside factor is the whole — sign included — and it must reach every term: , not . Stopping after the first term feels natural because the eye reads ” times … done” and the looks like it was already handled by its own plus sign. A five-second lie detector: substitute . The original gives ; the wrong version gives ; the right one gives ✓. That trick — test any simplification with a small number — catches nearly every algebra slip you’ll ever make.
Put it together: distribute, then combine
Real problems mix the two skills: distribute every set of parentheses first (watching signs), then count the like terms. Give the widget and predict just the -coefficient before looking. Then run the lie detector on the result: at , do the original and the simplified version agree?
The one thing to remember
A variable is a number-in-waiting, and an expression is a machine that becomes a number the moment you feed it one. Only matching kinds count together; an outside factor — sign included — reaches every term inside; and when you’re not sure a simplification is legal, substitute a small number and let arithmetic be the judge.
The language of algebra
A variable (like ) is a placeholder for a number. A term is a single piece: or . The number in front of a variable is its coefficient (in , the ). A plain number is a constant.
Like terms
Like terms have the exact same variable part. and are like terms; and are not. You can only add or subtract like terms — count the ‘s together, count the plain numbers together.
Evaluating
To evaluate, replace the variable with a number and compute. If : .
The distributive property
A number outside parentheses multiplies every term inside: .
Putting both together, the signature example:
Quick reference
| Skill | Example |
|---|---|
| Combine like terms | |
| Distribute | |
| Distribute a negative | |
| Distribute then combine |