Algebra Unit A1
Linear Equations in One Variable
Solving with inverse operations, variables on both sides, and fractions in equations.
An equation is a balance scale — whatever you do to one side, you must do to the other. Solving means freeing x with inverse operations, working backwards through the order of operations. Clear parentheses, clear fractions, collect the x-terms, then undo the constant and the coefficient. When the x-terms cancel completely, read what's left — a true statement means infinitely many solutions, a false one means none. Always check by plugging the answer back in.
Builds on: F8 · Introduction to Variables
Run the machine backwards
In F8 you built a phone-bill machine: at $ a month plus $ per gigabyte, the bill is . Feed it a usage, out comes a bill. Now flip the problem: the bill arrives at $ — how many gigabytes did you use? This time you know the output and want the input, and writing that down gives you your first equation:
Solving it means finding the value of that makes both sides genuinely equal. All of algebra’s most famous machinery — this module — exists to answer questions shaped like that.
The one rule: keep the scale balanced
An equation is a balance scale that hangs perfectly level: sits in one pan, in the other. You’re allowed to do anything to the scale that keeps it level, which means: whatever you do to one side, you must do to the other. Add to both pans — still level. Add to one pan only, and the scale tips; . Every legal solving move is just this one rule applied with a purpose.
So let’s find the gigabytes, one balanced move at a time:
Notice the order of the undoing. Building the bill, the machine multiplied first and added second (F1’s ladder). Freeing , you undid the addition first and the multiplication second — inverse operations, in reverse order, like taking off shoes before socks:
| has… | To undo it… |
|---|---|
| done to it | subtract from both sides |
| done to it | add to both sides |
| done to it | divide both sides by |
| done to it | multiply both sides by |
“Move it to the other side” — what’s actually happening
You’ll hear solving described as moving terms: “the moves over and becomes .” That shorthand is fine once you know what it hides, and dangerous before. Nothing moves. In , you subtract from both sides; on the left it cancels to nothing, on the right it surfaces as . The “sign flip” isn’t a rule about crossing the equals sign — it’s the visible leftover of a both-sides move. People who memorize it as teleportation eventually flip a sign that shouldn’t flip (or drag a coefficient across as if it worked the same way). When in doubt, fall back to the scale: name the operation, do it to both pans.
Variables on both sides
looks new, but is just a quantity like any other — so subtract from both pans and it’s gone from the right: . From there you know the drill. (Collecting the smaller -term keeps the coefficient positive, which is kinder to your signs.)
The solver opens on that exact equation. Before reading each step, predict the move: which -term gets collected, what gets undone first, and what’s the final ? Then type an equation with parentheses — say — and watch the F8 skills (distribute, watch the negative!) become the opening moves of solving.
When x vanishes: no solution or infinitely many
Try in the solver, then . In both, the -terms cancel completely — and what’s left tells you which strange case you’re in. is true no matter what was: the two sides were the same machine in different clothes, so every number solves it — infinitely many solutions. is false no matter what: the two sides always differ by exactly , so no number can ever reconcile them. Neither is an error — both are answers, and the SAT loves asking you to recognize them.
Always check
Plug your answer back into the original equation — not a later line, which may already carry your mistake — and confirm both sides land on the same number. It’s the same five-second lie detector from F8, and it catches nearly every slip. Build the habit in the Check a Solution tab.
The one thing to remember
An equation is a level scale, and solving is undoing: peel everything off with inverse operations, in reverse order of operations, doing each move to both sides. “Moving terms” is only ever a both-sides move wearing a nickname — and a plugged-back-in answer never lies.
What a linear equation is
An equation says two things are equal: a left side and a right side joined by . A linear equation has the variable to the first power only — no , no in a denominator. Solving means finding the value of that makes both sides truly equal.
The strategy (same every time)
Work backwards through the order of operations to peel free:
- Clear parentheses — distribute.
- Clear fractions — multiply every term by the common denominator (optional but tidy).
- Collect like terms — all -terms on one side, all constants on the other.
- Undo what’s done to — subtract/add the constant, then divide by the coefficient.
Each move uses an inverse operation: addition undoes subtraction, multiplication undoes division.
Worked example — two-step
Worked example — variables on both sides
Get the ‘s together first. Move the smaller -term to avoid a negative if you can.
Worked example — fractions
Multiply every term by the common denominator to clear them.
Two special answers
Sometimes the ‘s cancel out completely. Look at what’s left:
| You end up with… | Meaning |
|---|---|
| A true statement, e.g. | Infinitely many solutions — every works (the sides are identical). |
| A false statement, e.g. | No solution — no can work. |
| a single number | One solution — the normal case. |
The SAT loves to ask “for what value does this have no / infinitely many solutions” — recognizing these is worth points.
Always check
Plug your answer back into the original equation. If both sides match, you’re right. This single habit catches almost every arithmetic slip.