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Module 1 · L3 of 15 ~35 min ⚡ +95 XP available

Rational Inequalities

Engineers design bridges that must withstand variable loads, doctors dose medications so concentrations stay within safe ranges, and economists model revenue functions that must stay positive. All of these require solving inequalities involving fractions — rational inequalities. In this lesson you'll master the sign-table method that makes these problems systematic and foolproof.

Today's hook — A student tries to solve $\dfrac{x-2}{x+3} \le 0$ by multiplying both sides by $(x+3)$ to get $x - 2 \le 0$, so $x \le 2$. They missed the answer $x = -4$. Why did that happen? By the end of this lesson you'll know exactly why, and you'll never make that mistake.

0/5QUESTS

Recall — your gut answer first

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Why is it dangerous to multiply both sides of an inequality by an expression containing $x$? Think before you read on — what could go wrong?

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The two moves

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There are only two core ideas in this lesson. First: always bring everything to one side so the other side is zero. Second: use a sign table — test one point per interval, never multiply by unknowns.

Every rational inequality lives on one road: bring all terms to one side, combine into a single fraction, then find where that fraction is positive or negative using a sign table. The denominator's zeros are always excluded — no exceptions.

$\dfrac{x-2}{x+3} \le 0 \implies x \in (-3,\,2]$

Never multiply by x

You don't know if the expression is positive or negative, so you can't know whether to flip the inequality sign. Always move to one side instead.

Denominator zeros excluded

Values that make the denominator zero are always excluded from the solution — even if the inequality includes "equals."

One test point per interval

A rational expression can only change sign at critical values — so test just one point per interval. The sign is constant throughout.

What you'll master

Know

Key facts

The six-step method for solving rational inequalities
Critical values come from both numerator and denominator zeros
Denominator zeros are always excluded from solutions

Understand

Concepts

Why multiplying both sides by an expression in $x$ is invalid
Why the sign of a rational expression is constant between critical values
Why we need a sign table rather than just algebraic manipulation

Can do

Skills

Bring all terms to one side and combine into a single fraction
Build and read a sign table for rational expressions
Express solutions in interval notation with correct inclusions/exclusions

Key terms

Rational inequalityAn inequality involving one or more algebraic fractions.

Critical valueA value of $x$ where the numerator or denominator equals zero; the expression changes sign or is undefined here.

Excluded valueA value that makes the denominator zero; it can never be part of the solution, even when equality is allowed.

Sign tableA table showing the sign of each factor in the intervals divided by critical values, used to determine where the whole expression is positive or negative.

Interval notationA concise way to write a set of real numbers, e.g., $(-3, 2]$ means $-3 < x \le 2$ with $-3$ excluded and $2$ included.

The standard method — six steps

core concept

To solve a rational inequality such as $\dfrac{x - 2}{x + 3} \le 0$, follow these six steps every time:

Bring all terms to one side so that the other side is zero.
Combine into a single fraction if necessary.
Find critical values — values where the numerator equals zero and where the denominator equals zero.
Draw a sign table showing the intervals created by the critical values.
Determine the sign of the expression in each interval by testing one point.
Select the intervals that satisfy the inequality. Exclude denominator zeros; include numerator zeros if equality is part of the inequality.

Why this works. A rational expression can only change sign where the numerator or denominator is zero — at critical values. Between critical values, the sign is constant. So we only need to test one representative point per interval: everything in that interval has the same sign.

Six steps: (1) move all terms to one side, (2) single fraction, (3) critical values, (4) sign table, (5) determine signs, (6) select intervals and exclude denominator zeros; Never multiply both sides by an expression containing x — you don't know its.

Pause — copy the six-step rational inequality method into your book: (1) move all terms to one side; (2) combine into a single fraction; (3) find critical values; (4) draw a sign table; (5) determine sign of each interval; (6) select correct intervals, excluding denominator zeros.

Quick check: To solve $\dfrac{x+1}{x-3} > 0$, what are the critical values?

Why sign tables work — the key insight

core concept

We just saw the six-step method: combine into a single fraction, find critical values, build a sign table, and exclude denominator zeros. That raises a question: why can we test just one point per interval — what guarantees the sign doesn't change between critical values? This card answers it → a rational expression changes sign only at a zero of numerator or denominator; between consecutive critical values, the sign is constant throughout.

A rational expression can only change sign at a critical value. Between any two consecutive critical values, the expression maintains the same sign throughout. This is the foundation of the whole method.

Consider $\dfrac{x-2}{x+3}$. The critical values divide the number line into three intervals:

$x < -3$: both factors are negative, so the fraction is $\dfrac{-}{-} = +$ (positive)
$-3 < x < 2$: numerator is negative, denominator is positive, so $\dfrac{-}{+} = -$ (negative)
$x > 2$: both factors are positive, so $\dfrac{+}{+} = +$ (positive)

We test just one point in each interval — say $x = -4$, $x = 0$, $x = 3$ — to confirm the sign. Then we select the intervals where the sign matches the inequality.

Denominator zeros are always excluded. At $x = -3$, the expression is undefined (division by zero), so $x = -3$ cannot be in the solution regardless of whether the inequality uses $\le$ or $<$. By contrast, when the numerator is zero (e.g. $x = 2$), the expression equals zero, so if the inequality includes equality ($\le$ or $\ge$), we include that value.

Sign of f(x){g(x)}: positive when f and g have the same sign; negative when they have opposite signs; Between critical values, the sign is constant — test one representative point per interval

Pause — copy the sign-table rule into your book: $\frac{f(x)}{g(x)}$ is positive when $f$ and $g$ have the same sign; between any two consecutive critical values the expression's sign is constant — test one point per interval.

Did you get this? True or false: if $x = 5$ makes the denominator of a rational expression zero, then $x = 5$ must be excluded from the solution even when solving $\dfrac{f(x)}{x-5} \le 0$.

Worked examples · 3 in a row, reveal as you go

PROBLEM 1 · BASIC RATIONAL INEQUALITY

Solve: $\dfrac{x - 2}{x + 3} \le 0$

Critical values: numerator zero at $x = 2$; denominator zero at $x = -3$.

Set $x - 2 = 0$ to get $x = 2$. Set $x + 3 = 0$ to get $x = -3$. These are the two critical values that divide the number line into three intervals.

Sign table:

Interval	$x+3$	$x-2$	Expression
$x < -3$	$-$	$-$	$+$
$-3 < x < 2$	$+$	$-$	$-$
$x > 2$	$+$	$+$	$+$

Test $x = -4$ (gives $\frac{-6}{-1} = +$), $x = 0$ (gives $\frac{-2}{3} = -$), $x = 3$ (gives $\frac{1}{6} = +$). Signs confirmed.

PROBLEM 2 · SUBTRACT 1 FIRST

Solve: $\dfrac{2x - 1}{x + 3} > 1$

Bring all terms to one side: $\dfrac{2x - 1}{x + 3} - 1 > 0$

Never move the 1 to the right and multiply both sides by $(x+3)$ — you don't know its sign. Always subtract so one side is zero.

PROBLEM 3 · QUADRATIC NUMERATOR

Solve: $\dfrac{x^2 - 4}{x} > 0$

Factorise: $\dfrac{(x-2)(x+2)}{x} > 0$. Critical values: $x = 2$, $x = -2$, $x = 0$.

Set each factor equal to zero. Three critical values divide the number line into four intervals: $x < -2$, $-2 < x < 0$, $0 < x < 2$, $x > 2$. Note $x = 0$ is a denominator zero — always excluded.

Sign table:

Interval	$x-2$	$x+2$	$x$	Result
$x < -2$	$-$	$-$	$-$	$-$
$-2 < x < 0$	$-$	$+$	$-$	$+$
$0 < x < 2$	$-$	$+$	$+$	$-$
$x > 2$	$+$	$+$	$+$	$+$

Test representative points: $x = -3$, $x = -1$, $x = 1$, $x = 3$. Three factors so count the number of negatives — odd count gives negative result.

Fill the gap: To solve $\dfrac{3x}{x+2} > 2$, the first step is to rewrite it as $\dfrac{3x}{x+2} - 2 > 0$, then combine over a common denominator to get $\dfrac{x-4}{x+2}$ $0$.

Misconceptions to fix · the 3 traps that cost marks

Trap 01

Multiplying by the denominator

Writing $\dfrac{x-2}{x+3} \le 0 \Rightarrow x - 2 \le 0 \Rightarrow x \le 2$ is wrong. Since $x+3$ can be negative, multiplying might flip the inequality sign — and you've lost a whole section of the solution. Always bring terms to one side instead.

Trap 02

Including the denominator zero

Writing the solution as $[-3, 2]$ instead of $(-3, 2]$ is wrong. $x = -3$ makes the denominator zero, so the expression is undefined there — it can never satisfy any inequality. Denominator zeros are always excluded, even for $\le$.

Trap 03

Forgetting to subtract before finding critical values

For $\dfrac{2x-1}{x+3} > 1$, treating the right-hand side as $1$ and finding critical values from $2x - 1 = 1$ and $x + 3 = 0$ misses the point. You must bring all terms to one side first: $\dfrac{2x-1}{x+3} - 1 > 0$, then combine into a single fraction.

Did you get this? True or false: for the inequality $\dfrac{x+1}{x-2} \le 0$, the value $x = 2$ must be included in the solution because the inequality uses $\le$.

Work mode · how are you completing this lesson?

Activities · practice with the ideas

Solve $\dfrac{x + 1}{x - 2} \le 0$ and express your answer in interval notation.

Solve $\dfrac{3x}{x + 2} > 2$. Show all steps including how you bring terms to one side.

Solve $\dfrac{x^2 - 9}{x} \ge 0$. There are three critical values — identify them all.

A student claims the solution to $\dfrac{x-3}{x+1} > 0$ is $x > 3$. What error did they make, and what is the correct solution?

Explain in your own words why the denominator zero must always be excluded from the solution, even when the inequality sign includes equality ($\le$ or $\ge$).

Revisit your thinking

Earlier you were asked: why is it dangerous to multiply both sides of an inequality by an expression containing $x$?

The answer is that the expression in $x$ can be either positive or negative depending on the value of $x$. When you multiply an inequality by a negative number, the inequality sign flips. Since you don't know whether the expression is positive or negative, you don't know whether to flip the sign — and any assumption you make will give the wrong answer for at least some values of $x$.

The correct approach: always bring all terms to one side and use a sign table to determine the sign in each interval.

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Multiple choice

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Pick your answer, then rate your confidence — that tells the system what to drill next. Each retry pulls a fresh mix from the bank.

Short answer

ApplyBand 42 marks

Q1. Solve $\dfrac{x + 1}{x - 2} \le 0$, clearly stating which critical values are included and which are excluded. (2 marks)

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ApplyBand 43 marks

Q2. Solve $\dfrac{3x}{x + 2} > 2$. Show all working including how you bring terms to one side and combine into a single fraction. (3 marks)

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AnalyseBand 53 marks

Q3. Solve $\dfrac{x^2 - 4}{x} > 0$. Your solution should include a sign table with all three critical values, and express the final answer in interval notation. (3 marks)

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Comprehensive answers (click to reveal)

Activity drills: 1. CVs: $x = -1$, $x = 2$. Sign: $+$ on $x < -1$, $-$ on $-1 < x < 2$, $+$ on $x > 2$. Solution: $[-1, 2)$ — include $x=-1$ (numerator zero, $\le$), exclude $x=2$ (denominator zero). · 2. Subtract 2: $\frac{3x - 2(x+2)}{x+2} = \frac{x-4}{x+2} > 0$. CVs: $x=4$, $x=-2$. Positive when $x < -2$ or $x > 4$. · 3. $\frac{(x-3)(x+3)}{x}$. CVs: $-3, 0, 3$. Positive on $(-3,0)\cup(3,\infty)$; zero at $\pm 3$ included. Solution: $[-3, 0) \cup [3, \infty)$. · 4. Error: multiplied both sides by $(x+1)$ without knowing its sign. Correct: $x < -1$ or $x > 3$. · 5. At a denominator zero, the expression is undefined — division by zero is not defined, so it cannot satisfy any inequality.

Q1 (2 marks): CVs: $x = -1$ (numerator zero) and $x = 2$ (denominator zero) [0.5]. Sign table: $+$ for $x < -1$, $-$ for $-1 < x < 2$, $+$ for $x > 2$ [0.5]. Select negative or zero: $-1 \le x < 2$, i.e. $[-1, 2)$ [1]. Include $x = -1$ (numerator zero, $\le$); exclude $x = 2$ (denominator zero always excluded) [correct notation: +0.5 if both inclusions stated correctly].

Q2 (3 marks): $\frac{3x}{x+2} - 2 > 0$ [1]. $\frac{3x - 2(x+2)}{x+2} = \frac{x-4}{x+2} > 0$ [1]. CVs: $x = 4$ (excluded, $>$) and $x = -2$ (excluded, denominator). Positive when $x < -2$ or $x > 4$. Solution: $(-\infty, -2) \cup (4, \infty)$ [1].

Q3 (3 marks): $\frac{(x-2)(x+2)}{x} > 0$ [0.5]. CVs: $x = -2, 0, 2$ [0.5]. Four intervals; sign pattern: $-,+,-,+$ (for $x<-2$, $-2<x<0$, $0<x<2$, $x>2$) [1]. Select positive: $(-2, 0) \cup (2, \infty)$ — all endpoints excluded (strict inequality or denominator zero) [1].

Boss battle · The Sign Master

earn bronze · silver · gold

Five timed questions. Beat the boss to bank a tier — gold (90% + speed), silver (75%), or bronze (50%). Replays welcome.

⚔ Enter the arena

Science Jump · platform challenge

Climb platforms by answering rational inequality questions. Lighter alternative to the boss.

Mark lesson as complete

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