Sine Rule
Unlock the power to solve any triangle. The sine rule connects every side to the sine of its opposite angle -- and it works for every triangle, not just right-angled ones.
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SOH CAH TOA only works in right-angled triangles. Imagine a triangle with angles 50°, 60° and 70° -- no right angle at all. How might you find a missing side if you know one side and all three angles? What relationship could connect sides to angles?
The sine rule states that in any triangle, the ratio of each side to the sine of its opposite angle is constant. This means larger sides face larger angles, and this relationship is precise and calculable.
$$\frac{a}{\sin A} = \frac{b}{\sin B} = \frac{c}{\sin C}$$
The sine rule is essential when you know two angles and one side (AAS) and need to find another side, or when you know two sides and a non-included angle (SSA) and need to find another angle. It transforms angle information into side information and vice versa.
Know
- The sine rule: $\frac{a}{\sin A} = \frac{b}{\sin B} = \frac{c}{\sin C}$
- When the sine rule applies (AAS and SSA cases)
Understand
- Why the sine rule works for any triangle, not just right-angled ones
- The ambiguous case and why two triangles may exist
Can Do
- Use the sine rule to find unknown sides and angles
- Identify when the ambiguous case applies
- Choose between sine rule and SOH CAH TOA
Wrong: The sine rule can be used in any triangle, including right-angled triangles -- so use it everywhere.
Right: The sine rule can be used in right-angled triangles, but it is unnecessary. Use SOH CAH TOA for right-angled triangles and the sine rule for non-right-angled triangles.
Wrong: The sine rule is $\frac{a}{\sin A} = \frac{b}{\sin B} = \frac{c}{\sin C} = \text{area}$.
Right: The sine rule is $\frac{a}{\sin A} = \frac{b}{\sin B} = \frac{c}{\sin C}$. It relates sides to the sines of their opposite angles, not to the area.
The sine rule can be derived from the area formula for a triangle. By calculating the area in three different ways (using each side as the base), we obtain three expressions that must be equal -- and the sine rule drops out.
Area = $\frac{1}{2}ab \sin C = \frac{1}{2}bc \sin A = \frac{1}{2}ca \sin B$. Divide all three by $\frac{1}{2}abc$: $$\frac{\sin C}{c} = \frac{\sin A}{a} = \frac{\sin B}{b}$$ Taking reciprocals gives the sine rule: $\frac{a}{\sin A} = \frac{b}{\sin B} = \frac{c}{\sin C}$. The key insight: the height of a triangle can be expressed using any side and the sine of the adjacent angle.
Use the sine rule to find an unknown side when you know two angles and one side (AAS). First find the third angle (angles sum to 180°), then set up the proportion and solve.
Step 1: Find the third angle: $C = 180° - A - B$.
Step 2: Write the sine rule with the known side-angle pair and the unknown side.
Step 3: Cross-multiply and solve.
Always use the side opposite the known angle as your reference pair. This gives you the constant ratio that connects to every other side-angle pair.
When you know two sides and a non-included angle (SSA), the sine rule can find the missing angle. But beware: there may be two possible answers. This is the famous ambiguous case.
From $\frac{a}{\sin A} = \frac{b}{\sin B}$, you get $\sin B = \frac{b \sin A}{a}$. Since $\sin x = \sin(180° - x)$, if the calculated angle is acute, $180°$ minus that angle is also a valid solution -- provided the resulting triangle angles still sum to 180°. Two triangles exist when: $a < b$ and $a > b \sin A$.
Watch Me Solve It · 3 examples
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1Find angle C$\angle C = 180° - 50° - 60° = 70°$Angles in a triangle sum to 180°.
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2Write the sine rule$\frac{a}{\sin A} = \frac{b}{\sin B}$We know $a$ and $A$, and want $b$ given $B$.
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3Substitute and solve$\frac{10}{\sin 50°} = \frac{b}{\sin 60°}$$b = \frac{10 \times \sin 60°}{\sin 50°}$$b = \frac{10 \times 0.8660}{0.7660} \approx 11.3$ cm
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4Check reasonableness$B = 60° > A = 50°$, so $b$ should be greater than $a = 10$$11.3 > 10$ ✓ Larger angle faces larger side.
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1Write the sine rule for angles$\frac{a}{\sin A} = \frac{b}{\sin B}$We know two sides and one opposite angle.
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2Rearrange to find sin B$\sin B = \frac{b \sin A}{a} = \frac{12 \times \sin 30°}{8}$$\sin B = \frac{12 \times 0.5}{8} = \frac{6}{8} = 0.75$
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3Find angle B$B = \sin^{-1}(0.75) \approx 48.6°$Using inverse sine on your calculator.
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4Check for the ambiguous case$180° - 48.6° = 131.4°$If $B = 131.4°$, then $C = 180° - 30° - 131.4° = 18.6° > 0$ ✓Since $a < b$ and $a > b \sin A$ ($8 > 12 \times 0.5 = 6$), two triangles exist. $B \approx 48.6°$ or $131.4°$.
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1Find angle C$\angle C = 180° - 40° - 70° = 70°$Angles in a triangle sum to 180°.
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2Find side a$\frac{a}{\sin 40°} = \frac{12}{\sin 70°}$$a = \frac{12 \times \sin 40°}{\sin 70°} = \frac{12 \times 0.6428}{0.9397} \approx 8.2$ cm
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3Find side b$\frac{b}{\sin 70°} = \frac{12}{\sin 70°}$$b = 12$ cmSince $\angle B = \angle C = 70°$, the triangle is isosceles with $b = c$.
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4VerifyAngles: $40° + 70° + 70° = 180°$ ✓Sides: $a < b = c$ since $A < B = C$ ✓Largest angle faces largest side. The triangle is consistent.
Sine Rule
- $\frac{a}{\sin A} = \frac{b}{\sin B} = \frac{c}{\sin C}$
- Side / sin(opposite angle) = constant
- Works for any triangle
Finding Sides (AAS)
- Find third angle first
- Set up proportion with known pair
- Cross-multiply and solve
Finding Angles (SSA)
- Rearrange to find sin(angle)
- Use inverse sine
- Check for ambiguous case
Ambiguous Case
- Two solutions if $a < b$ and $a > b \sin A$
- Second angle = $180° - \text{first angle}$
- Check angles sum to 180°
How are you completing this lesson?
Brain Trainer · 4 problems
Four quick problems on the sine rule. Work each, then reveal the answer.
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1 In $\triangle ABC$, $\angle A = 40°$, $\angle B = 70°$, and $a = 12$ cm. Find side $b$.
$\angle C = 70°$. $\frac{12}{\sin 40°} = \frac{b}{\sin 70°}$ → $b = \frac{12 \times \sin 70°}{\sin 40°} \approx 17.5$ cm.$b \approx 17.5$ cm -
2 In $\triangle ABC$, $a = 10$ cm, $b = 15$ cm, and $\angle A = 35°$. Find $\angle B$.
$\sin B = \frac{15 \times \sin 35°}{10} = \frac{15 \times 0.5736}{10} \approx 0.860$. $B \approx 59.4°$ or $120.6°$.$B \approx 59.4°$ or $120.6°$ -
3 In $\triangle ABC$, $\angle A = 50°$, $\angle B = 60°$, and $a = 8$ cm. Find $\angle C$ and side $c$.
$\angle C = 180° - 50° - 60° = 70°$. $c = \frac{8 \times \sin 70°}{\sin 50°} \approx 9.8$ cm.$C = 70°$, $c \approx 9.8$ cm -
4 In $\triangle ABC$, $a = 5$ cm, $b = 8$ cm, and $\angle A = 30°$. How many possible triangles exist? Explain.
$b \sin A = 8 \times 0.5 = 4$. Since $a = 5$ and $4 < 5 < 8$, two triangles exist. If $a < 4$, no triangle. If $a \ge 8$, one triangle.Two triangles
Multiple Choice · 5 questions
The sine rule states:
The sine rule is used when you know:
In $\triangle ABC$, $A = 30°$, $B = 60°$, $a = 5$. Find $b$:
The ambiguous case occurs with:
The sine rule applies to:
Short Answer · 3 questions
(a) Find $\angle C$.
(b) Use the sine rule to find side $a$.
(c) Use the sine rule to find side $b$.
(a) Use the sine rule to find $\angle B$.
(b) Explain why there might be two possible values for $\angle B$.
(c) Sketch both possible triangles.
(a) Find $\angle ABC$ and $\angle ACB$.
(b) Find $\angle BAC$.
(c) Use the sine rule to find the distance from $A$ to the tower ($AB$).
(d) Find the distance from $C$ to the tower ($CB$).
(e) Explain why there is no ambiguous case in this problem.
Reveal solution
(a) $\angle ABC = 180° - 35° = 145°$ (bearing geometry: the tower is 35° east of north from A, so the interior angle at B is 180° - 35° = 145°... wait, let us be more careful. From A, the tower is 35° east of north. From C, the tower is 22° west of north. The line AC runs east. The angle between north and AB is 35°. The angle between north and CB is 22°. Since AC is east-west, the angles on the same side of north sum: $\angle BAC = 90° - 35° = 55°$ and $\angle BCA = 90° - 22° = 68°$.
(b) $\angle BAC = 180° - 55° - 68° = 57°$... Actually, using the bearing geometry more carefully: the angle at A inside the triangle is $90° - 35° = 55°$ and at C is $90° - 22° = 68°$. So $\angle ABC = 180° - 55° - 68° = 57°$.
(c) Using sine rule: $\frac{AB}{\sin 68°} = \frac{200}{\sin 57°}$. $AB = \frac{200 \times \sin 68°}{\sin 57°} \approx \frac{200 \times 0.9272}{0.8387} \approx 221$ m.
(d) $\frac{CB}{\sin 55°} = \frac{200}{\sin 57°}$. $CB = \frac{200 \times \sin 55°}{\sin 57°} \approx \frac{200 \times 0.8192}{0.8387} \approx 195$ m.
(e) There is no ambiguous case because we know two angles (ASA effectively), which uniquely determines a triangle. The ambiguous case only arises with SSA (two sides and a non-included angle).
Sine rule
$\frac{a}{\sin A} = \frac{b}{\sin B} = \frac{c}{\sin C}$
Finding sides
Use AAS, find third angle first
Finding angles
Use SSA, check ambiguous case
Ambiguous
$B$ or $180° - B$
Label
Capital = angle, lowercase = side
Right triangle
Use SOH CAH TOA instead
Interactive: Sine Rule Solver
Practice using the sine rule to find missing sides and angles. Test your calculations with instant feedback.
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