Mathematics • Year 9 • Unit 4 • Lesson 3

Solving Right-Angled Triangles

Build fluency choosing the right trig ratio, setting up the equation, rearranging to make the unknown the subject, and using inverse trig to find angles. One step at a time, from a fully worked example through guided practice to independent problems.

Build · I Do / We Do / You Do

1. I do — fully worked example

Read every line. Each step has a short reason on the right so you can see why, not just what.

Problem. A right-angled triangle has opposite = 8 cm and adjacent = 6 cm. Find the unknown angle θ to 1 dp.

Step 1 — Identify which sides you know and which you want.

Known: opposite = 8, adjacent = 6. Want: the angle θ.

Reason: writing this down first stops you picking the wrong ratio later.

Step 2 — Pick the ratio that uses ONLY the sides you know.

Opposite + adjacent → TOA → tan.

Reason: don't drag the hypotenuse into the equation when you don't need it.

Step 3 — Set up the equation.

tan θ = opp / adj = 8 / 6 = 4/3

Reason: simplify the fraction if you can — easier to read.

Step 4 — Use the inverse function to solve for θ.

θ = tan⁻¹(4/3) = tan⁻¹(1.3333…)

Reason: tan⁻¹ means "the angle whose tangent is …". It UNDOES tan.

Step 5 — Evaluate on the calculator (degree mode), keep full precision until the final answer.

θ ≈ 53.1301° → round to 53.1° (1 dp)

Reason: keep all decimals on the calculator screen; only round the FINAL answer.

Answer: θ ≈ 53.1°. (This is one of the angles in the 3-4-5 / 6-8-10 right-angled triangle.)

Stuck? Revisit lesson § "Finding an Unknown Angle" — inverse trig is just a button on the calculator (usually shift + sin/cos/tan).

2. We do — fill in the missing steps

Same structure as Section 1, but with the working faded. Fill in each blank line. 4 marks

Problem. A right-angled triangle has angle 25°, hypotenuse 10 cm. Find the adjacent side to 2 dp.

Step 1 — Known and wanted: known = angle and ____________; wanted = ____________ side.

Step 2 — Pick the ratio. Hypotenuse + adjacent → ________ → cos.

Step 3 — Set up:

cos 25° = ________ / 10

Step 4 — Rearrange to make adjacent the subject:

adjacent = 10 × ________ ° = 10 × ____________ ≈ ____________ cm

Step 5 — Round to 2 dp:

adjacent ≈ ____________ cm

Stuck? cos 25° ≈ 0.9063. Calculator in DEGREE mode.

3. You do — independent practice

Show your working in the space under each problem. The first four are foundation (single ratio). The middle two are standard (combine 2 ideas or use inverse trig). The last two are extension (multi-step + check).

Foundation — single ratio

3.1 Find x to 2 dp: angle = 30°, hypotenuse = 14, x = opposite. 1 mark

3.2 Find x to 2 dp: angle = 45°, adjacent = 9, x = opposite. 1 mark

3.3 Find the angle θ to 1 dp: opposite = 5, hypotenuse = 13. 1 mark

3.4 Find the angle θ to 1 dp: adjacent = 12, hypotenuse = 15. 1 mark

Standard — solve for the unknown

3.5 Find the HYPOTENUSE to 2 dp: angle = 35°, adjacent = 8 cm. (Hint: rearrange cos = adj/hyp to make hyp the subject — you'll need to DIVIDE.) 2 marks

3.6 A ramp rises 2 m vertically over a horizontal distance of 10 m. Find the angle of inclination to 1 dp. 2 marks

Extension — push your thinking

3.7 In a right-angled triangle, the opposite side to one acute angle is 5 cm and the adjacent is 12 cm. Find the angle, the hypotenuse, and the OTHER acute angle. 3 marks

3.8 A student calculates the opposite side of a triangle (angle 40°, hyp 10) and gets 6.43 cm. They want to check by computing the adjacent side and then using Pythagoras. Carry out the check and state whether the answer is consistent. 2 marks

Stuck on 3.8? Use cos 40° to find the adjacent, then check opp² + adj² ≈ hyp².

How did this worksheet feel?

Got it Partly Lost

What I'll revisit before next class:

Answers — Do not peek before attempting

Section 2 — We do (cos 25°, hyp 10, find adj)

Step 1: known = angle and hypotenuse; wanted = adjacent.
Step 2: hyp + adj → CAH → cos.
Step 3: cos 25° = adjacent / 10.
Step 4: adjacent = 10 × cos 25° = 10 × 0.9063 ≈ 9.063 cm.
Step 5: adjacent ≈ 9.06 cm.

3.1 — Angle 30°, hyp 14, find opp

sin 30° = x/14 → x = 14 × 0.5 = 7.00 cm.

3.2 — Angle 45°, adj 9, find opp

tan 45° = x/9 → x = 9 × tan 45° = 9 × 1 = 9.00 cm.

3.3 — Opposite 5, hyp 13, find angle

sin θ = 5/13 = 0.3846 → θ = sin⁻¹(0.3846) ≈ 22.6°. (5-12-13 triangle.)

3.4 — Adjacent 12, hyp 15, find angle

cos θ = 12/15 = 0.8 → θ = cos⁻¹(0.8) ≈ 36.9°. (9-12-15 = 3×(3-4-5) triangle.)

3.5 — Angle 35°, adj 8, find hyp

cos 35° = 8 / hyp → hyp = 8 / cos 35° = 8 / 0.8192 ≈ 9.77 cm.
Sanity check: hyp > adj (9.77 > 8). ✓

3.6 — Ramp rise 2 m over 10 m

tan θ = 2/10 = 0.2 → θ = tan⁻¹(0.2) ≈ 11.3°. (A gentle wheelchair-friendly ramp slope.)

3.7 — Opposite 5, adjacent 12

tan θ = 5/12 = 0.4167 → θ ≈ 22.6°.
Hypotenuse by Pythagoras: √(25 + 144) = √169 = 13 cm.
Other acute angle = 90° − 22.6° = 67.4° (since the two acute angles sum to 90°).

3.8 — Check the opposite is 6.43

Adjacent: cos 40° = adj/10 → adj = 10 × cos 40° ≈ 10 × 0.7660 = 7.66 cm.
Pythagoras check: 6.43² + 7.66² ≈ 41.3 + 58.7 = 100 = 10² ✓.
The answer is consistent — the triangle works.
This is the cross-check technique from card 3 of the lesson.