Mathematics • Year 9 • Unit 3 • Lesson 3

Finding a Shorter Side

Build fluency with the rearranged Pythagoras formula $a^2 = c^2 - b^2$ — used when the hypotenuse and one leg are known. Identify the hypotenuse, SUBTRACT (not add), then square-root. 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 hypotenuse 13 cm and one leg of 5 cm. Find the other leg.

Step 1 — Identify the hypotenuse $c$.

$c = 13$ (the biggest), $b = 5$ (known leg), $a = $ ? (missing leg).

Reason: the hypotenuse is the LARGEST of the three sides — always check this first.

Step 2 — Rearrange and substitute into $a^2 = c^2 - b^2$.

$a^2 = 13^2 - 5^2$

Reason: finding a LEG means SUBTRACTING. The hypotenuse squared goes FIRST (it's the bigger number).

Step 3 — Compute.

$a^2 = 169 - 25 = 144$

Reason: positive result confirms we put the hypotenuse-squared first. If you ever get negative, you've swapped $c$ and $b$.

Step 4 — Square root.

$a = \sqrt{144} = 12$ cm.

Reason: $\sqrt{}$ undoes squaring. Sanity check: $12 < 13$, so the leg is shorter than the hypotenuse ✓.

Answer: $a = \mathbf{12}$ cm (this completes the 5-12-13 triple).

Stuck? Revisit lesson § "Decision Question: Add or Subtract?" — missing hyp = ADD, missing leg = SUBTRACT. Always check what's missing first.

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 hypotenuse 10 cm and one leg of 7 cm. Find the other leg to 2 d.p.

Step 1 — Identify the hypotenuse: $c = $ ____ (the __________ of the three), $b = $ ____ (known leg), $a = $ ?

Step 2 — Rearrange to $a^2 = c^2 - b^2$ and substitute:

$a^2 = \_\_\_^2 - \_\_\_^2$

Step 3 — Compute:

$a^2 = \_\_\_\_ - \_\_\_\_ = \_\_\_\_$

Step 4 — Square root, round to 2 d.p.:

$a = \sqrt{\_\_\_\_} \approx \_\_\_\_$ cm

Stuck? Revisit lesson § "Watch Me Solve It · A non-perfect square" — same numbers (10 and 7), same method.

3. You do — independent practice

Show your working in the space under each problem. The first four are foundation (use known triples — no calculator). The middle two are standard (calculator + round). The last two are extension (sanity-check and reasoning).

Foundation — known triples (no calculator)

3.1 Hypotenuse 5 cm, one leg 3 cm. Find the other leg. 1 mark

3.2 Hypotenuse 10 cm, one leg 6 cm. Find the other leg. 1 mark

3.3 Hypotenuse 17 cm, one leg 8 cm. Find the other leg. 1 mark

3.4 Hypotenuse 25 cm, one leg 7 cm. Find the other leg. 1 mark

Standard — calculator, round to 2 d.p.

3.5 Hypotenuse 9 m, one leg 4 m. Find the other leg to 2 d.p. 2 marks

3.6 Hypotenuse 20 cm, one leg 11 cm. Find the other leg to 2 d.p. 2 marks

Extension — sanity check and reasoning

3.7 The hypotenuse of a right triangle is 65 inches and one leg is 56.7 inches. Find the other leg to 2 d.p. and state explicitly whether your answer passes the sanity check "leg must be shorter than the hypotenuse". 3 marks

3.8 A classmate writes $a^2 = 7^2 - 13^2 = 49 - 169 = -120$ when trying to find a leg with $c = 13$ and $b = 7$. (i) What sign mistake did they make? (ii) What is the correct value of the missing leg? 2 marks

Stuck on 3.8? The lesson tip "If the result under $\sqrt{}$ is negative, swap $b$ and $c$" is exactly this trap.

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 (faded hyp 10, leg 7)

Step 1: $c = \mathbf{10}$ (the largest), $b = \mathbf{7}$, $a = $ ?
Step 2: $a^2 = \mathbf{10}^2 - \mathbf{7}^2$.
Step 3: $a^2 = \mathbf{100} - \mathbf{49} = \mathbf{51}$.
Step 4: $a = \sqrt{\mathbf{51}} \approx \mathbf{7.14}$ cm.

3.1 — Hyp 5, leg 3

$a^2 = 5^2 - 3^2 = 25 - 9 = 16$, so $a = \sqrt{16} = \mathbf{4}$ cm. (3-4-5 triple.)

3.2 — Hyp 10, leg 6

$a^2 = 10^2 - 6^2 = 100 - 36 = 64$, so $a = \sqrt{64} = \mathbf{8}$ cm. (This is $2\times$(3-4-5).)

3.3 — Hyp 17, leg 8

$a^2 = 17^2 - 8^2 = 289 - 64 = 225$, so $a = \sqrt{225} = \mathbf{15}$ cm. (8-15-17 triple.)

3.4 — Hyp 25, leg 7

$a^2 = 25^2 - 7^2 = 625 - 49 = 576$, so $a = \sqrt{576} = \mathbf{24}$ cm. (7-24-25 triple.)

3.5 — Hyp 9, leg 4

$a^2 = 9^2 - 4^2 = 81 - 16 = 65$, so $a = \sqrt{65} \approx \mathbf{8.06}$ m. (Sanity: $8.06 < 9$ ✓.)

3.6 — Hyp 20, leg 11

$a^2 = 20^2 - 11^2 = 400 - 121 = 279$, so $a = \sqrt{279} \approx \mathbf{16.70}$ cm. (Sanity: $16.70 < 20$ ✓.)

3.7 — Hyp 65, leg 56.7

$a^2 = 65^2 - 56.7^2 = 4225 - 3214.89 = 1010.11$, so $a = \sqrt{1010.11} \approx \mathbf{31.78}$ inches.
Sanity check: $31.78 < 65$ ✓ — pass. (This is the height of a typical 65-inch TV — matches the lesson's worked example.)

3.8 — Classmate's sign mistake

(i) They put the smaller number FIRST: they wrote $7^2 - 13^2$ instead of $13^2 - 7^2$. The hypotenuse-squared (the biggest) must come first when subtracting; otherwise you get a negative number, and the square root of a negative is not a real number.
(ii) Correct working: $a^2 = 13^2 - 7^2 = 169 - 49 = 120$, so $a = \sqrt{120} \approx \mathbf{10.95}$ cm.