Practice problems for applying the Pythagorean Theorem to find missing sides of right triangles.
A worksheet featuring 18 problems on the Pythagorean Theorem, each with a right triangle and two side lengths given, asking to find the third side.
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Show Answer Key & Explanations
Step-by-step solution for: Worksheet) Pythagoras Theorem PDF | PDF | Triangle Geometry ...
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Show Answer Key & Explanations
Step-by-step solution for: Worksheet) Pythagoras Theorem PDF | PDF | Triangle Geometry ...
Let's solve each of these problems using the Pythagorean Theorem, which states:
> For a right triangle:
> $$
> a^2 + b^2 = c^2
> $$
> where:
> - $a$ and $b$ are the legs (the two sides forming the right angle),
> - $c$ is the hypotenuse (the side opposite the right angle, the longest side).
We will identify the known sides and use the formula to find the missing side.
---
- Right angle at B → AB and BC are legs, AC is hypotenuse.
- $AC^2 = AB^2 + BC^2 = 12^2 + 5^2 = 144 + 25 = 169$
- $AC = \sqrt{169} = \boxed{13}$
---
- Right angle at B → AB and BC are legs.
- $AC^2 = 3^2 + 4^2 = 9 + 16 = 25$
- $AC = \sqrt{25} = \boxed{5}$
---
- Right angle at B → AB and BC are legs.
- $AC^2 = 8^2 + 6^2 = 64 + 36 = 100$
- $AC = \sqrt{100} = \boxed{10}$
---
- Right angle at B → AB and BC are legs.
- $AC^2 = 7^2 + 24^2 = 49 + 576 = 625$
- $AC = \sqrt{625} = \boxed{25}$
---
- Right angle at B → AB and BC are legs.
- $AC^2 = 12^2 + 9^2 = 144 + 81 = 225$
- $AC = \sqrt{225} = \boxed{15}$
---
- Right angle at B → AB and BC are legs.
- $AC^2 = 15^2 + 8^2 = 225 + 64 = 289$
- $AC = \sqrt{289} = \boxed{17}$
---
- Right angle at B → AB and BC are legs, AC is hypotenuse.
- $BC^2 = AC^2 - AB^2 = 20^2 - 12^2 = 400 - 144 = 256$
- $BC = \sqrt{256} = \boxed{16}$
---
- Right angle at B → AB and BC are legs, AC is hypotenuse.
- $AB^2 = AC^2 - BC^2 = 13^2 - 5^2 = 169 - 25 = 144$
- $AB = \sqrt{144} = \boxed{12}$
---
- Right angle at B → AB and BC are legs, AC is hypotenuse.
- $AB^2 = AC^2 - BC^2 = 30^2 - 18^2 = 900 - 324 = 576$
- $AB = \sqrt{576} = \boxed{24}$
---
- Right angle at B → AB and BC are legs, AC is hypotenuse.
- $BC^2 = AC^2 - AB^2 = 40^2 - 24^2 = 1600 - 576 = 1024$
- $BC = \sqrt{1024} = \boxed{32}$
---
- Right angle at B → AB and BC are legs, AC is hypotenuse.
- $AB^2 = AC^2 - BC^2 = 100^2 - 80^2 = 10000 - 6400 = 3600$
- $AB = \sqrt{3600} = \boxed{60}$
---
Wait — actually, it says: $AC = 85$, $AB = 68$, $BC = ?$
Right angle at B → AB and BC are legs, AC is hypotenuse.
So:
- $BC^2 = AC^2 - AB^2 = 85^2 - 68^2 = 7225 - 4624 = 2601$
- $BC = \sqrt{2601} = \boxed{51}$
---
- Right angle at B → AB and BC are legs.
- $AC^2 = 9^2 + 7^2 = 81 + 49 = 130$
- $AC = \sqrt{130} \approx \boxed{11.4}$ (exact: $\boxed{\sqrt{130}}$)
---
- Right angle at B → AB and BC are legs, AC is hypotenuse.
- $AB^2 = AC^2 - BC^2 = 19^2 - 12^2 = 361 - 144 = 217$
- $AB = \sqrt{217} \approx \boxed{14.7}$ (exact: $\boxed{\sqrt{217}}$)
---
- Right angle at B → AB and BC are legs.
- $AC^2 = 15^2 + 11^2 = 225 + 121 = 346$
- $AC = \sqrt{346} \approx \boxed{18.6}$ (exact: $\boxed{\sqrt{346}}$)
---
- Right angle at B → AB and BC are legs, AC is hypotenuse.
- $AB^2 = AC^2 - BC^2 = 12^2 - 5^2 = 144 - 25 = 119$
- $AB = \sqrt{119} \approx \boxed{10.9}$ (exact: $\boxed{\sqrt{119}}$)
---
- Right angle at B → AB and BC are legs, AC is hypotenuse.
- $AB^2 = AC^2 - BC^2 = 23^2 - 19^2 = 529 - 361 = 168$
- $AB = \sqrt{168} = \sqrt{4 \cdot 42} = 2\sqrt{42} \approx \boxed{12.96}$ (exact: $\boxed{2\sqrt{42}}$)
---
- Right angle at B → AB and BC are legs, AC is hypotenuse.
- $AB^2 = AC^2 - BC^2 = 34^2 - 21^2 = 1156 - 441 = 715$
- $AB = \sqrt{715} \approx \boxed{26.74}$ (exact: $\boxed{\sqrt{715}}$)
---
| Problem | Answer |
|--------|--------|
| 1 | 13 |
| 2 | 5 |
| 3 | 10 |
| 4 | 25 |
| 5 | 15 |
| 6 | 17 |
| 7 | 16 |
| 8 | 12 |
| 9 | 24 |
| 10 | 32 |
| 11 | 60 |
| 12 | 51 |
| 13 | $\sqrt{130} \approx 11.4$ |
| 14 | $\sqrt{217} \approx 14.7$ |
| 15 | $\sqrt{346} \approx 18.6$ |
| 16 | $\sqrt{119} \approx 10.9$ |
| 17 | $2\sqrt{42} \approx 12.96$ |
| 18 | $\sqrt{715} \approx 26.74$ |
---
Let me know if you'd like a visual explanation or help with any specific one!
> For a right triangle:
> $$
> a^2 + b^2 = c^2
> $$
> where:
> - $a$ and $b$ are the legs (the two sides forming the right angle),
> - $c$ is the hypotenuse (the side opposite the right angle, the longest side).
We will identify the known sides and use the formula to find the missing side.
---
1. Triangle ABC: $BC = 5$, $AB = 12$, $AC = ?$
- Right angle at B → AB and BC are legs, AC is hypotenuse.
- $AC^2 = AB^2 + BC^2 = 12^2 + 5^2 = 144 + 25 = 169$
- $AC = \sqrt{169} = \boxed{13}$
---
2. Triangle ABC: $BC = 3$, $AB = 4$, $AC = ?$
- Right angle at B → AB and BC are legs.
- $AC^2 = 3^2 + 4^2 = 9 + 16 = 25$
- $AC = \sqrt{25} = \boxed{5}$
---
3. Triangle ABC: $BC = 8$, $AB = 6$, $AC = ?$
- Right angle at B → AB and BC are legs.
- $AC^2 = 8^2 + 6^2 = 64 + 36 = 100$
- $AC = \sqrt{100} = \boxed{10}$
---
4. Triangle ABC: $BC = 7$, $AB = 24$, $AC = ?$
- Right angle at B → AB and BC are legs.
- $AC^2 = 7^2 + 24^2 = 49 + 576 = 625$
- $AC = \sqrt{625} = \boxed{25}$
---
5. Triangle ABC: $AB = 12$, $BC = 9$, $AC = ?$
- Right angle at B → AB and BC are legs.
- $AC^2 = 12^2 + 9^2 = 144 + 81 = 225$
- $AC = \sqrt{225} = \boxed{15}$
---
6. Triangle ABC: $BC = 8$, $AB = 15$, $AC = ?$
- Right angle at B → AB and BC are legs.
- $AC^2 = 15^2 + 8^2 = 225 + 64 = 289$
- $AC = \sqrt{289} = \boxed{17}$
---
7. Triangle ABC: $AC = 20$, $AB = 12$, $BC = ?$
- Right angle at B → AB and BC are legs, AC is hypotenuse.
- $BC^2 = AC^2 - AB^2 = 20^2 - 12^2 = 400 - 144 = 256$
- $BC = \sqrt{256} = \boxed{16}$
---
8. Triangle ABC: $BC = 5$, $AC = 13$, $AB = ?$
- Right angle at B → AB and BC are legs, AC is hypotenuse.
- $AB^2 = AC^2 - BC^2 = 13^2 - 5^2 = 169 - 25 = 144$
- $AB = \sqrt{144} = \boxed{12}$
---
9. Triangle ABC: $BC = 18$, $AC = 30$, $AB = ?$
- Right angle at B → AB and BC are legs, AC is hypotenuse.
- $AB^2 = AC^2 - BC^2 = 30^2 - 18^2 = 900 - 324 = 576$
- $AB = \sqrt{576} = \boxed{24}$
---
10. Triangle ABC: $AB = 24$, $AC = 40$, $BC = ?$
- Right angle at B → AB and BC are legs, AC is hypotenuse.
- $BC^2 = AC^2 - AB^2 = 40^2 - 24^2 = 1600 - 576 = 1024$
- $BC = \sqrt{1024} = \boxed{32}$
---
11. Triangle ABC: $BC = 80$, $AC = 100$, $AB = ?$
- Right angle at B → AB and BC are legs, AC is hypotenuse.
- $AB^2 = AC^2 - BC^2 = 100^2 - 80^2 = 10000 - 6400 = 3600$
- $AB = \sqrt{3600} = \boxed{60}$
---
12. Triangle ABC: $AC = 85$, $BC = 68$, $BC = ?$ ← Wait, it says "BC = ?" but gives BC = 68?
Wait — actually, it says: $AC = 85$, $AB = 68$, $BC = ?$
Right angle at B → AB and BC are legs, AC is hypotenuse.
So:
- $BC^2 = AC^2 - AB^2 = 85^2 - 68^2 = 7225 - 4624 = 2601$
- $BC = \sqrt{2601} = \boxed{51}$
---
13. Triangle ABC: $AB = 9$, $BC = 7$, $AC = ?$
- Right angle at B → AB and BC are legs.
- $AC^2 = 9^2 + 7^2 = 81 + 49 = 130$
- $AC = \sqrt{130} \approx \boxed{11.4}$ (exact: $\boxed{\sqrt{130}}$)
---
14. Triangle ABC: $BC = 12$, $AC = 19$, $AB = ?$
- Right angle at B → AB and BC are legs, AC is hypotenuse.
- $AB^2 = AC^2 - BC^2 = 19^2 - 12^2 = 361 - 144 = 217$
- $AB = \sqrt{217} \approx \boxed{14.7}$ (exact: $\boxed{\sqrt{217}}$)
---
15. Triangle ABC: $BC = 11$, $AB = 15$, $AC = ?$
- Right angle at B → AB and BC are legs.
- $AC^2 = 15^2 + 11^2 = 225 + 121 = 346$
- $AC = \sqrt{346} \approx \boxed{18.6}$ (exact: $\boxed{\sqrt{346}}$)
---
16. Triangle ABC: $BC = 5$, $AC = 12$, $AB = ?$
- Right angle at B → AB and BC are legs, AC is hypotenuse.
- $AB^2 = AC^2 - BC^2 = 12^2 - 5^2 = 144 - 25 = 119$
- $AB = \sqrt{119} \approx \boxed{10.9}$ (exact: $\boxed{\sqrt{119}}$)
---
17. Triangle ABC: $AC = 23$, $BC = 19$, $AB = ?$
- Right angle at B → AB and BC are legs, AC is hypotenuse.
- $AB^2 = AC^2 - BC^2 = 23^2 - 19^2 = 529 - 361 = 168$
- $AB = \sqrt{168} = \sqrt{4 \cdot 42} = 2\sqrt{42} \approx \boxed{12.96}$ (exact: $\boxed{2\sqrt{42}}$)
---
18. Triangle ABC: $AC = 34$, $BC = 21$, $AB = ?$
- Right angle at B → AB and BC are legs, AC is hypotenuse.
- $AB^2 = AC^2 - BC^2 = 34^2 - 21^2 = 1156 - 441 = 715$
- $AB = \sqrt{715} \approx \boxed{26.74}$ (exact: $\boxed{\sqrt{715}}$)
---
✔ Final Answers:
| Problem | Answer |
|--------|--------|
| 1 | 13 |
| 2 | 5 |
| 3 | 10 |
| 4 | 25 |
| 5 | 15 |
| 6 | 17 |
| 7 | 16 |
| 8 | 12 |
| 9 | 24 |
| 10 | 32 |
| 11 | 60 |
| 12 | 51 |
| 13 | $\sqrt{130} \approx 11.4$ |
| 14 | $\sqrt{217} \approx 14.7$ |
| 15 | $\sqrt{346} \approx 18.6$ |
| 16 | $\sqrt{119} \approx 10.9$ |
| 17 | $2\sqrt{42} \approx 12.96$ |
| 18 | $\sqrt{715} \approx 26.74$ |
---
Let me know if you'd like a visual explanation or help with any specific one!
Parent Tip: Review the logic above to help your child master the concept of pythagoras theorem worksheet pdf.