Right-angled triangles
Pythagoras' theorem states that for all right-angled triangles:
The square on the hypotenuse is equal to the sum of the squares on the other two sides.
The hypotenuse is the longest side and it's always opposite the right angle.
In this triangle \(a^2 = b^2 + c^2\) and angle \(A\) is a right angle.
Pythagoras' theorem only works for right-angled triangles, so you can use it to test whether a triangle has a right angle or not.
In the triangle above, if \({a}^{2}~\textless~{b}^{2}+{c}^{2}\) the angle \(A\) is acute.
In the triangle above, if \({a}^{2}~\textgreater~{b}^{2}+{c}^{2}\) the angle \(A\) is obtuse.
Question
Which of the following triangles is right-angled?
a)
b)
c)
Answer a)
\(8^2 = 64\)
\(5^2 + 6^2 = 25 + 36 = 61\)
\(8^2\) is greater than \(5^2 + 6^2\), so angle \(A\) must be obtuse.
Answer b)
\(13^2 = 169\)
\(5^2 + 12^2 = 25 + 144 = 169\)
\(13^2\) is equal to \(5^2 + 12^2\) so angle \(P\) must be a right angle.
Answer c)
\(10^2 = 100\)
\(5^2 + 9^2 = 25 + 81 = 106\)
\(10^2\) is less than \(5^2 + 9^2\) so angle \(X\) must be acute.*
So, it is triangle b which is right-angled.
Working out the hypotenuse
Question
Work out the length of the line \({BR}\), correct to \({1}\) decimal place.
Answer
\(BR^2 = 4^2 + 7^2\)
\(BR^2 = 16 + 49\)
\(BR^2 = 65\)
\({BR}=\sqrt65\) (Find the square root of both sides) \(BR={8.1~cm}\) (\({1}\) decimal place)
Calculating the length of another side of a triangle
If you know the length of the hypotenuse and one of the other sides, you can use Pythagoras鈥 theorem to find the length of the third side.
We can rearrange the formula for Pythagoras鈥 theorem, in order to make \({b}\) or \({c}\) the subject of the formula:
\({a}^{2}={b}^{2}+{c}^{2}\)
\({b}^{2}={a}^{2}-{c}^{2}\)
\({c}^{2}={a}^{2}-{b}^{2}\)
Example
Work out the length of the line \({LM}\), correct to \({1}\) decimal place.
\({LM}^{2}={LN}^{2}-{MN}^{2}\)
\({LM}^{2}={6}^{2}-{4}^{2}\)
\({LM}^{2}={36}-{16}\)
\({LM}^{2}={20}\)
\({LM}=\sqrt{20}\)
\({LM}={4.5~cm}\) (\({1}\) decimal place)
Question
Work out the length of the line \(YZ\), correct to \({1}\) decimal place.
Answer
Method 1
\({YZ}^{2}+{XZ}^{2}={XY}^{2}\)
\({YZ}^{2}+{7}^{2}={8}^{2}\)
\({YZ}^{2}+{49}={64}\)
\({YZ}^{2}={15}\) (subtract \({49}\) from both sides)
\({YZ}=\sqrt{15}\) (find the square root of both sides)
\({YZ}={3.9~cm}\) (\({1}\) decimal place)
Method 2
\({YZ}^{2}={XY}^{2}-{XZ}^{2}\)
\({YZ}^{2}={8}^{2}-{7}^{2}\)
\({YZ}^{2}={64}-{49}\)
\({YZ}^{2}={15}\)
\({YZ}=\sqrt{15}\) (find the square root of both sides)
\({YZ}={3.9~cm}\) (\({1}\) decimal place)
Length of a line segment
You can also use Pythagoras' theorem to find the distance between two points:
Determining distance with Pythagoras' theorem
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Test section
Question 1
Is a triangle with sides of \({3}~{cm}\), \({4}~{cm}\) and \({5}~{cm}\) a right-angled triangle?
Answer
Yes, it is.
鈥楾he square on the hypotenuse is equal to the sum of the squares on the other two sides鈥.
In this case \({5}^{2}={3}^{2}+{4}^{2}\).
Question 2
Is a triangle with sides of \({5}~{cm}\), \({6}~{cm}\) and \({12}~{cm}\) a right-angled triangle?
Answer
No, it's not.
Remember that 鈥榯he square on the hypotenuse is equal to the sum of the squares on the other two sides鈥.
In this case \({12}^{2}\neq{5}^{2}+{6}^{2}\).
Question 3
What is the length of the hypotenuse of a right-angled triangle when the lengths of the other sides are \({6}~{cm}\) and \({8}~{cm}\)?
Answer
Remember that 鈥榯he square on the hypotenuse is equal to the sum of the squares on the other two sides鈥.
So the \({hypotenuse}^{2}={6}^{2}+{8}^{2}={100}\).
Therefore the \({hypotenuse}=\sqrt{100}={10}~{cm}\).
Question 4
What is the length of the hypotenuse of a right-angled triangle when the lengths of the other sides are \({5}~{cm}\) and \({9}~{cm}\)?
Answer
Remember that 鈥榯he square on the hypotenuse is equal to the sum of the squares on the other two sides鈥.
So the \({hypotenuse}^{2}={5}^{2}+{9}^{2}={106}\).
Therefore the \({hypotenuse}=\sqrt{106}={10.3}~{cm}~(1~dp)\).
Question 5
What is the length of the hypotenuse of a right-angled triangle when the lengths of the other sides are \({6}~{m}\) and \({12}~{m}\)?
Answer
Remember that 鈥榯he square on the hypotenuse is equal to the sum of the squares on the other two sides'.
So the \({hypotenuse}^{2}={6}^{2}+{12}^{2}={180}\).
Therefore the \({hypotenuse}=\sqrt{180}={13.4}~{m}~(1~dp)\).
Question 6
What is the length of one side of a right-angled triangle when the length of the hypotenuse is \({10}~{cm}\) and the length of the other side is \({4}~{cm}\)?
Answer
Remember that 鈥榯he square on the hypotenuse is equal to the sum of the squares on the other two sides鈥.
\({x}={length~of~side}\)
So \({10}^{2}={x}^{2}+{4}^{2}\), \({x}^{2}={10}^{2}-{4}^{2}={84}\)
\({x}=\sqrt{84}={9.2}~{cm}~(1~dp)\).
Question 7
What is the length of one side of a right-angled triangle when the length of the hypotenuse is \({18}~{cm}\) and the length of the other side is \({10}~{cm}\)?
Give your answer correct to \({1}\) decimal place.
Answer
Remember that 鈥榯he square on the hypotenuse is equal to the sum of the squares on the other two sides鈥.
\({x}={length~of~side}\)
So \({18}^{2}={x}^{2}+{10}^{2}\)
\({x}^{2}={18}^{2}-{10}^{2}={224}\)
\({x}=\sqrt{224}={15.0}~{cm}~(1~dp)\).
Question 8
What is the length of one side of a right-angled triangle when the length of the hypotenuse is \({20}~{mm}\) and the length of the other side is \({14}~{mm}\)?
Answer
Remember that 鈥榯he square on the hypotenuse is equal to the sum of the squares on the other two sides鈥.
\({x}={length~of~side}\)
So \({20}^{2}={x}^{2}+{14}^{2}\)
\({x}^{2}={20}^{2}-{14}^{2}={204}\)
\({x}=\sqrt{204}={14.3}~{mm}~(1~dp)\).
Question 9
\({A}\) is located at \(({1},~{2})\), and \({B}\) is located at \(({5},~{6})\).
What is the length of \({AB}\)?
Answer
Note that the width of the triangle is \({4}~{units}\) (\({x}\)-coordinates: \({5}-{1}={4}\)) and the height of the triangle is \({4}~{units}\) (\({y}\)-coordinates: \({6}-{2}={4}\)), so the \({length~of~the~hypotenuse}=\sqrt({4}^{2}+{4}^{2})={5.7}~{units}~(1~dp)\).
Question 10
\({X}\) is located at \(({3},~{1})\), and \({Y}\) is located at \(({6},~{4})\).
What is the length of \({XY}\)?
Answer
Note that the width of the triangle is \({3}~{units}\) (\({x}\)-coordinates: \({6}-{3}={3}\)) and the height of the triangle is \({3}~{units}\) (\({y}\)-coordinates: \({4}-{1}={3}\)), so the \({length~of~the~hypotenuse}=\sqrt({3}^{2}+{3}^{2})={4.2}~{units}~(1~dp)\)
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