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Parents Pricing Home Leaving Cert Mathematics Trigonometry The diagram below shows a triangular patch of ground \( \triangle GHS \), with \(|SH| = 58 \) m, \(|GH| = 30 \) m and \(|GHS| = 68^\circ \)
The diagram below shows a triangular patch of ground \( \triangle GHS \), with \(|SH| = 58 \) m, \(|GH| = 30 \) m and \(|GHS| = 68^\circ \) - Leaving Cert Mathematics - Question 9 - 2019 Question 9
View full question The diagram below shows a triangular patch of ground \( \triangle GHS \), with \(|SH| = 58 \) m, \(|GH| = 30 \) m and \(|GHS| = 68^\circ \). The circle is a helicopt... show full transcript
View marking scheme Worked Solution & Example Answer:The diagram below shows a triangular patch of ground \( \triangle GHS \), with \(|SH| = 58 \) m, \(|GH| = 30 \) m and \(|GHS| = 68^\circ \) - Leaving Cert Mathematics - Question 9 - 2019
Find \(|SG|\). Give your answer in metres, correct to 1 decimal place. Only available for registered users.
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To find (|SG|), we can use the cosine rule:
∣ S G ∣ 2 = ∣ S H ∣ 2 + ∣ G H ∣ 2 − 2 ∣ S H ∣ ∣ G H ∣ cos ( ∠ G H S ) |SG|^2 = |SH|^2 + |GH|^2 - 2|SH| |GH| \cos(\angle GHS) ∣ SG ∣ 2 = ∣ S H ∣ 2 + ∣ G H ∣ 2 − 2∣ S H ∣∣ G H ∣ cos ( ∠ G H S )
Substituting the known values:
∣ S G ∣ 2 = 3 0 2 + 5 8 2 − 2 ⋅ 30 ⋅ 58 ⋅ cos ( 6 8 ∘ ) |SG|^2 = 30^2 + 58^2 - 2 \cdot 30 \cdot 58 \cdot \cos(68^\circ) ∣ SG ∣ 2 = 3 0 2 + 5 8 2 − 2 ⋅ 30 ⋅ 58 ⋅ cos ( 6 8 ∘ )
Calculating each part:
(30^2 = 900)
(58^2 = 3364)
(\cos(68^\circ) \approx 0.3746) leads to (-2 \cdot 30 \cdot 58 \cdot 0.3746 \approx -1293.6)
Now, summing these results:
∣ S G ∣ 2 = 900 + 3364 − 1293.6 = 2960.4 ⇒ ∣ S G ∣ ≈ 54.4 m |SG|^2 = 900 + 3364 - 1293.6\ = 2960.4\Rightarrow |SG| \approx 54.4 \text{ m} ∣ SG ∣ 2 = 900 + 3364 − 1293.6 = 2960.4 ⇒ ∣ SG ∣ ≈ 54.4 m
Find \( \angle HSG \). Give your answer in degrees, correct to 2 decimal places. Only available for registered users.
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Using the sine rule:
∣ G H ∣ sin ( ∠ H S G ) = ∣ S G ∣ sin ( ∠ G H S ) \frac{|GH|}{\sin(\angle HSG)} = \frac{|SG|}{\sin(\angle GHS)} s i n ( ∠ H SG ) ∣ G H ∣ = s i n ( ∠ G H S ) ∣ SG ∣
Substituting our known values gives:
30 sin ( ∠ H S G ) = 54.4 sin ( 6 8 ∘ ) \frac{30}{\sin(\angle HSG)} = \frac{54.4}{\sin(68^\circ)} s i n ( ∠ H SG ) 30 = s i n ( 6 8 ∘ ) 54.4
From which solving for ( \angle HSG ) provides:
sin ( ∠ H S G ) ≈ 30 ⋅ sin ( 6 8 ∘ ) 54.4 ≈ 0.51131 \sin(\angle HSG) \approx \frac{30 \cdot \sin(68^\circ)}{54.4} \approx 0.51131 sin ( ∠ H SG ) ≈ 54.4 30 ⋅ s i n ( 6 8 ∘ ) ≈ 0.51131
Thus, ( \angle HSG \approx 30.75^\circ ).
Find the area of \( \triangle GHS \). Give your answer in \( m^2 \), correct to 2 decimal places. Only available for registered users.
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The area ( A ) can be found using the formula:
A = 1 2 ∣ S H ∣ ⋅ ∣ G H ∣ ⋅ sin ( ∠ G H S ) A = \frac{1}{2} |SH| \cdot |GH| \cdot \sin(\angle GHS) A = 2 1 ∣ S H ∣ ⋅ ∣ G H ∣ ⋅ sin ( ∠ G H S )
Substituting our values:
A = 1 2 ⋅ 58 ⋅ 30 ⋅ sin ( 6 8 ∘ ) A = \frac{1}{2} \cdot 58 \cdot 30 \cdot \sin(68^\circ) A = 2 1 ⋅ 58 ⋅ 30 ⋅ sin ( 6 8 ∘ )
Calculating yields:
A ≈ 806.65 m 2 ⇒ 806.65 ≈ 806.65 m 2 A \approx 806.65 \text{ m}^2 \Rightarrow 806.65 \approx 806.65 \text{ m}^2 A ≈ 806.65 m 2 ⇒ 806.65 ≈ 806.65 m 2
Find the area of \( \triangle AHSP \), in terms of \( r \), where \( r \) is the radius of the helicopter pad. Only available for registered users.
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The area can be defined as:
A A H S P = 1 2 ⋅ ∣ S H ∣ ⋅ r A_{AHSP} = \frac{1}{2} \cdot |SH| \cdot r A A H SP = 2 1 ⋅ ∣ S H ∣ ⋅ r
Thus, we denote:
A A H S P = 1 2 ( 58 ) ( r ) = 29 r A_{AHSP} = \frac{1}{2} (58)(r) = 29r A A H SP = 2 1 ( 58 ) ( r ) = 29 r
Show that the area of \( \triangle GHS \), in terms of \( r \), can be written as \( 71-2r \,m^2 \). Only available for registered users.
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The area can be computed using the known triangles. The total area becomes:
A G H S = 1 2 ⋅ 30 ⋅ ( 54.4 − 2 r ) + A A H S P A_{GHS} = \frac{1}{2} \cdot 30 \cdot (54.4-2r) + A_{AHSP} A G H S = 2 1 ⋅ 30 ⋅ ( 54.4 − 2 r ) + A A H SP
Simplifying:
⇒ 15 r + 27 r + 29 r = 71 − 2 r . \Rightarrow 15r + 27r + 29r = 71 - 2r. ⇒ 15 r + 27 r + 29 r = 71 − 2 r .
Find the value of \( r \). Give your answer in metres, correct to 1 decimal place. Only available for registered users.
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Setting equations from previous area calculations yields:
71 − 2 r = 806 − 62 ⇒ 806 − 62 = 71 + 2 r 71 - 2r = 806 - 62\Rightarrow 806-62 = 71 + 2r 71 − 2 r = 806 − 62 ⇒ 806 − 62 = 71 + 2 r
Solving this provides:
r = 806 − 62 71 ≈ 11.3 m r = \frac{806 - 62}{71} \approx 11.3 \text{ m} r = 71 806 − 62 ≈ 11.3 m
Find the height of the pole. Only available for registered users.
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Using the tangent ratio:
tan ( 1 4 ∘ ) = ∣ S T ∣ ∣ P S ∣ ⇒ ∣ S T ∣ = ∣ P S ∣ ⋅ tan ( 1 4 ∘ ) . \tan(14^\circ) = \frac{|ST|}{|PS|}\Rightarrow |ST| = |PS|\cdot \tan(14^\circ). tan ( 1 4 ∘ ) = ∣ PS ∣ ∣ ST ∣ ⇒ ∣ ST ∣ = ∣ PS ∣ ⋅ tan ( 1 4 ∘ ) .
Substituting evaluates:
∣ P S ∣ = 11.3 ⋅ tan ( 1 4 ∘ ) 1 ⇒ ∣ P S ∣ ≈ 42.51 m |PS| = \frac{11.3 \cdot \tan(14^\circ)}{1}\Rightarrow |PS| \approx 42.51 \text{ m} ∣ PS ∣ = 1 11.3 ⋅ t a n ( 1 4 ∘ ) ⇒ ∣ PS ∣ ≈ 42.51 m
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