At 12 noon, ship A is north west of ship B as shown. Ship A is moving north 85° east at a uniform speed of 15 km h⁻¹. Ship B is moving in a straight line with uniform speed v km h⁻¹. Ship B intercepts ship A. (i) Find the least possible value of v. (ii) If v = 13 km h⁻¹, find the two possible directions that ship B can travel in order to intercept ship A. (b) A man can swim at $rac{5}{6}$ m s⁻¹ in still water. He swims across a river 125 m wide. The river flows at a constant speed of $rac{25}{18}$ m s⁻¹ parallel to the straight banks. How long will it take him if he swims so as to reach the opposite bank (i) as quickly as possible (ii) as little downstream as possible?

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At 12 noon, ship A is north west of ship B as shown - Leaving Cert Applied Maths - Question 2 - 2016

Question 2

At 12 noon, ship A is north west of ship B as shown. Ship A is moving north 85° east at a uniform speed of 15 km h⁻¹. Ship B is moving in a straight line with unif... show full transcript

Worked Solution & Example Answer:At 12 noon, ship A is north west of ship B as shown - Leaving Cert Applied Maths - Question 2 - 2016

Step 1

(i) Find the least possible value of v.

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Answer

To find the least possible value of v, we start by applying the law of sines in the triangle formed by the positions of the ships.

Using the given information:

Speed of ship A = 15 km/h
Angle at A (between ship A and the North) = 85°
Angle at B = 45°

We apply the law of sines: $\frac{15}{\sin 50^\circ} = \frac{v}{\sin \theta}$

This rearranges to: $v = 15 \cdot \frac{\sin \theta}{\sin 50^\circ}$

For minimal speed, we require ( \sin \theta = 1 ) which gives: $v_{min} = 15 \cdot \frac{1}{\sin 50^\circ} \approx 11.49 \text{ km/h}$

Step 2

(ii) If v = 13 km h⁻¹, find the two possible directions that ship B can travel in order to intercept ship A.

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Answer

When v = 13 km/h:

Using the law of sines again: $\frac{15}{\sin 50^\circ} = \frac{13}{\sin \alpha}$

This results in: $\sin \alpha = 13 \cdot \frac{\sin 50^\circ}{15}$

Calculating: $\sin \alpha \approx 0.8839$

Thus, the angles are: $\alpha \approx 62.1^\circ \text{ or } 117.9^\circ$

These angles represent the two possible directions for ship B to intercept ship A.

Step 3

(i) as quickly as possible

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Answer

To find how long it takes to cross the river as quickly as possible, he should swim directly across:

$t = \frac{125}{\frac{5}{6} \cdot \sin \theta}$

Here, ( \sin \theta = 1 ) (swimming straight across). Thus: $t = \frac{125}{\frac{5}{6}} = 150 ext{ seconds}$

Step 4

(ii) as little downstream as possible?

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Answer

When swimming with minimal downstream drift, we need to balance the flow of the river:

Using trigonometric relationships: $v \sin \alpha = \frac{5}{6} \sin \theta$ $v \cos \alpha = \frac{125}{t}$

Setting up the tangent relationship: $\tan \alpha = \frac{\frac{5}{6} \sin \theta}{\frac{125}{t}}$

Differentiating and solving leads to: $t = \frac{125}{\frac{5}{6} \sin \theta}$

Calculating gives: $t \approx 187.5 ext{ seconds}$

At 12 noon, ship A is north west of ship B as shown - Leaving Cert Applied Maths - Question 2 - 2016

Worked Solution & Example Answer:At 12 noon, ship A is north west of ship B as shown - Leaving Cert Applied Maths - Question 2 - 2016

(i) Find the least possible value of v.

(ii) If v = 13 km h⁻¹, find the two possible directions that ship B can travel in order to intercept ship A.

(i) as quickly as possible

(ii) as little downstream as possible?

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