Airplane B, which is travelling at a constant 560 km/h, is pursuing airplane A, which is travelling northeast at a constant 800 km/hr. At time t = 0, airplane A is 640 km east of airplane B. Determine (a) the direction of the course airplane B should follow (measured from the east) to intercept

Question

Airplane B, which is travelling at a constant 560 km/h, is pursuing airplane A, which is travelling northeast at a constant 800 km/hr. At time t = 0, airplane A is 640 km east of airplane B. Determine (a) the direction of the course airplane B should follow (measured from the east) to intercept plane A, (b) the rate at which the distance between the airplanes is decreasing, (c) how long it takes for airplane B to catch airplane A.

Accepted Answer

STRATEGY: To find when B intercepts A, you just need to find out
when the two planes are at the same location. The rate at which the distance is decreasing is the magnitude of [latex]v_{B/A} [/latex], so you can use the relative velocity equation.
MODELING and ANALYSIS: Choose x to be east, y to be north, and
place the origin of your coordinate system at B (Fig. 1).
Positions of the Planes: You know that each plane has a constant speed, so you can write a position vector for each plane. Thus,

[latex]\begin{aligned}&\mathbf{r}_{A}=\left[\left(v_{A} \cos 45^{\circ} ight) t+640 \mathrm{~km} ight] \mathbf{i}+\left[\left(v_{A} \sin 45^{\circ} ight) t ight] \mathbf{j} (1)\&\mathbf{r}_{B}=\left[\left(v_{B} \cos heta ight) t ight] \mathbf{i}+\left[\left(v_{B} \sin heta ight) t ight] \mathbf{j} (2)\end{aligned}[/latex]

a. Direction of B. Plane B will catch up when they are at the same location, that is, [latex]r_{A}= r_{B}[/latex]. You can equate components in the j direction to find

[latex]v_{A} \sin 45^{\circ} t_{1}=v_{B} \sin heta t_{1}[/latex]

After you substitute in values,

[latex]\begin{aligned}&\sin heta=\frac{\left(v_{A} \sin 45^{\circ} ight) t_{1}}{v_{B} t_{1}}=\frac{(560 \mathrm{~km} / \mathrm{hr}) \sin 45^{\circ}}{800 \mathrm{~km} / \mathrm{hr}}=0.4950\& heta=\sin ^{-1} 0.4950=29.67^{\circ}\& heta=29.7^{\circ}\end{aligned}[/latex]

b. Rate. The rate at which the distance is decreasing is the magnitude
of [latex]v_{B/A}[/latex], so

[latex]\begin{aligned}&\mathbf{v}_{B / A}=\mathbf{v}_{B}-\mathbf{v}_{A}=\left(v_{B} \cos heta \mathbf{i}+v_{B} \sin heta \mathbf{j} ight)-\left(v_{A} \cos 45^{\circ} \mathbf{i}+v_{A} \sin 45^{\circ}\mathbf{j} ight)\&=\left[(800 \mathrm{~km} / \mathrm{h}) \cos 29.668^{\circ}-(560 \mathrm{~km} / \mathrm{h}) \cos 45^{\circ} ight] \mathbf{i}\&+\left[(800 \mathrm{~km} / \mathrm{h}) \sin 29.668^{\circ}-(560 \mathrm{~km} / \mathrm{h}) \sin 45^{\circ} ight] \mathbf{j}\&=299.15 \mathrm{~km} / \mathrm{h} \mathbf{i}\&\left|\mathbf{v}_{B / A} ight|=299 \mathrm{~km} / \mathrm{h}\end{aligned}[/latex]

c. Time for B to catch up with A. To find the time, you equate the i components of each position vector, giving

[latex]\left(v_{A} \cos 45^{\circ} ight) t_{1}+640 \mathrm{~km}=\left(v_{B} \cos heta ight) t_{1}[/latex]

Solve this for [latex]t_{1}[/latex]. Thus,

[latex]\begin{aligned}t_{1} &=\frac{640 \mathrm{~km}}{v_{B} \cos heta-v_{A} \cos 45^{\circ}} \&=\frac{640 \mathrm{~km}}{(800 \mathrm{~km} / \mathrm{h}) \cos 29.67^{\circ}-(560 \mathrm{~km} / \mathrm{h}) \cos 45^{\circ}}=2.139 \mathrm{~h} \t_{1}=2.14 \mathrm{~h}\end{aligned}[/latex]

REFLECT and THINK: The relative velocity is only in the horizontal (eastern) direction. This makes sense, because the vertical (northern) components have to be equal in order for the two planes to intersect.

Question 11.SP.13: Airplane B, which is travelling at a constant 560 km/h, is p...

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