Question

asked Oct 9, 2021 189k views

1 Answer

Frunsi · Answer 1 · 2021-10-14T03:39:44+0000

a) 7 buses

b) 6.8 m

Step-by-step explanation:

a)

The motion of the motorcycle is a projectile motion, so it consists of 2 independent motions:

- A uniform motion along the horizontal direction

- A uniformly accelerated motion along the vertical direction

The initial components of the velocity of the motorcycle are:

$v_x = u cos(32^(\circ))=(40.0)(cos 32^(\circ))=33.9 m/s\\v_y = u sin(32^(\circ))=(40.0)(sin 32^(\circ))=21.2 m/s$

The equation for the vertical motion of the motorcycle is

y=h+u_y t - (1)/(2)gt^2

where

y is the altitude at time t

h is the initial height

g=9.8 m/s^2 is the acceleration due to gravity

The bus top is at the same height of the initial ramp, so we have

y=h

And therefore, we can solve the equation for t, to find the time of flight:

$0=u_y t - (1)/(2)gt^2\\t(u_y-(1)/(2)gt)=0\\t=(2u_y)/(g)=(2(21.2))/(9.8)=4.33 s$

Now we find what is the horizontal distance covered by the motorcycle in its jump, which is given by:

d=v_x t = (33.9)(4.33)=146.8 m

And since each bus has a length of L = 20.0 m, the number of buses that the motorcycle can clear with its jump is:

n=(d)/(L)=(146.8)/(20)=7.34

So, 7 buses.

b)

In the previous problem, we saw that the total range of the motion of the motorcycle is

d=146.8 m

And we said that this corresponds to 7 buses.

Each bus has a length of

L = 20 m

So, the total length of 7 buses is

L' = 7L=7(20)=140 m

Therefore, the range of the motorcycle is greater than the length of the buses by:

$\Delta x = d-L'=146.8-140 = 6.8 m$

which means he will miss the last bus by 6.8 meters.

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