Solution :
Velocity of the car, [tex]$v_c$[/tex] = 72 km/h
= 20 m/s
Distance from the intersection = 20 m
Velocity of the bicycle, [tex]$v_b$[/tex] = 8 m/s
Distance from the intersection = 32 m
a). The time for the bicycle to reach at the center
[tex]$=\frac{\text{distance}}{\text{velocity}}$[/tex]
[tex]$=\frac{32}{8}=4 \ s$[/tex]
The distance travelled by the car during text reading (3 s) = [tex]$v_c$[/tex] x 3
= 20 x 3
= 60 m
Distance travelled by the car after braking and till the bike reaches at the center -- remaining time = 4 - 3
= 1 second
∴ [tex]$s= ut - \frac{1}{2}at^2$[/tex]
[tex]$s= 20 \times 1 - \frac{1}{2}\times 0.5 \times (1)^2$[/tex]
= 17.5 m
So the total distance travelled by the car in 4 s = 60 + 17.5
= 77.5 m
So the distance between the car and the bike when the bike reaches at the intersection = 80 - 77.5
= 2.5 m
b). Speed of the car when the bike is at the intersection :
v = u - at
= 20 - (5 x 1)
= 15 m/s
[tex]$v_c$[/tex] = 15 [tex]$\hat j$[/tex] m/s
[tex]$v_b$[/tex] = 8 cos 10 [tex]$\hat i$[/tex] - 8 sin 10 [tex]$\hat j$[/tex]
Velocity of the car w.r.t cyclist,
[tex]$\vec{v}_{cb} = \vec v_c - \vec v_b$[/tex]
[tex]$= 15 \hat j - (8 \cos 10 \ \hat i - 8 \sin 10 \hat j)$[/tex]
[tex]$= -7.87\ \hat i+ 16.3\ \hat j $[/tex]
c). When the car stops, the distance travelled by the car is
[tex]$v^2=u^2-2as$[/tex]
or [tex]$s=\frac{u^2}{2a}$[/tex]
[tex]$=\frac{20^2}{2 \times 5}$[/tex]
= 40 m
The car applied brake when it was 20 m before the intersection.
So the car will stop 20 m after the intersection.
