An automobile travelling with a speed of 60 km/h, can brake to stop within a distance of 20 m. If the car is going twice as fast, i.e. 120 km/h, the stopping distance will be
(1) 20 m
(2) 40 m
(3) 60 m
(4) 80 m
A lift is going up. The total mass of the lift and the passenger is 1500 kg. The variation in the speed of the lift is as given in the graph. The height to which the lift takes the passenger is
(1) 3.6 meters
(2) 8 meters
(3) 1.8 meters
(4) 36 meters
A bus is moving with a velocity 10 m/s on a straight road. A scooterist wishes to overtake the bus in 100 s. If the bus is at a distance of 1 km from the scooterist, with what velocity should the scooterist chase the bus
(1) 50 m/s
(2) 40 m/s
(3) 30 m/s
(4) 20 m/s
Two trains along the same straight rails moving with constant speed 60 km/hr and 30 km/hr respectively towards each other. If at time t = 0, the distance between them is 90 km, the time when they collide is:
1. 1 hr
2. 2 hr
3. 3 hr
4. 4 hr
A 150 m long train is moving to north at a speed of 10 m/s. A parrot flying towards south with a speed of 5 m/s crosses the train. The time taken by the parrot the cross to train would be:
(1) 30 s
(2) 15 s
(3) 8 s
(4) 10 s
Two cars are moving in the same direction with the same speed \(30\) km/hr. They are separated by a distance of \(5\) km. The speed of a car moving in the opposite direction, if it meets these two cars at an interval of \(4\) minutes, will be:
1. \(40\) km/hr
2. \(45\) km/hr
3. \(30\) km/hr
4. \(15\) km/hr
An iron ball and a wooden ball of the same radius are released from a height ‘h’ in a vacuum. The time taken by both of them to reach the ground is
(1) Unequal
(2) Exactly equal
(3) Roughly equal
(4) Zero
Two cars P and Q start from a point at the same time in a straight line and their positions are represented by and . At what time do the cars have the same velocity?
(1)
(2)
(3)
(4)
A particle of unit mass undergoes one-dimensional motion such that its velocity varies according to v(x)= where, and n are constants and x is the position of the particle. The acceleration of the particle as a function of x, is given by
1.
2.
3.
4. +1
A stone falls under gravity. It covers distances h1, h2 and h3 in the first 5 seconds, the next 5 seconds and the next 5 seconds respectively. The relation between h1, h2, and h3 is
1. h1=2h2=3h3
2. h1=h2/3=h3/5
3. h2=3h1 and h3=3h2
4. h1=h2=h3