The displacement of the particle varies with time according to the relation . Then the velocity of the particle is
1.
2.
3.
4. None of these
1. | \(-\frac{1}{2}\left(a\omega^2\sin\omega t\right)t^2\) | 2. | \(a\omega \sin \omega t\) |
3. | \(a\omega \cos \omega t\) | 4. | \(a\sin \omega t\) |
If the velocity of a particle is (10 + 2t2) m/s, then the average acceleration of the particle between 2 sec and 5 sec is:
1. 2 m/s2
2. 4 m/s2
3. 12 m/s2
4. 14 m/s2
A thief is running away on a straight road in a jeep moving with a speed of \(9\) m/s. A policeman chases him on a motorcycle moving at a speed of \(10\) m/s. If the instantaneous separation of the jeep from the motorcycle is \(100\) m, how long will it take for the policeman to catch the thief?
1. \(1\) s
2. \(19\) s
3. \(90\) s
4. \(100\) s
A car A is travelling on a straight level road with a uniform speed of 60 km/h. It is followed by another car B which is moving with a speed of 70 km/h. When the distance between them is 2.5 km, the car B is given a deceleration of 20 km/h2. After how much time will B catch up with A
1. 1 hr
2. 1/2 hr
3. 1/4 hr
4. 1/8 hr
The speed of a body moving with uniform acceleration is u. This speed is doubled while covering a distance S. When it covers an additional distance S, its speed would become
1.
2.
3.
4.
Two trains one of length 100 m and another of length 125 m, are moving in mutually opposite directions along parallel lines, meet each other, each with speed 10 m/s. If their acceleration are 0.3 m/s2 and 0.2 m/s2 respectively, then the time they take to pass each other will be
1. 5 s
2. 10 s
3. 15 s
4. 20 s
A body starts from rest with uniform acceleration. If its velocity after n second is v, then its displacement in the last two seconds is
1.
2.
3.
4.
A particle is moving in a straight line and passes through a point O with a velocity of 6 ms–1. The particle moves with a constant retardation of 2 ms–2 for 4 s and there after moves with constant velocity. How long after leaving O does the particle return to O
1. 3s
2. 8s
3. Never
4. 4s
A particle is projected with velocity along x-axis. The deceleration of the particle is proportional to the square of the distance from the origin i.e., The distance at which the particle stops is :
1.
2.
3.
4.