The acceleration of an athlete running at 36 km/h when negotiating a turn of radius 25 m is

The acceleration of a particle in S.H.M. is

In the given figure, a=15 m//s^2 represents the total acceleration of a particle moving in the clockwise direction in a circle of radius R=2.5 m at a given instant of time. The speed of the particle is

The acceleration of a particle executing S.H.M, when it is at its mean position is

The acceleration of a particle performing a linear S.H.M. is 16 cm//s^(2) , when it is at a distance of 4 cm from the mean position. The period of S.H.M. is

To stimulate the acceleration of large rockets astronauts are spun at the end of a long rotating beam of radius 9.8m. Angular velocity, required to generate a centripetal acceleration 8 times the acceleration due to gravity, is.

Tangential acceleration of a particle moving on a circle of radius 1 m varies with time t as shown in the graph (initial velocity of particle is zer). Time after which total acceleration of particle makes an angle of 30^@ with radial acceleration is,

To simulate the acceleration of large rockets , the astronauts are spun at the end of long rotating beam of radius 9.8 m. What will be angular velocity required for generating centripetal acceleration 8 times the acceleration due to gravity ?

A car moves at speed of 36 km hr^-1 on a level road. The coefficient of friction between the tyres and the road is 0.8 . The car negotiates a curve of radius R. IF g=10 ms^-2 , then the car will skid (or slip) while negotiating the curve if the value R is

If the value of the gravitational acceleration at the height h be 1% of its value at the surface of the earth, then h is equal to (given R_e=6400 km )

Derive an expression for critical velocity of satellite. Calculate the acceleration due to gravity at a height of 300 km from the surface of the earth. M = 6xx10^24kg R = 6400 km.