A particle moves with initial velocity `v_(0)` and retardation `alphav`, where v is velocity at any instant t. Then the particle

A particle moves with an initial v_(0) and retardation alphav, where v is its velocity at any time t. (i) The particle will cover a total distance v_(0)/alpha . (ii) The particle will come to rest after time 1/alpha . (iii) The particle will continue to move for a very long time. (iv) The velocity of the particle will become v_(0)/2 after time (1n2)/alpha

A particle moves with an initial velocity V_(0) and retardation alpha v , where alpha is a constant and v is the velocity at any time t. Velocity of particle at time is :

A particle moves with an initial velocity V_(0) and retardation alpha v , where alpha is a constant and v is the velocity at any time t. total distance covered by the particle is

A particle moves with an initial velocity V_(0) and retardation alpha v , where alpha is a constant and v is the velocity at any time t. After how much time, speed of particle decreases by 75%

A particle starts moving with initial velocity u=25ms^-1 and retardation a=-2ms^-2 . Draw the velocity-time graph.

A particle moving in the positive x-direction has initial velocity v_(0) . The particle undergoes retardation kv^(2) , where vis its instantaneous velocity. The velocity of the particle as a function of time is given by:

A particle is projected horizontally from the top of a tower with a velocity v_(0) . If v be its velocity at any instant, then the radius of curvature of the path of the particle at that instant is directely proportional to

If a particle starts moving with initial velocity u=1ms^-1 and acceleration a=2ms^-2 , the veloctiy of the particle at any time is given by v=u+at=1+2t . Plot the velocity-time graph of the particle.

A particle is projected with a velocity u making an angle theta with the horizontal. At any instant its velocity becomes v which is perpendicular to the initial velocity u. Then v is

Two particles are moving with velocities v_(1) and v_2 . Their relative velocity is the maximum, when the angle between their velocities is