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 velocity v_(0) and retardation alpha v , where v is the velocity at any time t.

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 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 alphav, where alpha is a constant and v is the velocity at any time t. If the particle is at the origin at t=0 , find (a) (i) velocity as a function of time t. (ii) After how much time the particle stops? (iii) After how much time velocity decreases by 50% ? (b) (i) Velocity as a function of displacement s. (ii) The maximum distance covered by the particle. (c ) Displacement as a function of time t.

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. 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