The position of a particle at time moving in `x-y` plane is given by `vec(r) = hat(i) + 2 hat(j) cos omegat`. Then, the motikon of the paricle is :

The position vector of a particle moving in x-y plane is given by vec(r) = (A sinomegat)hat(i) + (A cosomegat)hat(j) then motion of the particle is :

Position vector of a particle moving in x-y plane at time t is r=a(1- cos omega t)hat(i)+a sin omega t hat(j) . The path of the particle is

The time dependence of the position of a particle of mass m = 2 is given by vec(r) (t) = 2t hat(i) - 3 t^(2) hat(j) Its angular momentum, with respect to the origin, at time t = 2 is :

The time dependence of the position of a particle of mass m = 2 is given by vec(r) (t) = 2t hat(i) - 3 t^(2) hat(j) Its angular momentum, with respect to the origin, at time t = 2 is :

A particle is moving in xy-plane in a circular path with centre at origin. If at an instant the position of particle is given by (1)/(sqrt(2)) ( hat(i) + hat(j)) , then velocity of particle is along

If vec(E)=2y hat(i)+2x hat(j) , then find V (x, y, z)

A particle of mass 0.2 kg moves along a path given by the relation : vec(r)=2cos omegat hat(i)+3 sin omegat hat(j) . Then the torque on the particle about the origin is :

The position vector of a particle vec(R ) as a funtion of time is given by: vec(R )= 4sin(2pit)hat(i)+4cos(2pit)hat(j) Where R is in meters, t is in seconds and hat(i) and hat(j) denote until vectors along x-and y- directions, respectively Which one of the following statements is wrong for the motion of particle ?

A particle is moving in a plane with velocity given by vec(u)=u_(0)hat(i)+(aomega cos omegat)hat(j) , where hat(i) and hat(j) are unit vectors along x and y axes respectively. If particle is at the origin at t=0 . Calculate the trajectory of the particle :-

A particle is moving with a position vector, vec(r)=[a_(0) sin (2pi t) hat(i)+a_(0) cos (2pi t) hat(j)] . Then -