A particle of mass `m` is moving with constant velocity `v_(0)` along the line `y=b`. At time `t=0` it was at the point `(0,b)`. At time `t=(b)/(v_(0))`, the

A particle of mass m is travelling with a constant velocity v=v_(0)hati along the line y=b,z=0 . Let dA be the area swept out by the position vector from origin to the particle in time dt and L the magnitude of angular momentum of particle about origin at any time t. Then

Block B moves to the right with a constant velocity v_(0) . The velocity of body a relative to b is

Two particles A and B are moving with constant velocities V_(1)=hatj and v_(2)=2hati respectively in XY plane. At time t=0, the particle A is at co-ordinates (0,0) and B is at (-4,0). The angular velocities of B with respect to A at t=2s is (all physical quantities are in SI units)

A particle of mass m is moving along the line y-b with constant acceleration a. The areal velocity of the position vector of the particle at time t is (u=0)

A particle is moving with constant speed v along x - axis in positive direction. Find the angular velocity of the particle about the point (0, b), when position of the particle is (a, 0).

A particle of mass m, moving in a circular path of radius R with a constant speed v_2 is located at point (2R, 0) at time t = 0 and a man starts moving with a velocity v_0 along the positive y-axis from origin at time t = 0. Calculate the linear momentum of the particle w.r.t. man as a function of time ______________.

Two particles A and B are moving with constant velocities v_1 and v_2 . At t = 0 , v_1 makes an angle theta_0 with the line joining A and B and v_2 makes an angle theta_2 with the line joining A and B . (a) Find the condition for A and B to collide. (b) Find the time after which A and B will collide if separation between them is d at t = 0 . .

A particle of mass m is moving anticlockwise, in a circle of radius R in x-y plane with centre at (R,0) with a constant speed v_(2) . If is located at point (2R,0) at time t=0 . A man starts moving with a velocity v_(1) along the positive y -axis from origin at t=0 . Calculate the linear momentum of the particle w.r.t. man as a function of time.

Two blocks A and B of masses m and 2m respectively are placed on a smooth floor. They are connected by a spring. A third block C of mass m moves with a velocity v_0 along the line joing A and B and collides elastically with A, as shown in figure. At a certain instant of time t_0 after collision, it is found that the instantaneous velocities of A and B are the same. Further, at this instant the compression of the spring is found to be x_0 . Determine (i) the common velocity of A and B at time t_0 , and (ii) the spring constant.

Two particles of masses m_(1) and m_(2) in projectile motion have velocities vec(v)_(1) and vec(v)_(2) , respectively , at time t = 0 . They collide at time t_(0) . Their velocities become vec(v')_(1) and vec(v')_(2) at time 2 t_(0) while still moving in air. The value of |(m_(1) vec(v')_(1) + m_(2) vec(v')_(2)) - (m_(1) vec(v)_(1) + m_(2) vec(v)_(2))|