A two particles P and Q are separated by distance d apart. P and Q move with velocity v and u making an angle `60^@` and `theta` with line PQ the graph between their relative separation (8) when time t is shown in figure (2). The velocity v in terms of u

Two particles 1 and 2 move with velocities vec v_1 and vec v_2 making the angles theta_1 and theta_2 with the line joining them, respectively. Find angular velocity of relative to 1 . .

Two particles A and B are situated at a distance d = 2m apart. Particle A has a velocity of 10 m//s at an angle of 60^@ and particle B has a velocity v at an angle 30^@ as shown in figure. The distance d between A and B is constant. the angular velocity of B with respect to A 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

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

A particle of charge -q and mass m enters a uniform magnetic field vecB (perpendicular to paper inward) at P with a velocity v_0 at an angle alpha and leaves the field at Q with velocity v at angle beta as shown in fig.

The position-time graph for two particles P and Q moving on x-axis is shown in the figure. Then

A particle is projected from a point P with a velocity v at an angle theta with horizontal. At a certain point Q it moves at right angles to its initial direction. Then

A particle is projected from a point P with a velocity v at an angle theta with horizontal. At a certain point Q it moves at right angles to its initial direction. Then

Two particles A and B start from the origin along x -axis. Velocity time graph of both particles are shown in the figure. During the given time interval, the maximum separation between the particles is

A ring of radius R moves with a velocity v in a uniform static magnetic field B as shown in diagram. The emf between P and Q is