Two particles A And B , move with constant velocities `v_(1)` and `v_(2)` At the initial moment their position vectors are `r_(1)` and `r_(2)`
respectively. The condition for particle A and B for their collision is

Two particles, 1 and 2, move with constant velocities v_1 and v_2 . At the initial moment their radius vectors are equal to r_1 and r_2 . How must these four vectors be interrelated for the particles to collide?

Two point masses 1 and 2 move with uniform velocities vec(v)_(1) and vec(v)_(2) , respectively. Their initial position vectors are vec(r )_(1) and vec(r )_(2) , respectively. Which of the following should be satisfied for the collision of the point masses?

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)

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 move with constant velocity vec(v_1) and vec(v_2) along two mutually perpendicular straight lines towards intersection point O as shown in figure, At moment t = 0 particles were located at distance l_1 and l_2 respectively from O. Then minimu distance between the particles and time taken are respectively

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

Four particles A, B, C and D are moving with constant speed v each at the instant shown relative velocity of A with respect to B, C and D are in directions

Four particles A, B, C and D are moving with constant speed v each. At the instant shown relative velocity of A with respect to B, C and D are in directions :-

Particle A of mass m_1 moving with velocity (sqrt3hati+hatj)ms^(-1) collides with another particle B of mass m_2 which is at rest initially. Let vec(V_1) and vec(V_2) be the velocities of particles A and B after collision respectively. If m_1 = 2m_2 and after collision vec(V_1) - (hati + sqrt3hatj)ms^(-1) , the angle between vec (V_1) and vec (V_2) is :

Two objects A and B are moving in opposite directions with velocities v_(A) and v_(B) respectively, the magnitude of relative velocity of A w.r.t. B is