A particle of mass 1 kg has velocity `vecv_(1)=(2t)hati` and another particle of mass 2 kg has velocity `vecv_(2)=(t^(2))hatj`.
Velocity of the centre of mass at 2 s

A particle of mass 1 kg has velocity vecv_(1)=(2t)hati and another particle of mass 2 kg has velocity vecv_(2)=(t^(2))hatj . Displacement of the centre of mass in 2 s

A particle of mass 1 kg has velocity vecv_(1)=(2t)hati and another particle of mass 2 kg has velocity vecv_(2)=(t^(2))hatj . Net force on the centre of mass at 2 s

The escape velocity of a particle of mass m is

Two particles of masses 1 kg and 2 kg are positioned on x-and y-axes at distances of 1 m and 2 m from the origin respectively. Find the position of the centre of mass of the system.

Two particles of masses m_1 and m_2 move on the same plane. If their relative velocity is u, and the velocity of their centre of mass is v, show that the total kinetic energy is 1/2(m_1+m_2)v^2+1/2 ((m_1m_2)/(m_1+m_2))u^2 .

A charged particle of mass m_(1) and charge q_(1) is revolving in a cricle of radius r. another charged particle of charge q_(2) and mass m_(2) is situated at the centre of the circle. If the velocity and time period of the revolving particle be v and T respectively, then,

A particle of charge q moves with a velocity vecv=ahati+bhatj in magnetic field vecB=chati+dhatj . The force acting on the particle has magnitude F. Them

Two ice skaters A and B approach each other at right angles. Skater A has a mass 30 kg and velocity 1 "m.s"^(-1) , skater B has a mass 20 kg and velocity 2"m.s"^(-1) . They meet and cling together. Find the final velocity (in "m.s"^(-1) ) of the couple.