CM of the given system of particles will be at

The reference frame, in which the centre of inertia of a given system of particles is at rest, translates with a velocity V relative to an inertial reference frame K. The mass of the system of particles equals m, and the total energy of the system in the frame of the centre of inertia is equal to overset~E . Find the total energy E of this system of particles in the reference frame K.

Choose the wrong statements about the centre of mass (CM) of a system of two particles The CM lies on the line joining the two particles midway between them The CM lies on the line joining them at a point whose distance from each particle is proportional to the square of the mass of that particle The CM is on the line joining them at a point whose distance from each particle is proportional to the mass of that particl The CM lies on the line joining them at a point whose distance from each particle is inversely proportional to the mass of that particle

Particles of masses 1g, 2g, 3g ….100g are kept at the marks 1cm, 2cm, 3cm …., 100 cm respectively on a metre scale. Find the moment of inertia of the system of particles about a perpendicular besector of the metre scale.

The centre of mass of a system of particles is at the origin. It follows that

The position vector of the centre of mass of a system of particles is the _________ of the position vectors of the particles, each particle making a contribution proportional to its _________

Four particles of masses m, 2m, 3m & 4m respectively are placed on the periphery of a circle of radius R as shown in the figure then CM of the system contains the particle is at

Find the radius of gyration of a system of particles about an axis passing through the center of mass and perpendicular to the line joining the particles. The system consists of two particles of masses m_(1) and m_(2) placed at separation at r

Prove that the rate of change of total angular momentum of a system of particles is equal to the total torque acting on the system.

The sum of all the external forces on a system of particles is zero. Which of the following must be true for the system of particles ?