If `m_(1), m_(2),m_(3)` and `m_(4)` are masses of four bodies 0.3 kg, 0.3 mg, `0.3xx10^(-6)g` nad 3000 g respectively. The above in increasing order of masses are as sollows

If m_(1),m_(2),m_(3)andm_(4) are masses of four bodies 0.3 g, 0.3 kg, 0.3xx10^(-6) g and 3000 g respectively. The above, in increasing order of masses, are as follows.

Two blocks of mass m_(1) = 6 kg and m_(2) = 3kg are as shown in the diagram. Coefficient of friction between m_(1) and m_(2) and between m_(1) and m_(2) and between m_(1) and the surface is 0.5 and 0.4 , respectively . The maximum horizontal force that can be applied to the mass m_(1) so that they move without separation is

Four particle of masses m_(1)=2kg,m_2=4kg,m_(3)=1kg and m_(4) are placed at four corners of a square as shown in figure. Can mass of m_(4) be adjusted I such a way that the centre of mass of system will be at the centre of the square C.

The centres of three spherical masses of 1 kg, 2 kg and 3 kg have co-orinates (4,0) m,(0,3)m and (-2,5)m respectively. What is the position vector of its centre of mass is terms of its x and y co-ordinates?

An aluminium wire is wound on a piece of cork of mass m_("cork") . The densities rho_("cork") , rho_(a1) , and rho_(w) , of cork, aluminium, and water are 0.5 xx 10^(3) kg//m^(3), 2.7 xx 10^(3) kg//m^(3) , and 1 xx 10^(3) kg//ms respectively. Determine the minimum mass ma t of the wire that should be wound on the cork so that the cork with the wire is completely submerge 1 in water.

Find the loss of KE of the two particles of mass m_(1)=3 kg & m_(2)=6 kg , moving towards each other with speed u_(1)=5 m//s, u_(2)=10 m//s respectively. The coefficient of restitution of collision of the particles is e = 0.5.