Here, ` m = 9.8 xx 10^(-3) kg//m`
`theta = 30^(@) , g = 9.8 m//s^(2) `
` upsilon = 100 m//s , M_(1) = ? M_(2) = ? `
The various forces acting on the system are shown in
As the system of two masses is in equilibrium therefore ,
` T = M_(1) g sin theta = M_(1) g sin 30^(@) = (M_(1) g )/(2) `
` R = M_(1) g cos theta = M_(1) g cos 30^(@) = M_(1) g sqrt3/(2) `
Also ` T = M_(2) g`
From (i) and (iii) , ` T = (M_(1) g )/(2) = M_(2) g `
` M_(1) = 2 M_(2) `
Now the velocity of transverse waves is
` upsilon= sqrt((T)/(m) `
` T = upsilon^(2) xx m = (100)^(2) xx 9.8 xx 10^(-3) = 9.8 N `
From (iii) `M_2 = (T)/(g) = (98)/(9.8) = 10 kg `
From `M_(1) = 2 M_(2) = 2 xx 10 kg = 20 kg `