8 ROTATIONAL MOTION 8.11 Combined translational and rotational motion
b v^
cylinder
surface
f
since the perpendicular distance between the line of action of f and the axis
of rotation is the radius, b, of the cylinder. Note that the friction force acts to
decelerate the cylinder’s rotational motion. If the cylinder is slipping with respect
to the surface, then the friction force, f, is equal to the coefficient of friction, μ,
times the normal reaction, M g, at the surface:f = μ M g.
Finally, the moment of inertia of the cylinder isI =1
M b^2.
2The above equations can be solved to givėv = μ g,b ω ̇ = − 2 μ g.Given that v = 0 (i.e., the cylinder is initially at rest) and ω = ω 0 at time t = 0 ,
the above expressions can be integrated to givev = μ g t,
b ω = b ω 0 − 2 μ g t,which yields
v − b ω = −(b ω 0 − 3 μ g t).Now, the cylinder stops slipping as soon as the “no slip” condition,v = b ω,