Discuss the effect of rolling on inclined plane and derive the expression for the acceleration.

Let us assume a round object of mass m and radius R is rolling down an inclined plane without slipping as shown in figure. There are two forces acting on the object along the inclined plane. One is the component of gravitational force `(mg sin theta)` and the other is the static frictional force (f). The other component of gravitation force `(mg cos theta)` is cancelled by the normal force (N) exerted by the plane. As the motion is happening along the incline, we shall write the equation for motion from the free body diagram (FBD) of the object.
For translational motion, `mg sin theta` is the supporting force and f is the opposing force `mg sin theta-f= ma`
For rotational motion, let us take the torque with respect to the center of the object. Then `mg sin theta` cannot cause torque as it passes through it but the frictional forcef can set torque of Rs. Rf-
`Rf=I alpha`
By using the relation, `a=r alpha`, and moment of inertia `I= mK^(2)`, we get
`Rf=mK^(2)(a)/(R), f= ma ((K^(2))/(R^(2)))`
Now equation becomes,
`mg sin theta- ma ((K^(2))/(R^(2)))=ma`
`mg sin theta= ma+ma((K^(2))/(R^(2)))`
`a(1+(K^(2))/(R^(2)))= g sin theta`
After rewriting it for acceleration, we get
`a=(g sin theta)/((1+(K^(2))/(R^(2))))`
We can also find the expression for final velocity of the rolling object by using third equation of motion for the inclined plane
`v^(2)=u^(2)+2as`. If the body starts rolling from rest, -0. When his the vertical height of the incline, the length of the incline s is, `s=(h)/(sin theta)`
`v^(2)=2(g sin theta)/((1+(K^(2))/(R^(2)))) ((h)/(sin theta))=(2gh)/((1+(K^(2))/(R^(2))))`
By taking square root,
`v=sqrt((2gh)/((1+(K^(2))/(R^(2)))))`
The time taken for rolling down the incline could also be written from first equation of motion as `v=u+at`.. For the object which starts rolling from rest, -0. Then,
`t=(v)/(a)`
`t=(sqrt((2gh)/((1+(K^(2))/(R^(2)))))) (((1+(K^(2))/(R^(2))))/(g sin theta))`
`sqrt ((2h(1+(K^(2))/(R^(2))))/(g sin theta))`
The equation suggests that for a given incline, the object with the least value of radius of gyration K will reach the bottom of the incline first.