Consider a uniform disc of mass `m`, radius `r` rolling without slipping on a rough surface with linear acceleration `a` and angular acceleration `alpha` due to an external force F as shown in the figure coefficient of friction is `mu`.
Q. The magnitude of frictional force acting on the disc is

Consider a uniform disc of mass m , radius r rolling without slipping on a rough surface with linear acceleration a and angular acceleration alpha due to an external force F as shown in the figure coefficient of friction is mu . Q. The work done by the frictional force at the instant of pure rolling is

Consider a uniform disc of mass m , radius r rolling without slipping on a rough surface with linear acceleration a and angular acceleration alpha due to an external force F as shown in the figure coefficient of friction is mu . Q. Angular momentum of the disc will be conserved about

A solid uniform disc of mass m rolls without slipping down a fixed inclined plank with an acceleration a. The frictional force on the disc due to surface of the plane is

A solid uniform disc of mass m rols without slipping down a fixed inclined plank with an acceleration a. The frictional force on the disc due to surface of the plane is

A force F is applied horizontally on a cylinder in the line of centre as shown in the figure. The cylinder is on a rough surface of coefficient of fricition mu . The direction of the friction force acting on the cylinder will be

A ring of mass m and radius R is acted upon by a force F as shown in the figure. There os sufficient friction between the ring and the ground. The force of friciton force necessary for pure rolling is

A force F is applied at the top of a ring of mass M and radius R placed on a rough horizontal surface as shown in figure. Friction is sufficient to prevent slipping. The friction force acting on the ring is:

A spherical shell of mass m and radius R is rolling up without slipping on a rough inclined plane as shown in the figure. The direction of static friction acting on the shell is

Choose the correct option: A disc of radius R rolls on a horizontal ground with linear acceleration a and angular acceleration alpha as shown in Fig. The magnitude of acceleration of point P as shown in the figure at an instant when its linear velocity is v and angular velocity is omega will be a

A sphere of mass m rolls without slipping on an inclined plane of inclination theta . Find the linear acceleration of the sphere and the force of friction acting on it. What should be the minimum coefficient of static friction to support pure rolling?