A body of mass `m` and radius `r` is released from rest along a smooth inclined plane of angle of inclination `theta`. The angular momentum of the body about the instantaneous point of contact after a time `t` from the instant of release is equal to

A body of mass m and radius r is released from rest along a smooth inclined plane of angle of inclination theta . The angular momentum of the body about the instantanoues point contact after a time t from the instant of release of equal is :

A triangular prism of mass m placed on it is released from rest on a smooth inclined plane of inclination theta The block does not slip on the prism. Then

A spherical object of mass m and radius R is released from the top of a smooth inclined plane of height h and angle of inclination is 37° . The radius of gyration of the object is K. The speed of object at the bottom of inclined plane is

A sphere is released on a smooth inclined plane from the top. When it moves down, its angular momentum is

A block is released from rest from point on a rough inclined place of inclination 37^(@). The coefficient of friction is 0.5.

An uniform spherical shell of mass m and radius R starts from rest with pure rolling on long inclined plane as shown in figure. The angular momentum of shell about point of contact after 1 s of its starting is KmR. Determine the value of k(g=10m//s^(2)) .

A body of mass m is kept on a rough fixed inclined plane of angle of inclination theta=30^(@) . It remains stationary. Then magnitude of force acting on the body by the inclined plane is equal to :

A body of mass m is projected with a velocity u at an angle theta with the horizontal. The angular momentum of the body, about the point of projection, when it at highest point on its trajectory is

An object of mass m is released from rest from the top of a smooth inclined plane of height h. Its speed at the bottom of the plane is proportional to

A uniform cylinder of mass M and radius R is released from rest on a rough inclined surface of inclination theta with the horizontal as shown in figure. As the cylinder rolls down the inclined surface, the maximum elongation it the spring stiffness k is