A partical moves from rest at A on the surface of a smooth circule cylinder of radius `r` as shown . At `B` it leavels the cylinder. The equation releaseder . The equation relating `alpha and beta` is

A particle of mass m initially at rest starts moving from point A on the surface of a fixed smooth hemisphere of radius r as shown. The particle looses its contact with hemisphere at point B.C is centre of the hemisphere. The equation relating theta and theta' is .

A particle of mass m initially at rest starts moving from point A on the surface of a fixed smooth hemisphere of radius r as shown. The particle looses its contact with hemisphere at point B.C is centre of the hemisphere. The equation relating theta and theta' is .

A particle of mass m moves along the internal smooth surface of a vertical cylinder of the radius R. Find the force with which the particle acts on the cylinder wall if at the initial moment of time its velocity equals v_(0) . And forms an angle alpha with the horizontal.

An infinite cylinder of radius r_(o), carrying linear charge density lamda. The equation of the equipotential surface for the cylinder is

From a cylinder of radius R, a cylider of radius R//2 is removed, as shown in Fig. Current flowing in the remaining cylinder is I. Then, magnetic field strength is

From a cylinder of radius R, a cyclinder of radius R/2 is removed, as shown . Current flowing in the remaning cylinder is l. magnetic field strength is :

A small block of mass m is released from rest from position A inside a smooth hemispherical bowl of radius R as shown in figure Choose the wrong option.

A cylinder of mass M and radius R moves with constant speed v through a region of space that contains dust particles of mass m which is at rest. There are n number of particles per unit volume. The cylinder moves in a direction perpendicular to its axis. Assume mlt ltM , and assumes the particles do not interact wilth each other. All the collision takes place is perfectly elastic and the surface of the cylinder is smooth. The drag force per unit length of the cyliner require to maintain the speed v contant for the cylinder is K/3nmRv^(2) . Find the value of K ?

A small solid cylinder of radius r is released coaxially from point A inside the fixed large cylindrical bawl of radius R as shown in figure. If the friction between the small and the large cylinder is sufficient enough to prevent any slipping then find. (a). What fractions of the total energy are translational and rotational when the small cylinder reaches the bottom of the larger one? (b). The normal force exerted by the small cylinder on the larger one when it is at the bottom.

As shown, a narrow beam of light is incident onto a semi-circular glass cylinder of radius R. Light can exit the cylinder when the beam is at the centre. When the beam is moved parallel to a maximum distance d from the central line, no light can exit the cylinder from its lower surface. Find the refractive index of the glass.