A thin circular ring of area A is held perpendicular to a uniform magnetic field of induction B. A small cut is made in the ring and a galvanometer is connected across the ends such that the total resistance of the circuit is R. When the ring is suddenly squeezed to zero area, the charge flowing through the galvanometer is

A semi circular conducting ring acb of radius R moves with constant speed v in a plane perpendicular to uniform magnetic field B as shown in figure. Identify the correct statement.

A metallic ring of radius r with a uniform metallic spoke of negligible mass and length r is rotated about its axis with angular velocity omega in a perpendicular uniform magnetic field B as shown in Fig. 3.163. The central end of the spoke is connected to the rim of the wheel through a resistor R as shown. The resistor does not rotate, its one end is always at the center of the ring and the other end is always in as shown is needed to maintain constant angular velocity of the wheel. F is equal to (the ring and the spoke has zero resistance)

A metallic ring of mass 2 kg and radius 1 m with with a uniform metallic spoke of same mass 2 kg and length 1 m is rotated about its axis with angular velocity "1 rev sec"^(-1) . In a perpendicular uniform magnetic field B of magnitude 10 T as shown in the figure. If the central end of the spoke is connected to the rim of the wheel through a resistor R of magnitude pi Omega as shown. The resistor does not rotate, It's one end is always at the centre of the ring and another end is always in contact with the ring. A force F as shown is needed to maintain the constant angular velocity of the spoke then, F is equal to (The ring and the spoke has zero resistance)

A conducting loop of radius R is present in a uniform magnetic field B perpendicular to the plane of the ring. If radius R varies as a function of time t, as R =R_(0) +t . The emf induced in the loop is

A conducting ring of radius r and resistance R is placed in region of uniform time varying magnetic field B which is perpendicular to the plane of the ring. It the magnetic field is changing at a rate alpha , then the current induced in the ring is

A thin semi-circular conducting ring of radius R is falling with its plane verticle in horizontal magnetic induction (vec B) . At the position MNQ the speed of the ring is v, and the potential difference developed across the ring is

A thin wire ring of radius a and resitance r is located inside a long solenoid is equal to l , its cross-sectional radius , to b . At a certain moment the solenoid was connected to a source of a constant voltage V . The total resistance of the circuit is equal to R . Assuming the the radial force acting per unit length of the ring.

A conducting light string is wound on the rim of a metal ring of radius r and mass m . The free end of the string is fixed to the ceiling. A vertical infinite smooth conducting plane is always tangent to the ring as shown in the figure. A uniform magnetic field Bis applied perpendicular to the plane of the ring. The ring is always inside the magnetic field. The plane and the strip are connected by a resistance R . When the ring is released, find a. the curent in the resistance R as as function of time. b. the terminal velocity of the ring.

The figure shows a non conducting ring of radius R carrying a charge q . In a circular region of Radius r , a uniform magnetic field B perpendicular to the plane of the ring varies at a constant rate (dB)/(dt)=beta . The torque on the ring is

Consider a coil (of area A, resistance R and number of turns N) held perpendicular to a uniform magnetic field of strength B. The coil is now turned through 180^(@) in time Deltat . What is (i) Average induced emf (ii) Average induced current (iii) Total charge that flows through a given cross-section of the coil?