The magnetic flux through Circuit of resistance R chages by an amount `Deltapsi` in a time `Delta t`. Then the total quqntity in the circuit during thime `Deltat` is respresented by

The magnetic flux through a circuit of resistance R changes by an amount Deltaphi in a time Deltat . Then the total quantity of electric charge Q that passes any point in the circuit during the time Deltat is represent by

A magnetic flux through a stationary loop with a resistance R varies during the time interval tau as phi=at(tau-t) . Find the amount of heat the generated in the loop during that time

The magnetic flux linked with a circuit of resistance 100 ohm increase from 10 to 60 webers. The amount of induced charge that flows in the circuit is (in coulomb)

Magnetic flux in a circuite containing a coil of resistance 2Omega change from 2.0Wb to 10 Wb in 0.2 sec . The charge passed through the coil in this time is

The magnetic flux (phi) in a closed circuit of resistance 20 Omega varies with time (t) according to the equation phi = 7t^(2) - 4t where phi is in weber and t is in seconds. The magnitude of the induced current at t =0.25s is

When some potential difference V is applied across a resistance R then the work by the electrical field on the charge q to flow through the circuit in time t will be

When a capacitor discharges through a resistance R, the time constant is tau and the maximum current in the circuit is i_0 . Then,

The time constant T for the shown circuit containing resistance and capacitor, is

A circuit consisting of a constant EMF E, a self-inductance L and a resistance R in sereis is closed at time t=0 . The relation between the current i in the circuit and the time t is as shown by the curve. A in the figure-5.321. when one or more of parameters E,R and L are changed, the curve B is obtained. Then it is possible that:

The charge flowing through a resistance R varies with time t as Q = at - bt^(2) . The total heat produced in R is