The charge Q( in coulomb) flowing through a resistance `R=10Omega` varies with time t (in second) as `Q=2t-t^2` . The total heat produced in resistance R is

The charger Q(in coulomb) flowing through a resistance (R = 10Omega) varies with time t(in second) as (Q= 2t- t overset2 ). The total heat produced in resistance R is

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

In the circuit, the current flowing through 10Omega resistance is

When a current I flows through a resistance R for time t, the electrical energy spent is :

Flux phi (in weber) in a closed circuit of resistance 5 omega varies with time (in second) according to equation phi=3t^2-5t+2 . The magnitude of average induced current between 0 to 2s 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

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 charge flowing in a conductor varies with times as Q = at - bt^2. Then, the current

The charge flowing in a conductor varies with times as Q = at - bt^2. Then, the current

A cell sends a current through a resistance R_(1) for time t , next the same cell sends current through another resistance R_(2) for the time t If the same amount of heat is developed in both the resistance then find the internal resistance of the cell