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

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 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 charge passing through a resistor varies with time as shown in the figure. The amount of heat generated in time t is best represented (as a function of time ) by

The charge q flowing in a conductor of uniform cross section, varies with time as q=alphat-bt^(2) . Then, the current

The charge flowing in a conductor varies with time as Q= at -(1)/(2)bt^(2)+(1)/(6)ct^(3) where a, b and c are positive constants. If at time t, the current in the conductor is i, which of the following graphs is correct ?

The linear momentum of a particle varies with time t as p= a +bt + ct^(2) . Then, whichh of the following is correct?

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

In the current shows Fig x is joined to Y for a long time and then X is joined to Z . The total heat produced in R_(2) is