According to Kirchhoff's law, the algebraic sum of products of current and resistance as well as e.m.f.s in a closed loop is

According to the Kirchhoff's laws in an electric circuit, the algebraic sum of current at any junction is

In accordance with Kirchhoff’s law. Which of the following is incorrect :

What determines the conventional direction of the product of current and resistance while applying the Kirchhoff's law ?

In Fig. there is a conducting loop ABCDEF of resistance lambda per unit length placed near a long straight current-carrying wire. The dimension are shows in the figure. The long wire lies in the plane of the loop. The current in the long wire varies as I = I_(0)(t) . The emf induced in the closed loop is

Find currents in different branches of th electric circuit shown in figure. How to Proceed : In this problem there are three wires EFAB, BE and BCDE . Therefore, we have three unknown currents i_1, i_2 and i_3 . So, we require three equations. One equation will be obtained by applying Kirchhoff's junction law (either at B or at E ) and the remainig two equations, we get from te second law (loop law). We can make three loops ABEFA, ACDF and BCDEB . But we have to chose any two of them. Initilly, we can choose any arbitrary directions of i_1, i_2 and i_3 .

A stationary circular loop of radius a is located in a magnetic field which varies with time from t = 0 to t = T according to law B = B_(0) t(T - t) . If plane of loop is normal to the direction of field and resistance of the loop is R, calculate amount of heat generated in the loop during this interval.

Kirchhoffs voltage law and current law are respectively in accordance with the conservation of

According to Ampère's circuital law, the circulation of magnetic field in a closed curve is equal to ........ Times the total current enclosed within the closed curve.

An alternating e.m.f. E=10sqrt(2) sin omega volt is applied to a circuit containing a pure inductance L and a resistance and voltage acros the resistance is 6 v between the current and potential difference in this circuit is