In the circuit shown in figure

Current through `R_(2)` is zero if `R_(4) = 2 Omega` and `R_(3) = 4 Omega` In this case

Consider the circuit shown in fig. Current through R_2 is zero if R_4 = 2Omega and R_3 = 4 Omega in this case

Find the current flowing through the resistance R_(1) of the circuit shown in figure if the resistances are equal to R_(1) = 10Omega, R_(2) = 20 Omega and R_(3), = 30 Omega and the potentials of the points 1, 2, and 3 are equal to varphi_(1) = 10 V, varphi_(2) = 6 V and varphi_(3) = 5 V

Find the current flowing through the resistance R_(1) of the circuit shown in Fig. If the resistances are equal to R_(1) = 10 Omega. R_(2) = 20 Omega and R_(3) = 30 Omega , and the potential of points 1,2 and 3 are equal to varphi_(1) = 10 V, varphi_(2) = 6V , and varphi_(3) = 5 V

In the circuit shown in the figure R_(1) =3 Omega,R_(2) = 2 Omega and R_(3) = 5 Omega Emf of the cell epsilon = 6 Volt. (a) Infinitely many 1 Omega resistors are added in parallel to R_(1) and R_(2) . Find current through R_(2) and potential drop across it. (b) Infinitely many 1 Omega resistors are added in series to R_(3) . Find the potential drop across R_(3) and current through it.

In the circuit shown in figure For what ratio (R_(2))/(R_(4)) , current through R_(3) will be zero

In the circuit shown below E_(1) = 4.0 V, R_(1) = 2 Omega, E_(2) = 6.0 V, R_(2) = 4 Omega and R_(3) = 2 Omega . The current I_(1) is

In the curcuit shown in figure R_1=R_2=R_3=10Omega . Find the currents through R_1 and R_2

For the circuit shown in the figure, the current in the 4 Omega resistor is