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`

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 figure-3.103. the resistances are equal to R_(1)=10Omega,R_(2)=20Omega and R_(3)=30Omega and the potentials of points 1,2 and 3 are given as V_(1)=10V,V_(2)=6V and V_(3)=5V .

Find the currents in the Y connection of 3 resistances R_(1) = 10Omega , R_(2)=20Omega and R_(3)= 30 Omega . When the terminals of R_(1) , R_(3) and R_(3) are maintained at potentials V_(1) = 10V, V_(2) =6V and V_(3) = 15V.

Find the magnitude and direction of the current flowing through the resistance R in the circuit shown in Fig. if the emf's of the sources are equal to E_(1) = 1.5 V and E_(2) = 3.7 V and the resistances are equal to R_(1) = 10 Omega, R_(2) = 20 Omega , R = 5.0 Omega . The internal resistances of the sources are neglible.

In the given circuit, R_(1) = 10Omega R_(2) = 6Omega and E = 10V, then correct statement is

In the given circuit, R_(1) = 10Omega R_(2) = 6Omega and E = 10V, then correct statement is

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 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

Calculate : total resistance and R_1 = 3 Omega , R_2= 6 Omega , R_3 = 5Omega, V = 14 V.