Calculate ratio of `i_(1)` and `(i_(2)+i_(3))`

Consider the circuit shown in fig. If the switch is closed at t =0, then calculate the values of I, I_(1) and I_(2) at a. t =0 , b. = oo

Apply Kirchoff’s Laws to calculate the currents I_(1) and I_(2) in the circuit shown in Figure below:

In the given circuit find the ratio of i_(1) "to" i_(2) . Where is the initial (at t=0) current, and i_(2) is steady state (at t=oo) current the battery

Two parallel, long wires carry current i_(1) and i_(2) with i_(1)gti_(2) . When the currents are in the same direction, the magnetic field at a point midway between the wires is 30 muT . If the direction of i_(1) is reversed , the field becomes 90muT . The ratio i_(1)//i_(2) is

In the circuit shown in figure below, E_(1) and E_(2) are batteries having emfs 4.0 V and 3.5 V respectively and internal resistance 1Omega and 2Omega respectively. Using Kirchhoff.s laws, calculate currents : I_(1),I_(2) and I_(3) .

Two parallel long wire carry currents i_(1) and i_(2) with i_(1) gt i_(2) . When the currents are in the same direction , the magnetic field midway between the wires is 10 muT . When the direction of i_(2) is reversed, it becomes 40 muT . The ratio i_(1)//i_(2) is

Two parallel wires carrying equal currents i_(1) and i_(2) with i_(1)gti_(2) . When the current are in the same direction, the 10 mT . If the direction of i_(2) is reversed, the field becomes 30 mT . The ratio i_(1)//i_(2) is

Two long parallel wires carry currents i_(1) and i_(2) such that i_(1) gt i_(2) . When the currents are in the same direction, the magnetic field at a point midway between the wires is 6xx10^(-6)T . If the direction of i_(2) is reversed, the field becomes 3xx10^(-5)T . The ratio (i_(1))/(i_(2)) is

Calculate the values of currents · I_(1)I_(2)I_(3) and I_(4) Is and loin the section of networks shown in the figure

In the circuit shown, switch Sis closed att=O. Let i_(1) and i_(2) be the current at any finite time I, then the ratio i_(1)//i_(2) is