Taking the internal resistance of the battery as negligible, the steady state current in the 2`ohm` resistor shown in the figure will be

The steady state current in a 2 Omega resistor when the internal resistance of the battery is negligible and the capacitance of the condenser is 0.1 mu F is

In a circuit shown in figure if the internal resistance of the sources are negligible then at what value of resistance R will the thermal power generated in it be the maximum. What is its value in ohms ?

Calculate the steady state current in the 2- ohm resistor shown in the circuit in the figure. The intermal resistance of the battery is negligible and the capacitance of the condenser C is 0.2 microfarad.

An inductor of inductance L=400 mH and resistor of resistance R_(1) = 2(Omega) and R_(2) = 2 (Omega) are connected to a battery of emf E = 12 Vas shown in the figure. The internal resistance of the battery is negligible. The switch S is closed at time t =0. What is the potential drop across L as a function of time? After the steady state is reached, the switch is opened. What is the direction and the magnitude of current through R_(1) as a function of time?

An inductor of inductance L=400 mH and resistors of resistances R_1=2Omega and R_2=2Omega are connected to a battery of emf E=12 V as shown in the figure. The internal resistance of the battery is negligible. The switch S is closed at time t=0 . What is the potential dro across L s a function of time? After the steady state is reached, the switch is opened. What is the direction ad the magnitude of current throough R_1 as a function of time?

A 5V battery with internal resistance 2Omega and a 2V battery with internal resistance 1Omega are connected to a 10Omega resistor as shown in the figure. The current in the 10Omega resistor is

An inductor of inductance L=400mH and resistors of resistances R_(1)=2 Omega and R_(2)=2 Omega are connected to a battery of emf 12 V as shown in figure.The internal resistance of the battery is negligible.The switch S is closed at t=0 .The potential drop across L as a function of time is: