What resistance must be connected in series with an inductor of 5mH so that the circuit has a time constant of `2 xx 10^(-3)S` ?

A resistance R_(2) is connected in parallel with a resistance R_(1) what resistance R_(3) must be connected in series with the combination of R_(1) and R_(2) so that the equivalent resistance is equal to the resistance R_(1) -

An inductor of 2 henry and a resistance of 10 ohms are connected in series with a battery of 5 volts. The initial rate of change of current is

The time constant of a circuit is 10 sec , when a resistance of 10 Omega is connected in series in a prevouse circuit then time constant becomes 2 second, then the self inductance of the circuit is :-

A inductor of 20mH inductance and a resistor of 100 Omega resistance are connected in series to a battery of emf 10V. After a long time the circuit is short-circuited and the battery is disconnected. Find the current in the circuit 1 ms after short-circuiting.

A coil of some internal resistance 'r' behaves line an inductance. When it is connected in series with a resistance R_(1) , the time constant is found to be tau_(1) . When it is connected in series with a resistance R_(2) , the time constant is found to be tau_(2) . The inductance of the coil is

A capacitor of 10muF is connected with a resistance of 2.2 M Omega . What is the time constant of the circuit.

A 20 mH coil is connected in series with a 2 k Omega resistor and a 12 V battery. Calcualte (i) time constant of the circuit, (ii) time during which current decrys to 10% of its maximum value.

A 1 -k Omega resistor is connected in series with a 10-mH inductor, a 30 V battery and an open switch. At time t= 0 , the switch is suddenly closed. a. What is the maximum current in this circuit and when does it occur? b. What are the voltage drops across the inductor and across the resistor 20 mu s after the switch is closed? c. On a single set of axes, sketch the voltage across the resistor and the voltage across the inductor as functions of time. Also, sketch a graph of the current in the circuit as s function of time.