The charge flowing across the circuit on closing the key K is

Consider the circuit shown in the figure. (a) Find the current i flowing through the circuit when the key K_(1) is open and K_(2) is closed. (b) Find the net charge on the capacitor when K_(1) is open & K_(2) is.closed and also when K_(1) & K_(2) both are closed. (c) What is the change in the current'i, when K_(1) is closed

n the circuit shown in the figure, the capacitor C is charged to a potential V_(o) The heat generated and charge flow, in the circuit to when the switch S is closed, is

When some potential difference V is applied across a resistance R then the work by the electrical field on the charge q to flow through the circuit in time t will be

The charge across the capacitor in two different RC circuit 1 and 2 are potted as shown in figure. Choose the correct statement (s) related to the two circuit.

Find out the following if A is connected with C and B is connected with D. (i) How much charge flows in the circuit. (ii) How much heat is produced in the circuit.

A point charge +q is moved with a constant velocity v toward a solid conducting sphere carrying a charge Q. Find the (a) potential of th sphere, (b) charge induced as the function of r, (c ) charge flowing if we close the key K, and (d) current is the part (c ).

In the circuit shown, the key is inserted at t=0. Charge which passes in the circuit in one time constant is :

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.

A capacitor of capacitance 3muF is first charged by connecting it across a 10 V battery by closing key K_(1) . Then it is allowed to get discharged through 2 Omega and 4 Omega resistors by closing the key K_(2) . The total energy dissipated in the 4 Omega resistor is equal to

Charge flow through the battery after closing the switch is (initially all capacitors are unxharged) :