The rms value of potential difference V shown in the figure is

Two protons A and B are placed in between the two plates of a parallel plate capacitor charged to a potential difference V as shown in the figure. The forces on the two protons are identical.

The sinusoidal potential difference V shown in figure applied across a resistor R produces heat at a rate W. What is the rate of heat disspation when the squre wave potential diffrence V_(2) as shown in figure is applied across the resistor?

The potential difference between A and B as shown in figure is

The circuit shown in the figure is a series LCR circuit connected to an AC source. This circuit has many important applications in practical electronic systems. In the given circuit, L = 20 mH and frequency of applied alternating potential difference is omega = 8000 rad//s . Initial phase of applied potential difference has such a minimum value that initial value of instantaneous potential difference is half of is peak value while initial phase of current in the circuit has such a minimum value that initial value of instantaneous current equals its peak value. We also observe that current in the circuit leads the net voltage across the circuit. It is given that peak values of potential difference across R and L are I V_(R)( peak))= 25 V V(L)_(peak)= 20 V rms value of potential difference across capacitor is nearly

Find the potential difference between A and B as shown in the figure

A part of a complete circuit is shown in the figure . At some instant the value of current I is 1 A and it is decreasing at a rate of 10^2 A s^(-1) . The value of the potential difference V_P - V_Q , (in volts) at that instant , is ____________.

Calculate the value of resistance R in the circuit shown in the figure so that the current in the circuits is 0.2A . What would be the potential difference between the points B and E ?

Potential difference across AB in the network shown in figure.

A condenser of capacity 16 mF charged to a potential of 20 V is connected to a condenser of capacity C charged to a potential of 10 V as shown in the figure. If the common potential is 14 V. the capacity C is equal to