In figure two points A and B are located in a region of electric field . The potential difference `V_(B)-V_(A)` is

Consider . The potential difference V_(A)-V_(B) is.

The work done in carrying a charge of 5 mu C form a point A to a point B in an electric field is 10mJ . The potential difference (V_(B) - V_(A)) is then

Two points A and B are located in a region of space containing electric field as shown in the figure. As we move from A to B, the potentia

Potential difference V_(B)-V_(A) in the network shown is

A combination of five resistors are connected to a cell of emf 10 V as shown in figure. The potential difference V_(B) - V_(E) will be .

An infinitely long line of linear charge density lambda is shown in the figure. The potential difference V_(A)-V_(B) between the two points A and B is

Figure shown three points A, B and C in a region of unifrom electric field vecE . The line AB is perpendicular and BC is parallel to the field lines. Then which of the following holds good. Where V_(A), V_(B) and V_(C) represenet the electric potential at points A, B and C respectively

Potential difference across AB , i.e., V_(A)-V_(B) is

When the current in the portion of the circuit shown in the figure is 2A and increasing at the rate of 1A//s ,the measured potential difference V_(a)-V_(b)=8V .However when the current is 2A and decreasing at the rate of 1A//s , the measured potential difference V_(a)-V_(b)=4V .The values of R and L are:

A uniform electric field of 400 V/m is directed at 45^@ above the x-axis as shown in the figure. The potential difference V_A-V_B is given by