The Wheatstone Bridge

 Scientists use many skills to investigate the world around them. They make observations and gather information from their senses. Some observations are as simple as figuring out the texture and colour of an object. However, if scientists want to know more about a substance they may need to take measurements. Measurement is one of the important aspects of science. It is difficult to conduct experiments and form theories without the ability to measure.

What is Wheatstone Bridge?

Wheatstone bridge, also known as the resistance bridge, calculates the unknown resistance by balancing two legs of the bridge circuit. One leg includes the component of unknown resistance. Samuel Hunter Christie invented the Wheatstone bridge in 1833, which Sir Charles Wheatstone later popularised in 1843.

The Wheatstone Bridge Circuit comprises two known resistors, one unknown resistor and one variable resistor connected in the form of a bridge. This bridge is very reliable as it gives accurate measurements.

Construction of Wheatstone Bridge

A Wheatstone bridge circuit consists of four arms of which two arms consists of known resistances while the other two arms consist of an unknown resistance and a variable resistance. The circuit also consists of a galvanometer and an electromotive force source. The emf source is attached between points a and b while the galvanometer is connected between the points c and d. The current that flows through the galvanometer depends on the potential difference across it.

What is the Wheatstone Bridge Principle?

The Wheatstone bridge works on the principle of null deflection, i.e. the ratio of their resistances are equal and no current flows through the circuit. Under normal conditions, the bridge is in the unbalanced condition where current flows through the galvanometer. The bridge is said to be in a balanced condition when no current flows through the galvanometer. This condition can be achieved by adjusting the known resistance and variable resistance.

Wheatstone Bridge Derivation

The current enters the galvanometer and divides into two equal magnitude currents as I1 and I2. The following condition exists when the current through a galvanometer is zero,

I1P=I2R (1)

The currents in the bridge, in a balanced condition, is expressed as follows:

I1=I3=EP+Q I2=I4=ER+S

Here, E is the emf of the battery.

By substituting the value of I1 and I2 in equation (1), we get

PEP+Q=RER+S

PP+Q=RR+S

P(R+S)=R(P+Q)

PR+PS=RP+RQ

PS=RQ
(2)

R=PQ×S
(3)

Equation (2) shows the balanced condition of the bridge while (3) determines the value of the unknown resistance.

In the figure, R is the unknown resistance, and S is the standard arm of the bridge and P and Q are the ratio arm of the bridge.

Wheatstone Bridge Formula

Following is the formula used for Wheatstone bridge:

R=PSQ

Where,

• R is the unknown resistance
• S is the standard arm of the bridge
• P and Q is the ratio of arm of bridge