Wheatstone Bridge Calculator
Instantly calculate the unknown resistance in a balanced Wheatstone bridge. Input three known values to find the fourth. The circuit diagram updates in real-time to reflect the bridge’s state.
Calculator Inputs
Calculated Unknown Resistance (Rx):
-- Ω
The Principle of the Wheatstone Bridge
A Wheatstone bridge is an electrical circuit used to measure an unknown electrical resistance by balancing two legs of a bridge circuit, one leg of which includes the unknown component.
The key principle is the concept of 'null deflection'. When the bridge is "balanced," the voltage difference between the middle points of the two parallel branches is zero. This means no current flows through the galvanometer. At this point, the ratio of resistances in the first branch is equal to the ratio of resistances in the second branch.
R1 / Rx = R2 / R3
By rearranging this formula, we can easily solve for the unknown resistance, typically denoted as Rx:
Rx = R1 * (R3 / R2)
Real-World Applications
The Wheatstone bridge's ability to detect minute changes in resistance makes it invaluable in many sensor applications.
Temperature Sensing
Used with thermistors (whose resistance changes with temperature) to create precise digital thermometers and thermostat controls.
Strain Gauges
Measures stress and strain on objects like building supports or aircraft wings. The mechanical deformation changes the gauge's resistance, which the bridge detects.
Light Detection
Paired with Light Dependent Resistors (LDRs) to create light meters or automatic street lighting systems that activate when ambient light falls below a certain level.
Humidity & Pressure Sensors
Many modern pressure and humidity sensors rely on materials whose resistance changes with environmental conditions, measured precisely by a Wheatstone bridge.
Anemometers (Air Flow)
Hot-wire anemometers use a heated element whose resistance changes as air flows past it, causing cooling. The bridge circuit converts this change into an air speed reading.
Resistivity Measurement
In materials science, it's used to accurately measure the resistivity of samples, helping to characterize new materials or check for impurities in conductors.
Frequently Asked Questions
What is the condition for a balanced Wheatstone bridge?
The bridge is balanced when the potential difference between points connecting the galvanometer is zero, meaning no current flows through it. This occurs when the ratio of resistances in one branch is equal to the ratio in the other: R1/Rx = R2/R3.
Why is it called a 'bridge'?
The circuit diagram shows the galvanometer "bridging" the gap between the two parallel voltage divider branches. This central connection is the key to comparing the voltages between the two branches.
What are the limitations of a Wheatstone bridge?
It is less accurate for measuring very low or very high resistances. For very low resistances, contact and lead resistance can cause significant errors. For very high resistances, leakage currents can affect accuracy. Also, the sensitivity is dependent on the galvanometer and the voltage source.
Who invented the Wheatstone bridge?
It was invented by Samuel Hunter Christie in 1833, but it was improved and popularized by Sir Charles Wheatstone in 1843, which is why it bears his name.
