A basic resistive pressure sensor, often referred to as a resistive pressure transducer or sensor, is a device designed to measure the pressure of a fluid (liquid or gas) by utilizing changes in electrical resistance. The fundamental principle behind its operation is that the electrical resistance of certain materials changes in response to applied mechanical pressure or stress.
Here's how a basic resistive pressure sensor works:
Sensing Element: The sensor contains a sensing element made of a material that exhibits piezoresistive properties. Piezoresistive materials are those that change their electrical resistance when subjected to mechanical stress or pressure. Common materials used for this purpose include silicon, silicon carbide, and some metals.
Wheatstone Bridge Configuration: The piezoresistive sensing element is typically arranged in a Wheatstone bridge configuration. A Wheatstone bridge is a circuit arrangement of four resistors, where the piezoresistive element forms one of the arms of the bridge. The other three arms consist of fixed resistors.
Applied Pressure: When pressure is applied to the sensing element due to the presence of the fluid, it undergoes mechanical deformation. This deformation causes a change in its electrical resistance.
Resistance Change: As the resistance of the piezoresistive element changes, it leads to an imbalance in the Wheatstone bridge circuit. This imbalance results in a voltage output across the bridge, which is proportional to the applied pressure.
Signal Processing: The voltage output is then measured and amplified using signal conditioning circuitry. This conditioned output can be converted to digital signals for further processing and display.
Pressure Measurement: By calibrating the sensor's response and correlating it with known pressure values, the sensor can provide an accurate measurement of the applied pressure. The calibration process involves determining the relationship between the resistance change and the pressure change.
Basic resistive pressure sensors are widely used in various industries and applications, such as automotive, industrial automation, medical devices, and consumer electronics. They are known for their simplicity, reliability, and cost-effectiveness. However, they might have limitations in terms of accuracy, temperature sensitivity, and linearity compared to more advanced pressure sensing technologies like capacitive, piezoelectric, or MEMS-based sensors.