A basic resistive pressure sensor, also known as a piezoresistive pressure sensor, is a type of sensor designed to measure pressure by utilizing the principle of piezoresistivity. Piezoresistivity refers to the change in electrical resistance of a material when it is subjected to mechanical strain or pressure. These sensors are commonly used to convert a mechanical force (in this case, pressure) into an electrical signal that can be easily measured and interpreted.
The basic operation of a resistive pressure sensor involves the following key components and steps:
Pressure-Sensitive Element: The core of the sensor is a pressure-sensitive element, often made of a semiconductor material, such as silicon. This material has piezoresistive properties, meaning its electrical resistance changes when subjected to mechanical deformation, such as pressure.
Wheatstone Bridge Circuit: The pressure-sensitive element is integrated into a Wheatstone bridge circuit. A Wheatstone bridge is a network of resistors connected in a specific arrangement that enables measurement of changes in resistance with high sensitivity. The pressure-sensitive element's resistance is part of this bridge.
Voltage Excitation: The Wheatstone bridge circuit is supplied with a known voltage (excitation voltage). As pressure is applied to the sensor, the piezoresistive material in the pressure-sensitive element undergoes deformation, causing a change in its resistance.
Output Signal: The change in resistance of the pressure-sensitive element leads to an imbalance in the Wheatstone bridge circuit. This imbalance results in a differential voltage output across the bridge's output terminals. This voltage output is proportional to the applied pressure and can be measured using appropriate electronics.
Signal Processing: The differential voltage output is then amplified and conditioned using signal processing circuitry. This might involve amplification, filtering, and analog-to-digital conversion to make the signal suitable for further processing or display.
Pressure Measurement: By calibrating the sensor using known pressures and their corresponding voltage outputs, a linear relationship between pressure and voltage can be established. This calibration enables the sensor to accurately measure the applied pressure and convert it into an electrical signal.
Resistive pressure sensors are widely used in various applications, such as automotive systems (engine control, tire pressure monitoring), industrial equipment, medical devices (blood pressure monitors), consumer electronics (smartphones, wearables), and environmental monitoring, among others. Their simplicity, reliability, and relatively low cost make them a popular choice for pressure measurement in many scenarios.