A pyroelectric sensor is a type of thermal sensor that can detect changes in infrared radiation. It operates based on the pyroelectric effect, which is the ability of certain materials to generate an electric charge when exposed to a change in temperature. This effect is most prominent in certain crystalline materials like triglycine sulfate (TGS), lithium tantalate (LiTaO3), and others.
Here's how a pyroelectric sensor detects infrared radiation:
Material Selection: The sensor is typically made of a pyroelectric material. When this material is at a stable temperature, it exhibits a balanced distribution of positive and negative charges within its crystal lattice.
Infrared Radiation Detection: When infrared radiation (IR) is incident on the surface of the pyroelectric sensor, it causes a change in temperature. IR radiation is a form of electromagnetic radiation with longer wavelengths than visible light, and it carries thermal energy.
Charge Separation: As the temperature changes due to the absorbed infrared radiation, the crystal lattice of the pyroelectric material becomes asymmetric, leading to a separation of positive and negative charges within the material.
Electric Signal Generation: The separated charges generate an electric potential across the sensor's electrodes, proportional to the rate of change of temperature (i.e., the rate of change of IR radiation). This results in a temporary voltage across the sensor.
Signal Amplification and Processing: The temporary voltage generated by the pyroelectric sensor is usually very small, so it needs to be amplified and processed. The sensor is connected to an electronic circuit that amplifies the signal and converts it into a measurable output.
Output and Detection: The amplified signal is then interpreted by the electronic circuit, which can be used to trigger various applications. For example, in passive infrared (PIR) motion sensors commonly used in security systems or automatic lighting, the change in IR radiation caused by movement is detected by the pyroelectric sensor, and this triggers the system to take appropriate action, such as turning on lights or sounding an alarm.
It's worth noting that pyroelectric sensors are different from bolometers, which are another type of infrared radiation sensor. Bolometers work based on a different principle of detecting the change in resistance of a material when exposed to IR radiation, whereas pyroelectric sensors are based on the generation of an electric charge.