A piezoelectric wearable blood oxygen monitor is a device designed to measure the level of oxygen saturation in a person's blood in a non-invasive and continuous manner. It utilizes the principles of piezoelectricity and the inherent properties of oxygenated and deoxygenated blood to provide accurate readings.
Here's a breakdown of its working principle:
Piezoelectric Material: The core component of this device is a piezoelectric material, which has the unique ability to generate electric charges when subjected to mechanical stress or pressure. This material is usually a crystal or ceramic that possesses piezoelectric properties, such as quartz, lead zirconate titanate (PZT), or polyvinylidene fluoride (PVDF).
Contact with Skin: The wearable device is typically designed to be worn on a part of the body that allows it to come into contact with the skin, such as the fingertip, earlobe, or wrist. This allows the device to measure subtle changes in mechanical pressure caused by blood flow and arterial pulsations.
Blood Flow and Pressure Variation: When the blood circulates through the arteries, it generates pulsatile pressure waves. These pressure waves cause slight mechanical deformations in the underlying skin and tissue. The piezoelectric material in the wearable device responds to these mechanical deformations by generating small electric charges.
Signal Detection and Processing: The generated electric charges are detected by integrated electrodes or sensors on the surface of the piezoelectric material. These electrodes are connected to a signal processing circuit within the wearable device. The electric charges generated correspond to the mechanical pressure variations caused by the arterial pulsations, which are influenced by the heartbeat and blood flow.
Oxygen Saturation Calculation: The signal processing circuit then analyzes the frequency and amplitude of the electric charges generated by the piezoelectric material. Since oxygenated blood absorbs and scatters light differently than deoxygenated blood, the variations in blood volume associated with each heartbeat will be slightly different. This difference can be used to calculate the oxygen saturation level by comparing it with a baseline value obtained when the device is first calibrated.
Display and Communication: The calculated oxygen saturation level is typically displayed on the wearable device's screen or transmitted wirelessly to a paired device, such as a smartphone or a smartwatch. This enables the wearer to monitor their blood oxygen levels in real-time.
Calibration and Accuracy: Calibration is an essential step in ensuring accurate measurements. The device needs to be calibrated against a reference measurement, often done using a traditional pulse oximeter. This allows the wearable device to account for individual variations and provide accurate readings.
In summary, a piezoelectric wearable blood oxygen monitor operates by detecting and converting mechanical pressure variations caused by blood flow into electric charges using a piezoelectric material. These charges are then processed and used to calculate the oxygen saturation level, providing continuous and non-invasive monitoring for the wearer.