A piezoelectric sensor is a crucial component in ultrasonic imaging systems. It plays a vital role in both emitting and receiving ultrasonic waves. Ultrasonic imaging uses high-frequency sound waves (ultrasound) to create images of internal structures within the body or other objects. Here's how a piezoelectric sensor works in ultrasonic imaging:
Piezoelectric Effect: Piezoelectric materials have a unique property known as the piezoelectric effect. When these materials are subjected to mechanical stress (such as compression or tension), they generate an electrical charge across their surfaces. Conversely, when an electrical voltage is applied to these materials, they undergo mechanical deformation or vibration.
Transducer Operation - Transmitting: In ultrasonic imaging, a piezoelectric transducer acts as both a transmitter and a receiver. When it functions as a transmitter, an electrical voltage is applied to the piezoelectric element within the transducer. This causes the piezoelectric material to vibrate rapidly, generating ultrasonic waves in the frequency range of 1 to 20 MHz (or even higher). The frequency of the ultrasonic wave determines the resolution and penetration depth of the imaging.
Ultrasound Propagation: The ultrasonic waves generated by the vibrating piezoelectric element propagate into the object or body being imaged. As these waves encounter interfaces between different tissues or structures with varying acoustic properties (e.g., density or elasticity), some of the energy gets reflected back towards the transducer.
Transducer Operation - Receiving: When the same piezoelectric transducer functions as a receiver, the reflected ultrasonic waves strike the piezoelectric element. The mechanical stress caused by the incoming waves results in the generation of an electrical signal. This signal is proportional to the amplitude and frequency of the received ultrasound waves.
Signal Processing: The electrical signal generated by the piezoelectric sensor is extremely weak and needs to be amplified and processed. Ultrasonic imaging systems include sophisticated electronics to amplify, filter, and digitize the received signals.
Image Reconstruction: The processed signals are used to create an image representation of the internal structures. By knowing the time it takes for the ultrasonic waves to travel to and from different interfaces, the system can calculate the distance and intensity of the reflections. These data points are then used to construct a 2D or 3D image of the imaged object.
Overall, the piezoelectric sensor's ability to convert mechanical vibrations (ultrasound) into electrical signals and vice versa is fundamental to the functioning of ultrasonic imaging systems, enabling non-invasive visualization of internal structures in medical, industrial, and other applications.