Abstract
Microelectromechanical systems (MEMS) resonators have allowed the development of magnetic field sensors with potential applications such as biomedicine, automotive industry, navigation systems, space satellites, telecommunications and non-destructive testing. We present a review of recent magnetic field sensors based on MEMS resonators, which operate with Lorentz force. These sensors have a compact structure, wide measurement range, low energy consumption, high sensitivity and suitable performance. The design methodology, simulation tools, damping sources, sensing techniques and future applications of magnetic field sensors are discussed. The design process is fundamental in achieving correct selection of the operation principle, sensing technique, materials, fabrication process and readout systems of the sensors. In addition, the description of the main sensing systems and challenges of the MEMS sensors are discussed. To develop the best devices, researches of their mechanical reliability, vacuum packaging, design optimization and temperature compensation circuits are needed. Future applications will require multifunctional sensors for monitoring several physical parameters (e.g., magnetic field, acceleration, angular ratio, humidity, temperature and gases).
Highlights
Microelectromechanical systems (MEMS) allow the development of devices that are composed by mechanical and electrical components with a feature size in the micrometer-scale
Total quality factor (QT) of a resonator considering different damping where Qf, Qs, and Qt are quality factors associated with the fluid damping, support damping and thermoelastic damping, respectively
MEMS magnetic field sensors can employ different sensing techniques such as capacitive, optical, where Qf, Qs, and Qt are quality factors associated with the fluid damping, support damping and or piezoresistive
Summary
Microelectromechanical systems (MEMS) allow the development of devices that are composed by mechanical and electrical components with a feature size in the micrometer-scale. Several researchers [3,4,5,6,7,8] have designed MEMS magnetic field sensors for potential applications such as biomedical, telecommunications, navigation and non-destructive testing. Most of these sensors include resonators that operate with the Lorentz force, which is generated by the interaction between an external magnetic field and an electrical current. Dominguez-Nicolás et al [4] designed a signal conditioning system, implemented in a printed circuit board (PCB), for a MEMS magnetic field sensor. MEMS sensors could commercially compete against conventional magnetic field sensors in a wide variety of applications
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