A Sub-400-nT/<inline-formula> <tex-math notation="LaTeX">$\sqrt {\text {Hz}}$ </tex-math></inline-formula>, 775-<inline-formula> <tex-math notation="LaTeX">$\mu \text{W}$ </tex-math></inline-formula>, Multi-Loop MEMS Magnetometer With Integrated Readout Electronics

Abstract: This paper presents a novel z-axis Lorentz force magnetometer coupled with a low-power readout integrated circuit. The sensor is fabricated using an industrial process, and exploits an Al-on-polysilicon multi-loop architecture that gives a five-fold sensitivity and resolution improvement, useful for off-resonance operation. The integrated readout is based on a differential charge amplifier front-end, and designed to be balanced with the sensor in terms of noise and power consumption. The overall system, includ… Show more

“…Another solution has been first proposed by Langfelder et al consisting in off-resonance operation of the device [82][83][84][85][86]. This off-resonance operation consists in driving the sensor current at a frequency below the device mechanical resonance.…”

“…Second, some AM works do not require, due to their characteristics, a closed loop so they can operate in open loop. These are the works driving the sensor in off-resonance [44,82,84,85]: given that a frequency tracking is not a must, electronics can be simplified. Here it is worth to mention a few works.…”

“…In [44], off-resonance is used in order to implement bias chopping with the objective of reducing the sensor offset. In [84] the frequency reference is generated with an off-chip resonator that feeds the on-chip current driving stage. Similarly, an integrated resonator is used in [85] as the reference of a single Howland current source for three different sensors, each of them having its own integrated amplifier.…”

“…This solution has been used as a proof-of-concept of the modulation strategies proposed, but it requires bulky commercial devices that can not be integrated on a chip. In [84] a Pierce oscillator coupled to an off-chip Tang resonator has been used to track the resonance frequency. This solution requires off-chip components and does not provide resonance frequency tracking with temperature variations.…”

“…When magnetic field is amplitude modulated, though, electrostatic driving feedthrough introduces an important amount of offset that must be removed [44,79]. In order to avoid this offset, some works do not drive the MEMS electrostatically and track frequency with on-and off-chip oscillators [84,85], but requiring extra area consumption and design time. In [79], current chopping is proposed to get rid of this offset, but magnetic field requires an extra modulation step, which increases power consumption.…”

High performance readout circuits and devices for Lorentz force resonant CMOS-MEMS magnetic sensors

“…Another solution has been first proposed by Langfelder et al consisting in off-resonance operation of the device [82][83][84][85][86]. This off-resonance operation consists in driving the sensor current at a frequency below the device mechanical resonance.…”

“…Second, some AM works do not require, due to their characteristics, a closed loop so they can operate in open loop. These are the works driving the sensor in off-resonance [44,82,84,85]: given that a frequency tracking is not a must, electronics can be simplified. Here it is worth to mention a few works.…”

“…In [44], off-resonance is used in order to implement bias chopping with the objective of reducing the sensor offset. In [84] the frequency reference is generated with an off-chip resonator that feeds the on-chip current driving stage. Similarly, an integrated resonator is used in [85] as the reference of a single Howland current source for three different sensors, each of them having its own integrated amplifier.…”

“…This solution has been used as a proof-of-concept of the modulation strategies proposed, but it requires bulky commercial devices that can not be integrated on a chip. In [84] a Pierce oscillator coupled to an off-chip Tang resonator has been used to track the resonance frequency. This solution requires off-chip components and does not provide resonance frequency tracking with temperature variations.…”

“…When magnetic field is amplitude modulated, though, electrostatic driving feedthrough introduces an important amount of offset that must be removed [44,79]. In order to avoid this offset, some works do not drive the MEMS electrostatically and track frequency with on-and off-chip oscillators [84,85], but requiring extra area consumption and design time. In [79], current chopping is proposed to get rid of this offset, but magnetic field requires an extra modulation step, which increases power consumption.…”

High performance readout circuits and devices for Lorentz force resonant CMOS-MEMS magnetic sensors

Electrical and Physical Sensors for Biomedical Implants

Portable signal conditioning system of a MEMS magnetic field sensor for industrial applications