All-digital TAD-OFDM detection for sensor interface using TAD-digital synchronous detection

Watanabe, Toshio; Terasawa, Tomohito

doi:10.1109/icecs.2010.5724630

Cited by 6 publications

(4 citation statements)

References 18 publications

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“…Thus, the all-digital MEMS tuning-fork self-excited vibration control method can replace conventional analog vibration-control methods unsuitable for very scaling with lower-supply voltage. Finally, we confirmed angular-rate measured sensitivity of 0.14(º/s)/LSB and noise peaks of approximately ±0.18º/s at BW = 10Hz using the TAD-DSD method [8].…”

Section: Tad-adpll Construction and Operationsupporting

confidence: 52%

“…Figure 9 shows measured jitter levels of (a) Pdr-pulse-train, (b) Pmo-pulse-train and (c) phase-difference between Pmo and Pdr with measured σ = 21.6ns, 52.6ns and 69.7ns, respectively. These jitter levels are small enough compared with MEMS element resonance periods (37µs, for example) for achieving TAD-DSD methods [8]. Thus, the all-digital MEMS tuning-fork self-excited vibration control method can replace conventional analog vibration-control methods unsuitable for very scaling with lower-supply voltage.…”

Section: Tad-adpll Construction and Operationmentioning

confidence: 99%

“…The latter will be presented in the near future. Incidentally, for achieving angular-rate signal detection with all-digital synchronous detection using timedomain processing, we can use TAD-digital synchronous detection (TAD-DSD) presented in [8].…”

Section: Introductionmentioning

confidence: 99%

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All-digital MEMS tuning-fork self-excited vibration control by phase-relation using TAD-based ADPLL

Yamauchi

Watanabe

2015

2015 IEEE 13th International New Circuits and Systems Conference (NEWCAS)

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For achieving an all-digital resonant MEMS gyroscope, this paper presents an all-digital MEMS tuning-fork self-excited vibration control method, using TAD (Time-A/D converter)-based all-digital PLL (TAD-ADPLL) by applying a unique control algorithm based on entirely time-domain processing, which uses no conventional analog method such as automatic gain control (AGC) or automatic level control (ALC). The proposed algorithm involves three-step processing: 1) driving a tuning-fork using the ADPLL for searching its selfresonant frequency, 2) comparing the phase difference between drive-pulse signal and monitor-pulse signal, which should be 90º (π/2-radian) each other, and 3) keeping 90º-relationship between them even with any drift factors such as temperature, supply voltage, etc. In this method, TAD-type TDC (time-to-digital converter) digitizes the resonant frequency and phase difference alternately in order to realize self-excited vibration condition along with TAD-type DCO (digitally-controlled oscillator) without the need for any analog circuit method. By using a conventional piezoelectric MEMS tuning-fork element, we experimentally confirmed its self-excited vibration, resulting in its resonance jitter level of σ = 52.6ns at 37µs-self-resonance period. Finally, we propose an all-digital synchronous detection of angular-rate signal for achieving a digital-type gyro sensor.

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Section: Tad-adpll Construction and Operationsupporting

confidence: 52%

Section: Tad-adpll Construction and Operationmentioning

confidence: 99%

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All-digital MEMS tuning-fork self-excited vibration control by phase-relation using TAD-based ADPLL

Yamauchi

Watanabe

2015

2015 IEEE 13th International New Circuits and Systems Conference (NEWCAS)

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“…Therefore, it is necessary to design and realize decoupling control of the dual-axis angular rate gyroscope that aims to achieve tactical-grade level or better performance. Currently, most of the reported results focus on microfabrication and device optimization [17,20,23], capacitive position sensing [24,25,26] and suspension control [18,27,28], rotor spin-up [21,28,29], design of the gyro rebalance loop [21,30] and error analysis of the gyro [31]. Little work has been reported on the cross-axis coupling effect, nor the decoupling control of the micromachined spinning rotor gyroscopes with electrostatic suspension.…”

Section: Introductionmentioning

confidence: 99%

Decoupling Control of Micromachined Spinning-Rotor Gyroscope with Electrostatic Suspension

Sun

Wang

et al. 2016

Sensors

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A micromachined gyroscope in which a high-speed spinning rotor is suspended electrostatically in a vacuum cavity usually functions as a dual-axis angular rate sensor. An inherent coupling error between the two sensing axes exists owing to the angular motion of the spinning rotor being controlled by a torque-rebalance loop. In this paper, a decoupling compensation method is proposed and investigated experimentally based on an electrostatically suspended micromachined gyroscope. In order to eliminate the negative spring effect inherent in the gyroscope dynamics, a stiffness compensation scheme was utilized in design of the decoupled rebalance loop to ensure loop stability and increase suspension stiffness. The experimental results show an overall stiffness increase of 30.3% after compensation. A decoupling method comprised of inner- and outer-loop decoupling compensators is proposed to minimize the cross-axis coupling error. The inner-loop decoupling compensator aims to attenuate the angular position coupling. The experimental frequency response shows a position coupling attenuation by 14.36 dB at 1 Hz. Moreover, the cross-axis coupling between the two angular rate output signals can be attenuated theoretically from −56.2 dB down to −102 dB by further appending the outer-loop decoupling compensator. The proposed dual-loop decoupling compensation algorithm could be applied to other dual-axis spinning-rotor gyroscopes with various suspension solutions.

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All-digital A/D converter TAD with high-resolution and low-power for sensor/RF digitization

Watanabe

Terasawa

2013

Analog Integr Circ Sig Process

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All-digital TAD-OFDM detection for sensor interface using TAD-digital synchronous detection

Cited by 6 publications

References 18 publications

All-digital MEMS tuning-fork self-excited vibration control by phase-relation using TAD-based ADPLL

All-digital MEMS tuning-fork self-excited vibration control by phase-relation using TAD-based ADPLL

Decoupling Control of Micromachined Spinning-Rotor Gyroscope with Electrostatic Suspension

All-digital A/D converter TAD with high-resolution and low-power for sensor/RF digitization

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