Abstract
With nine-axis sensing systems in 5G smartphones, mobile power consumption has become increasingly important, and ultra-low-power (ULP) sensor circuits can decrease power consumption to tens of microwatts. This paper presents an innovative successive approximation register analog-to-digital converter, which comprises fine (three most significant bits (MSBs) plus course conversion (11 least significant bits (LSBs)) capacitive digital-to-analog converters (CDACs), ULP, four-mode reconfigurable resolution (9, 10, 11, or 12 bits), an internally generated clock, meta-detection, the switching base midpoint voltage (Vm) (SW-B-M), bit control logic, multi-phase control logic, fine (three MSBs) plus course conversion (11 LSBs) switch control logic, phase control logic, and an input signal plus negative voltage (VI + NEG) voltage generator. Then, the mechanism of the discrete Fourier transform (DFT)-based calibration is applied. The scalable voltage technique was used, and the analog/digital voltage was Vanalog (1.5 V) and Vdigital (0.9 V) to meet the specifications of the nine-axis ULP sensing system. The CDACs can reconfigure four-mode resolutions, 9–12 bits, for use in nine-axis sensor applications. The corresponding dynamic signal-to-noise and distortion ratio performance was 50.78, 58.53, 62.42, and 66.51 dB. In the 12-bit mode, the power consumption of the ADC was approximately 2.7 μW, and the corresponding figure of merit (FoM) was approximately 30.5 fJ for each conversion step.
Highlights
A recent trend is the application of nine-axis sensing systems that merge analog radio frequency microelectromechanical systems (RF MEMSs) with 5G mobile systems
To meet the specifications of the nine-axis ultra-low-power (ULP) sensing systems, the power consumption of the analog-to-digital converter which is less than 10 uW is needed
The output voltage of a three-axis accelerometer is pulled to the successive approximation register analog-to-digital converter (SAR-analog-todigital converters (ADCs)) with a fine (three most significant bits (MSBs)) plus course conversion (11 least significant bits (LSBs)) capacitive digital-to-analog converter (CDA)
Summary
A recent trend is the application of nine-axis sensing systems that merge analog radio frequency microelectromechanical systems (RF MEMSs) with 5G mobile systems. The output voltage of a three-axis accelerometer is pulled to the successive approximation register analog-to-digital converter (SAR-ADC) with a fine (three most significant bits (MSBs)) plus course conversion (11 least significant bits (LSBs)) capacitive digital-to-analog converter (CDA). The corresponding digital ou5tpofu2t5s of the non-binary-weighted CDAC simplify use the error correction for the non-binaryweighted and converter 11 bits back to 9 bits, the digital outputs are DO1~DO9. The analog block contains the bootstrap switch, two-stage comparator, SW-W-NEG (negative) and level shifter with NEG, the generator of the VI + NEG voltage, and the fine (three MSBs) plus course conversion (11 LSBs) CDAC. Fine Conversion Capacitive Digital-to-Analog Converter Control Logic, Reconfigurable Resolution (RR) Control Logic, Switch with NEG (SW-W-NEG), and the Input Signal Plus the Negative Voltage (VI + NEG) Voltage Generator. The binary (3 bits)-to-thermometer (7 bits) decoder logic expression is as follows
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