Feifei Zhang scite author profile

This article proposes a power-efficient highly linear capacitor-array-based digital-to-time converter (DTC) using a charge redistribution constant-slope approach. A fringecapacitor-based digital-to-analog converter (C-DAC) array is used to regulate the starting supply voltage of the constant discharging slope fed to a fixed-threshold comparator. The DTC operation mechanism is analyzed and design tradeoffs are investigated. The proposed DTC consumes merely 31 µW from a 1-V supply when clocked at 40 MHz, while achieving a fine resolution of 148 fs over a 9-bit range. The measured differential nonlinearity (DNL) and integral nonlinearity (INL) are 0.96/1.07 LSB.

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A 15-μW, 103-fs step, 5-bit capacitor-DAC-based constant-slope digital-to-time converter in 28nm CMOS

Chen

Zhang

Zong

et al. 2017

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An Active-Under-Coil RFDAC With Analog Linear Interpolation in 28-nm CMOS

Zhang¹,

Chen

Walling³

et al. 2021

IEEE Trans. Circuits Syst. I

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A Feedforward and Feedback Constant-Slope Digital-to-Time Converter in 28nm CMOS Achieving ≤ 0.12% INL/Range over >100mV Supply Range

Chen

Zhang

et al. 2021

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Mismatch Analysis of DTCs With an Improved BIST-TDC in 28-nm CMOS

Chen

Yin

Zhang

et al. 2022

IEEE Trans. Circuits Syst. I

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Nonlinearity of a digital-to-time converter (DTC) is pivotal to spur performance in DTC-based all-digital phaselocked-loops (ADPLL). In this paper, we characterize and analyze the mismatch of cascaded-delay-unit DTCs. Through an improved built-in-self-test (BIST) time-to-digital converter (TDC) assisted with phase-to-frequency detector (PFD), a measurement system of sub-half-ps accuracy is constructed to conduct the characterization. Fabricated in 28-nm CMOS, the DTC transfer functions are measured, and mismatches are compared against Monte-Carlo simulation results. The integral nonlinearity (INL) results are compared against each other and converted to the in-band fractional spur level when the DTC would be deployed in the ADPLL. The BIST-TDC system thus characterizes the on-chip delays without expensive equipment or complex setup. The effectiveness of adding a PFD into the loop is validated. The entire BIST system consumes 0.6 mW with a system self-calibration algorithm to tackle the analog blocks' nonlinearities.

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Feifei Zhang

A 31-$\mu$ W, 148-fs Step, 9-bit Capacitor-DAC-Based Constant-Slope Digital-to-Time Converter in 28-nm CMOS

A 15-μW, 103-fs step, 5-bit capacitor-DAC-based constant-slope digital-to-time converter in 28nm CMOS

An Active-Under-Coil RFDAC With Analog Linear Interpolation in 28-nm CMOS

A Feedforward and Feedback Constant-Slope Digital-to-Time Converter in 28nm CMOS Achieving ≤ 0.12% INL/Range over >100mV Supply Range

Mismatch Analysis of DTCs With an Improved BIST-TDC in 28-nm CMOS

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