IEEE Trans. Circuits Syst. I
 2018
DOI: 10.1109/tcsi.2018.2857999
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An On-Chip Self-Characterization of a Digital-to-Time Converter by Embedding it in a First-Order <inline-formula> <tex-math notation="LaTeX">$\Delta\Sigma$ </tex-math> </inline-formula> Loop

Peng Chen
1
,
Xiongchuan Huang
2
,
Yue Chen
3
et al.

Abstract: To characterize an on-chip programmable delay in a low-cost and high-resolution manner, a built-in self-test based on a first-order time-to-digital converter with self-calibration is proposed and implemented in TSMC 28-nm CMOS. The system is self-contained, and only one digital clock is needed for the measurements. A system self-calibration algorithm is proposed to calibrate nonlinearities of the analog circuitry. The operation is robust over PVT variations since the delay information is normalized to the inpu… Show more

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An IR-UWB CMOS Transceiver for High-Data-Rate, Low-Power, and Short-Range Communication

Lee
1
,
Park
2
,
Jang
3
et al. 2019
IEEE J. Solid-State Circuits
41
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18
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An IR-UWB CMOS Transceiver for High-Data-Rate, Low-Power, and Short-Range Communication

Lee
1
,
Park
2
,
Jang
3
et al. 2019
IEEE J. Solid-State Circuits
41
0
18
0
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A 31-$\mu$ W, 148-fs Step, 9-bit Capacitor-DAC-Based Constant-Slope Digital-to-Time Converter in 28-nm CMOS

Chen
1
,
Zhang
2
,
Zong
3
et al. 2019
IEEE J. Solid-State Circuits
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A Power-Efficient Fractional-N DPLL With Phase Error Quantized in Fully Differential-Voltage Domain

Wu
1
,
Burger
2
,
Schonle
3
et al. 2021
IEEE J. Solid-State Circuits
11
0
7
0
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