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A novel calibration technique and its all-digital implementation for the open-loop delay line is presented. Fully autonomous approach iteratively compares each digitally-controlled delay stage of the line with an on-chip reference delay, correspondingly tuning selected stage and memorizing associated settings. After correcting all individual stages, the total delay of the line is compared with the...
This paper proposes a new type of delay line locking mechanism with digitally controlled charge transfer. Delay-locked loop (DLL) based on the presented method features multi-phase outputs and is stepwise driven towards lock by a co-action of 1-bit Time-to-Digital Converters and revised charge-pump. On-chip pulse “slicing” arrangement provides high-rate clock for the Digital Signal Processing algorithm,...
This paper presents a 0.4 to 2.1 GHz open-loop fractional-N multiplying delay-locked loop based frequency synthesizer in 65 nm CMOS. The proposed frequency synthesizer architecture is based on Digital Period Synthesis that features wide frequency range, fine frequency resolution, instantaneous frequency switching and is capable to provide several independent outputs. An inherent challenge of fractional-N...
This paper describes an all-digital phase-locked loop based clock generator for a MIPI M-PHY serial link transmitter. The paper focuses on ADPLL phase accumulator speed optimization, PVT calibration, loop type changing criteria and power saving in phase digitization process. The experimental circuit is implemented in 40 nm CMOS and generates the MIPI M-PHY defined frequencies from 1.2 GHz to 5.8 GHz.
A scalable low-voltage signaling (SLVS) serial link transmitter for MIPI M-PHY is presented in this paper. It delivers 200–400 mV pp signals at date rates of 1.25–5.8 Gbps. The integrated circuit entity consists of the actual SLVS driver, an ADPLL-based clock synthesizer with a frequency multiplier, and an internal test signal generator with pseudo-random binary sequences. The circuit has been fabricated...
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