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A 12.5-GHz Fractional-N Type-I Sampling PLL Achieving 58-fs Integrated Jitter

Mario Mercandelli, Alessio Santiccioli, Angelo Parisi, Luca Bertulessi, Dmytro Cherniak, Andrea L. Lacaita, Carlo Samori, Salvatore Levantino

2021IEEE Journal of Solid-State Circuits62 citationsDOI

Abstract

This article presents a fractional-N sampling type-I phase-locked loop (PLL). To overcome the impairments of a conventional type-I PLL, namely the frequency-tuning-dependent time offset and the narrow range of the sampling phase detector (SPD), which would prevent fractional-N synthesis, a novel digital phase error correction (DPEC) technique, operating in the background, is introduced, which provides robust low-jitter performance. Besides, a novel frequency locking method is presented, which provides fast lock and seamless hand-off to main PLL operation. The PLL has been fabricated in a 28-nm CMOS technology process, and it synthesizes frequencies from 11.9 to 14.1 GHz, achieving an rms jitter of 58.2 and 51.7 fs (integrated into the 1 kHz-100 MHz bandwidth) for a fractional-N and integer-N channel, respectively. The reference spur is as low as -73.5 dBc, while the worst case near-integer fractional spurs are lower than -63.2 dBc. With a power consumption of 18 mW, the jitter-power figure of merit is -252.1 dB (fractional-N) and -253.3 dB (integer-N). The locking time is below 9 μs for a 1-GHz frequency step. The synthesizer occupies 0.16 mm², including decoupling capacitors.

Topics & Concepts

Phase-locked loopJitterdBcPhase noisePLL multibitCMOSElectronic engineeringOffset (computer science)Frequency offsetPhysicsComputer scienceEngineeringChannel (broadcasting)TelecommunicationsProgramming languageOrthogonal frequency-division multiplexingAdvancements in PLL and VCO TechnologiesRadio Frequency Integrated Circuit DesignAnalog and Mixed-Signal Circuit Design
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