Sub-sampling PLL techniques

Gao, Xiang; Klumperink, Eric A.M.; Nauta, Bram

doi:10.1109/cicc.2015.7338420

Cited by 35 publications

(13 citation statements)

References 22 publications

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“…is -124dBc/Hz at a 2.2GHz carrier with less than ±1dB variation for all digital codes, while the PLL alone without DTC showed -125dBc/Hz [29]. This shows the DTC is suitable for low-phase-noise applications.…”

Section: B Phase Noise and Jittermentioning

confidence: 82%

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A High-Linearity Digital-to-Time Converter Technique: Constant-Slope Charging

Palattella

Geraedts

et al. 2015

IEEE J. Solid-State Circuits

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Section: B Phase Noise and Jittermentioning

confidence: 82%

“…In an attempt to still quantify the phase noise, we used a previously published low-jitter PLL [29] as a frequency multiplier with the setup in Fig. 21 (a).…”

Section: B Phase Noise and Jittermentioning

confidence: 99%

A High-Linearity Digital-to-Time Converter Technique: Constant-Slope Charging

Palattella

Geraedts

et al. 2015

IEEE J. Solid-State Circuits

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“…analog-to-digital converters, optical data communication and RF front-ends. Sub-sampling phase-locked loops (SSPLLs) [1][2][3][4] have superior phase noise (PN) performance compared to conventional phase-frequency detector (PFD) PLLs. However, SSPLLs only reduce the closein PN.…”

Section: Introductionmentioning

confidence: 99%

Feedforward Phase Noise Cancellation Exploiting a Sub-Sampling Phase Detector

Thijssen

Klumperink

Quinlan

et al. 2018

IEEE Trans. Circuits Syst. II

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This paper presents a feedforward phase noise cancellation technique to reduce phase noise of the output clock signal of a phase-locked loop (PLL). It uses a sub-sampling phase detector to measure the phase noise and a variable time delay for cancellation. Both phase noise and spurs are reduced. Analytical expressions have been derived that characterize the performance of this technique and show its fundamental limitations. A subsampling phase-locked loop with the cancellation technique as a built-in feature is described. The feedforward technique has no stability requirements in contrast to conventional PLL architectures. The phase noise reduction bandwidth is increased to almost a third of the reference frequency-3x the maximal bandwidth for 3 rd order type-II PLLs. The proposed analytical model shows a phase noise reduction of 9 dB at a frequency offset of f ref /10. The total rms jitter is improved by 7.2 dB. The analytical results are verified by simulations.

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“…Recently, subsampling technique has been proposed as an alternative approach to the conventional tri-state phase-frequency detector (PFD) to achieve greatly improved in-band phase noise [1]. The SSPLL in [2] uses a tri-state PFD with large dead-zone to switch between the regular frequency/phase loop (FPL) and the subsampling loop (SSL).…”

Section: Introductionmentioning

confidence: 99%

“…Furthermore, to achieve fractional frequency synthesis in subsampling mode, conventional methods involving toggling of frequency dividers and its associated sigma-delta noise shaping cannot be used directly, as VCO zero-crossing sampling by the SSL is wanted [1]. To resolve this problem, prior art has proposed to use digital-to-time converter (DTC) on the reference clock to offset this mismatch such that the reference edge remains aligned with the VCO zero-crossing even in fractional-N mode [4].…”

Section: Introductionmentioning

confidence: 99%

Multi-phase sub-sampling fractional-N PLL with soft loop switching for fast robust locking

Liao

Dai

Nauta

et al. 2017

2017 IEEE Custom Integrated Circuits Conference (CICC)

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This paper presents a low phase noise sub-sampling PLL (SSPLL) with multi-phase outputs. Automatic soft switching between the sub-sampling phase loop and frequency loop is proposed to improve robustness against perturbations and interferences that may cause a traditional SSPLL to lose lock. A quadrature LC oscillator with capacitive phase interpolation network is employed to generate multi-phase outputs, which are further utilized to achieve fractional-N frequency synthesis. Implemented in a 130nm CMOS technology, the SSPLL chip is able to achieve a measured in-band phase noise of -120 dBc/Hz and a measured integrated jitter of 209 fs at 2.4 GHz, while consuming 27.2 mW with 16 output phases. The measured reference spur and fractional spur level is -72 dBc and -49 dBc, respectively.Index Terms -phase locked loop, subsampling, fractional-N, stability, multi-phase VCO, phase detector, jitter.

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Sub-sampling PLL techniques

Cited by 35 publications

References 22 publications

A High-Linearity Digital-to-Time Converter Technique: Constant-Slope Charging

A High-Linearity Digital-to-Time Converter Technique: Constant-Slope Charging

Feedforward Phase Noise Cancellation Exploiting a Sub-Sampling Phase Detector

Multi-phase sub-sampling fractional-N PLL with soft loop switching for fast robust locking

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