Xi Meng scite author profile

This paper presents an ultra-lower-power (ULP) digital-to-time-converter (DTC)-assisted fractional-N all-digital phase-locked loop (ADPLL) suitable for IoT applications. A proposed hybrid time-to-digital converter (TDC) extends the vernier-TDC input range with little power overhead in order to overcome the stability issue in the conventional architectures. The hybrid TDC also facilitates a background gain calibration to achieve a stable in-band phase noise insensitive to process, voltage, and temperature (PVT) variations. The implementation of a buffercascaded DTC simplifies the design complexity of the fractional-N operation. The ADPLL also features a 200 µW low-phase-noise inverse-class-F (class-F −1 ) digitally controlled oscillator (DCO) without the need of two-dimensional (2-D) capacitor tuning for frequency alignment of the fundamental and 2 nd -harmonic. Fabricated in 65-nm CMOS, the ULP ADPLL prototype achieves 868 fs rms jitter in a fractional-N channel when consuming only 529 µW, corresponding to a figure-of-merit (FoM) of −244 dB.

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Wideband MM-Wave CMOS VCOs - Switched Inductor, Mode-Switching Inductive Tuning, and Harmonic Extraction Techniques

Yin

Meng

Mak

et al. 2019

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Xi Meng

A 15.2-to-18.2GHz Balanced Dual-Core Inverse-Class-F VCO with Q-Enhanced 2^nd-Harmonic Resonance Achieving 187-to-188.1dBc/Hz FoM in 28nm CMOS

A 529-μW Fractional-N All-Digital PLL Using TDC Gain Auto-Calibration and an Inverse-Class-F DCO in 65-nm CMOS

Wideband MM-Wave CMOS VCOs - Switched Inductor, Mode-Switching Inductive Tuning, and Harmonic Extraction Techniques

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Xi Meng

A 15.2-to-18.2GHz Balanced Dual-Core Inverse-Class-F VCO with Q-Enhanced 2nd-Harmonic Resonance Achieving 187-to-188.1dBc/Hz FoM in 28nm CMOS

A 529-μW Fractional-N All-Digital PLL Using TDC Gain Auto-Calibration and an Inverse-Class-F DCO in 65-nm CMOS

Wideband MM-Wave CMOS VCOs - Switched Inductor, Mode-Switching Inductive Tuning, and Harmonic Extraction Techniques

Contact Info

Product

Resources

About

A 15.2-to-18.2GHz Balanced Dual-Core Inverse-Class-F VCO with Q-Enhanced 2^nd-Harmonic Resonance Achieving 187-to-188.1dBc/Hz FoM in 28nm CMOS