This work presents a low-spur and low-jitter fractional-N digital phase-locked loop (PLL). To reduce the fractional spurs caused by the non-linearity of the digital-to-time converter (DTC), two novel solutions are introduced. First, the inverse-constant-slope DTC achieves high-linearity, thanks to its immunity to channel-length modulation and non-linear parasitic capacitances. Second, the frequency-control-word (FCW) sub-tractive dithering technique randomizes the quantization error of the ?S modulator driving the PLL divider ratio without requiring an increased DTC dynamic range and pushing the fractional spurs outside the PLL bandwidth. The prototype, implemented in a 28-nm CMOS process, has an active area of 0.33 mm(2) and dissipates 17....
A fractional-N digital phase-locked loop (PLL) architecture with low fractional spur is presented in...
This paper presents a low-complexity calibration-free digital PLL architecture. The PLL adopts a fra...
DoctorThis thesis presents several low-noise techniques for the design of fractional-N PLL, includin...
This work presents a low-jitter and low-spur, fractional-N ring-oscillator-based digital phase-locke...
The quest of increasingly higher mobile uplink/downlink data-rates has recently driven the communica...
This paper introduces a Delta-Sigma fractional-N digital PLL based on a single-bit TDC. A digital-to...
Ultra-low-jitter and high-spectral-purity frequency synthesizers are key building blocks for high-pe...
Digital phase-locked loops (DPLLs) have been demonstrated to achieve excellent performance as fracti...
This work presents a low-jitter and low out-of-band noise two-core fractional- $N$ digital bang-bang...
In this article, we present a 4.5-5.1-GHz fractional-N digitally intensive phase-locked loop (DPLL) ...
Despite their superiority in silicon integration, ring-oscillator-based digital PLLs (RO-DPLLs) are ...
Nonlinearities in the time-to-digital converter (TDC) are a significant source of fractional spurs i...
This article presents a fractional-N sampling type-I phase-locked loop (PLL). To overcome the impair...
A fractional-N digital phase-locked loop (PLL) architecture with low fractional spur is presented in...
This paper presents a low-complexity calibration-free digital PLL architecture. The PLL adopts a fra...
DoctorThis thesis presents several low-noise techniques for the design of fractional-N PLL, includin...
This work presents a low-jitter and low-spur, fractional-N ring-oscillator-based digital phase-locke...
The quest of increasingly higher mobile uplink/downlink data-rates has recently driven the communica...
This paper introduces a Delta-Sigma fractional-N digital PLL based on a single-bit TDC. A digital-to...
Ultra-low-jitter and high-spectral-purity frequency synthesizers are key building blocks for high-pe...
Digital phase-locked loops (DPLLs) have been demonstrated to achieve excellent performance as fracti...
This work presents a low-jitter and low out-of-band noise two-core fractional- $N$ digital bang-bang...
In this article, we present a 4.5-5.1-GHz fractional-N digitally intensive phase-locked loop (DPLL) ...
Despite their superiority in silicon integration, ring-oscillator-based digital PLLs (RO-DPLLs) are ...
Nonlinearities in the time-to-digital converter (TDC) are a significant source of fractional spurs i...
This article presents a fractional-N sampling type-I phase-locked loop (PLL). To overcome the impair...
A fractional-N digital phase-locked loop (PLL) architecture with low fractional spur is presented in...
This paper presents a low-complexity calibration-free digital PLL architecture. The PLL adopts a fra...
DoctorThis thesis presents several low-noise techniques for the design of fractional-N PLL, includin...