Title :
A 3.5 GHz Digital Fractional-N PLL Frequency Synthesizer Based on Ring Oscillator Frequency-to-Digital Conversion
Author :
Weltin-Wu, Colin ; Guobi Zhao ; Galton, Ian
Author_Institution :
Analog Devices, San Jose, CA, USA
Abstract :
A 3.5 GHz digital fractional-N PLL in 65 nm CMOS technology is presented that achieves phase noise and spurious tone performance comparable to those of a high-performance analog PLL. It is enabled by a new second-order frequency-to-digital converter that uses a dual-mode ring oscillator and digital logic instead of a charge pump and ADC. It also incorporates a new technique to reduce excess phase noise that would otherwise be caused by component mismatches when the DCO input is near integer boundaries. The PLL´s largest in-band fractional spur is -60 dBc, its worst-case reference spur is -81 dBc, and its phase noise is -93, -126, and -151 dBc/Hz at offsets of 100 kHz, 1 MHz, and 20 MHz, respectively. Its active area is 0.34 mm2 and it dissipates 15.6 mW from a 1 V supply.
Keywords :
CMOS digital integrated circuits; MMIC oscillators; analogue-digital conversion; digital phase locked loops; field effect MMIC; frequency synthesizers; logic circuits; phase noise; ADC; CMOS technology; charge pump; digital fractional-N PLL frequency synthesizer; digital logic; dual-mode ring oscillator; frequency 3.5 GHz; high-performance analog PLL; near integer boundary; phase noise reduction; power 15.6 mW; ring oscillator frequency-to-digital conversion; second-order frequency-to-digital converter; size 65 nm; spurious tone performance; voltage 1 V; Calculators; Frequency conversion; Modulation; Noise; Phase locked loops; Quantization (signal); Radiation detectors; Digital PLL; PLL; fractional-N phase-locked loop; frequency synthesizer; frequency-to-digital conversion;
Journal_Title :
Solid-State Circuits, IEEE Journal of
DOI :
10.1109/JSSC.2015.2468712
