Title :
A low-jitter 125-1250-MHz process-independent and ripple-poleless 0.18-μm CMOS PLL based on a sample-reset loop filter
Author :
Maxim, Adrian ; Scott, Baker ; Schneider, Edmund M. ; Hagge, Melvin L. ; Chacko, Steven ; Stiurca, Dan
Author_Institution :
Maxim Integrated Products, Austin, CA, USA
fDate :
11/1/2001 12:00:00 AM
Abstract :
This paper describes a low-jitter phase-locked loop (PLL) implemented in a 0.18-μm CMOS process. A sample-reset loop filter architecture is used that averages the oscillator proportional control current which provides the feedforward zero over an entire update period and hence leads to a ripple-free control signal. The ripple-free control current eliminates the need for an additional filtering pole, leading to a nearly 90° phase margin which minimizes input jitter peaking and transient locking overshoot. The PLL damping factor is made insensitive to process variations by making it dependent only upon a bandgap voltage and ratios of circuit elements. This ensures tracking between the natural frequency and the stabilizing zero. The PLL has a frequency range of 125-1250 MHz, frequency resolution better than 500 kHz, and rms jitter less than 0.9% of the oscillator period
Keywords :
CMOS integrated circuits; active filters; feedforward; frequency synthesizers; phase locked loops; phase locked oscillators; programmable filters; proportional control; timing jitter; 125 to 1250 MHz; bandgap voltage; charge-pump PLL; damping factor; feedback circuit; feedforward zero; frequency synthesiser; low-jitter; oscillator proportional control current; process-independent PLL; programmable stage; ripple-free control current; ripple-poleless CMOS PLL; sample-reset loop filter; transient locking overshoot; CMOS process; Damping; Filtering; Filters; Frequency; Jitter; Oscillators; Phase locked loops; Photonic band gap; Proportional control;
Journal_Title :
Solid-State Circuits, IEEE Journal of
