A 0.5-to-2.5 Gb/s Reference-Less Half-Rate Digital CDR With Unlimited Frequency Acquisition Range and Improved Input Duty-Cycle Error Tolerance

Abstract

Clock and data recovery (CDR) circuits with wide frequency acquisition range offer flexibility in optical communication networks, help reduce link power through activity-based rate adaptation, and minimize cost with a single-chip multi-standard solution. Extracting the bit rate from the incoming random data stream is the main challenge in implementing reference-less CDRs. A conventional rotational frequency detector has a limited acquisition range of about ±50% of the VCO frequency, consumes large power, and is susceptible to harmonic locking. Extending its range requires additional high-speed circuitry and a complex state machine [1]. The DLL-based architecture in [2] requires passing high-speed data through a long string of power-hungry buffers, imposes stringent matching requirements, and works only with ring oscillators. Other approaches require detailed statistical [3] or timing analysis [4]. Further, all the above techniques are only suitable for full-rate CDRs. In this paper, we present a reference-less half-rate CDR that uses a sub-harmonic extraction method to achieve unlimited frequency acquisition range. This technique is capable of locking the CDR to within 40ppm of any sub-rate of the data (making it applicable for any sub-rate CDR architecture), while being immune to undesirable harmonic locking. This CDR also integrates a calibration loop to improve robustness to input duty cycle error.