A 1-to-6Gb/s phase-interpolator-based burst-mode CDR in 65nm CMOS

Burst-mode clock and data recovery circuits (BMCDR) are widely used in passive optical networks (PON) [1] and as a replacement for conventional CDRs in clock-forwarding links to reduce power [2]. In PON, a single CDR performs the task of clock and data recovery for several burst sequences, each originating from a different source. As a result, the BMCDR is required to lock to an incom ing data stream within tens of Uls (for example 40ns in GPON). Previous works use either injection locking [3, 4] or gated VCO [5, 6] to achieve this fast lock ing. In both cases, the control voltage of the CDR´s VCO is generated by a refer ence PLL with a matching VCO to guarantee accurate frequency locking. However, any component mismatch between the two VCO´s results in a frequen cy offset between the reference PLL frequency and the CDR´s VCO frequency, and hence in a reduction of the CDR´s tolerance for consecutive identical digits (CID). For example, [7] reports a frequency offset of over 20MHz (2000ppm) for 10Gb/s operation. We present a BMCDR that is based on phase interpolation (PI), eliminating the possibility of local frequency offset between the reference and recovered clock. We demonstrate 1 to 6Gb/s operation in 65nm CMOS with a locking time of less than 1UI.