A Fully-Synthesizable 10.06Gbps 16.1mW Injection-Locked CDR in 28nm FDSOI

A Fully-Synthesizable 10.06Gbps 16.1mW Injection-Locked CDR in 28nm FDSOI

An all-digital fully-synthesizable PVT-tolerant clock data recovery (CDR) architecture for wireline chip-to-chip interconnects is presented. The proposed architecture enables the co-synthesis of the CDR with the digital core. By eliminating the resource hungry manual layout and interfacing steps, wh...

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Veröffentlicht in:IEICE Transactions on Electronics 2017/03/01, Vol.E100.C(3), pp.259-267
Hauptverfasser: NARAYANAN, Aravind THARAYIL, DENG, Wei, YANG, Dongsheng, WU, Rui, OKADA, Kenichi, MATSUZAWA, Akira
Format: Artikel
Sprache:eng
Schlagworte:
all-digital
Architecture
clock data recovery
Clocks
Design engineering
Design improvements
Electronics
fully-synthesizable
injection locking
Manuals
Migration
phase-filtering
Power consumption
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Beschreibung
Zusammenfassung:An all-digital fully-synthesizable PVT-tolerant clock data recovery (CDR) architecture for wireline chip-to-chip interconnects is presented. The proposed architecture enables the co-synthesis of the CDR with the digital core. By eliminating the resource hungry manual layout and interfacing steps, which are necessary for conventional CDR topologies, the design process and the time-to-market can be drastically improved. Besides, the proposed CDR architecture enables the re-usability of majority of the sub-systems which enables easy migration to different process nodes. The proposed CDR is also equipped with a self-calibration scheme for ensuring tolerence over PVT. The proposed fully-syntehsizable CDR was implemented in 28nm FDSOI. The system achieves a maximum data rate of 10.06Gbps while consuming a power of 16.1mW from a 1V power supply.
ISSN:0916-8524
1745-1353
DOI:10.1587/transele.E100.C.259