Title :
Latency reduction in optical interconnects using short optical pulses
Author :
Agarwal, Diwakar ; Keeler, Gordon A. ; Debaes, Christof ; Nelson, Bianca E. ; Helman, Noah C. ; Miller, David A B
Author_Institution :
Depts. of Electr. Eng. & Appl. Phys., Stanford Univ., CA, USA
Abstract :
We present a new method of latency reduction in optical interconnects: using very low duty cycle return-to-zero encoding (i.e., subpicosecond pulses). An analytical comparison of three different receiver architectures, including transimpedance, integrating, and totem-pole diode pair, is presented. For all three receivers, we demonstrate that using short pulses instead of nonreturn-to-zero (NRZ) shortens the circuit delay. We also experimentally demonstrate a ∼65% reduction in latency of a transimpedance receiver by using short optical pulses. Finally, we show that the latency of optical interconnects can be comparable to or even less than electrical interconnects for global on-chip communication.
Keywords :
CMOS integrated circuits; electro-optical modulation; high-speed optical techniques; integrated circuit interconnections; integrated optoelectronics; optical interconnections; optical receivers; p-i-n photodiodes; quantum well devices; CMOS integrated circuits; MQW modulator; circuit delay; global on-chip communication; integrating receivers; latency reduction; optical interconnects; receiver architectures; short optical pulses; subpicosecond pulses; totem-pole diode pair receivers; transimpedance receivers; very low duty cycle return-to-zero encoding; Clocks; Computer interfaces; Delay estimation; Diodes; Integrated circuit interconnections; Optical interconnections; Optical pulses; Optical receivers; Vertical cavity surface emitting lasers; Wide area networks;
Journal_Title :
Selected Topics in Quantum Electronics, IEEE Journal of
DOI :
10.1109/JSTQE.2003.813309
