Alleviate chip I/O pin constraints for multicore processors through optical interconnects

Author

Zhehui Wang ; Jiang Xu ; Peng Yang ; Xuan Wang ; Zhe Wang ; Duong, Luan H. K. ; Zhifei Wang ; Haoran Li ; Maeda, Rafael K. V. ; Xiaowen Wu ; Ye Yaoyao ; Qinfen Hao

Author_Institution

Dept. of Electron. & Comput. Eng., Hong Kong Univ. of Sci. & Technol., Hong Kong, China

fYear

2015

fDate

19-22 Jan. 2015

Firstpage

791

Lastpage

796

Abstract

Chip I/O pins are an increasingly limited resource and significantly affect the performance, power and cost of multicore processors. Optical interconnects promise low power and high bandwidth, and are potential alternatives to electrical interconnects. This work systematically developed a set of analytical models for electrical and optical interconnects to study their structures, receiver sensitivities, crosstalk noises, and attenuations. We verified the models by published implementation results. The analytical models quantitatively identified the advantages of optical interconnects in terms of bandwidth, energy consumption, and transmission distance. We showed that optical interconnects can significantly reduce chip pin counts. For example, compared to electrical interconnects, optical interconnects can save at least 92% signal pins when connecting chips more than 25 cm (10 inches) apart.

Keywords

multichip modules; multiprocessing systems; optical interconnections; wavelength division multiplexing; attenuations; chip I/O pin constraints; chip pin counts; crosstalk noises; electrical interconnects; multicore processors; optical interconnects; receiver sensitivities; Crosstalk; Energy consumption; Limiting; Optical interconnections; Optical receivers; Optical transmitters; Optical waveguides;

fLanguage

English

Publisher

ieee

Conference_Titel

Design Automation Conference (ASP-DAC), 2015 20th Asia and South Pacific

Conference_Location

Chiba

Print_ISBN

978-1-4799-7790-1

Type

conf

DOI

10.1109/ASPDAC.2015.7059107

Filename

7059107