Title :
A highly integratable millimeter-wave silicon waveguide array for Terabit application
Author :
Qidong Wang ; Guidotti, Daniel ; Jie Cui ; Liqiang Cao ; Tianchun Ye ; Lixi Wan
Author_Institution :
Key Lab. of Microelectron. Devices & Integrated Technol., Inst. of Microelectron., Beijing, China
Abstract :
Multi-core scalar CPU are approaching processing rates of 256 GFLOPS. Transport latency and bandwidth (BW) between DRAM and processor are a substantial bottleneck to optimal system performance. This is, in large part, because board level, data transport occurs over legacy L-C transmission lines having limited BW over a limited distance. Consequently, high performance, systems running memory intensive applications are able to utilize only a fraction of their available computational potential and remain idle for many clock cycles while waiting for data and instructions. This paper proposes guided millimeter wave on a socket as a BW scalable inter-chip communication interface. Scalability is afforded by high order digital modulation of the guided carrier wave and the wide, re-usable, free spectral range within each waveguide that can accommodate multiple full duplex channels.
Keywords :
DRAM chips; elemental semiconductors; millimetre wave devices; modulation; multiprocessing systems; peripheral interfaces; silicon; transmission lines; waveguides; BW scalable interchip communication interface; DRAM; GFLOPS; L-C transmission lines; Si; clock cycles; free spectral range; full duplex channels; guided carrier wave; high order digital modulation; integratable millimeter waveguide array; memory intensive applications; multicore scalar CPU; terabit application; transport latency; Arrays; Bandwidth; Optical waveguides; Probes; Random access memory; Silicon;
Conference_Titel :
Electronic Components and Technology Conference (ECTC), 2013 IEEE 63rd
Conference_Location :
Las Vegas, NV
Print_ISBN :
978-1-4799-0233-0
DOI :
10.1109/ECTC.2013.6575564
