DocumentCode
2172458
Title
Performance Comparison of Interconnect Technology and Architecture Options for Deep Submicron Technology Nodes
Author
Bamal, Mandeep ; List, Scott ; Stucchi, Michele ; Verhulst, Anne S. ; Van Hove, Marleen ; Cartuyvels, Rudi ; Beyer, Gerald ; Maex, Karen
Author_Institution
IMEC, Leuven
fYear
2006
fDate
5-7 June 2006
Firstpage
202
Lastpage
204
Abstract
Several technological and architectural solutions have been proposed to solve the "interconnect performance bottleneck", such as the use of on-chip transmission lines, carbon-nanotube (CNT) interconnects, wafer-level package (WLP) interconnects, 3D interconnects, RF and microwave interconnects and optical interconnects. It is essential to accurately estimate the interconnect performance and power gains achievable by these options and to understand the various trade-offs involved between the different metrics of interest. In this paper, an exhaustive comparison in terms of representative performance, energy and density metrics has been carried out among the different options for global interconnects. This analysis shows that 3D interconnects offer an attractive option to reduce the energy dissipation and propagation delay of long on-chip wires (51% and 54% reduction in latency and energy dissipation respectively at 45nm node). This analysis also shows that optical interconnects offer reduced latency compared to scaled Cu/low-k technologies but they do not offer significant improvement compared to other technologies like WLP interconnects (Beyne, 2003). It also follows from the analysis that CNT interconnects compare favorably to scaled Cu/low-k interconnects in terms of latency with a 42% reduction in delay
Keywords
carbon nanotubes; copper; integrated circuit interconnections; low-k dielectric thin films; optical interconnections; transmission lines; 3D interconnects; CNT interconnects; Cu; RF interconnects; WLP interconnects; carbon-nanotube interconnects; copper low-k technology; deep submicron technology nodes; delay reduction; interconnect performance bottleneck; interconnect technology; microwave interconnects; on-chip transmission lines; optical interconnects; wafer-level package interconnects; Carbon nanotubes; Delay; Energy dissipation; Microwave technology; Optical interconnections; Packaging; Performance gain; Power transmission lines; Radio frequency; Wafer scale integration;
fLanguage
English
Publisher
ieee
Conference_Titel
Interconnect Technology Conference, 2006 International
Conference_Location
Burlingame, CA
Print_ISBN
1-4244-0104-6
Type
conf
DOI
10.1109/IITC.2006.1648688
Filename
1648688
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