Title :
On-chip interconnects: giga hertz and beyond
Author_Institution :
Hewlett-Packard Co., Palo Alto, CA, USA
Abstract :
Due to the excessive loss of long signal lines and limited DC and AC current carrying capacity, pushing the conventional on-chip interconnect system into multi-GHz VLSIs will soon hit performance barriers. Introduction of metal planes or meshes into on-chip interconnects provides an impedance-controlled environment for signal lines, and combined with larger signal lines, the long lossy line problem can be solved. Planes also help distribute power with minimal AC/DC noise. As an additional feature, integration of passive elements into on-chip interconnects will be very useful for realization of a fully integrated “system-on-a-chip”
Keywords :
MMIC; capacitors; electric impedance; inductors; integrated circuit interconnections; integrated circuit metallisation; integrated circuit noise; losses; microprocessor chips; resistors; AC current carrying capacity; AC/DC noise; DC current carrying capacity; VLSIs; fully integrated system-on-a-chip; impedance-controlled environment; lossy lines; metal meshes; metal planes; on-chip interconnect system; on-chip interconnects; passive element integration; performance barriers; plane power distribution; signal line length; signal line losses; signal lines; system-on-a-chip; Delay; Integrated circuit interconnections; Laboratories; Performance loss; Power supplies; Power system interconnection; Printed circuits; Repeaters; Routing; System-on-a-chip;
Conference_Titel :
Interconnect Technology Conference, 1998. Proceedings of the IEEE 1998 International
Conference_Location :
San Francisco, CA
Print_ISBN :
0-7803-4285-2
DOI :
10.1109/IITC.1998.704739
