Title :
Reliable design of multichip nonblocking crossbars
Author :
Ghosh, Joydeep ; Varma, Anujan
Author_Institution :
Dept. of Electr. & Comput. Eng., Texas Univ., Austin, TX, USA
Abstract :
A major problem in the design of VLSI crossbar networks is the simultaneous-switching noise (also known as Delta-I noise), caused by the simultaneous activation of a large number of line-drivers at the output leads of the VLSI package. In a nonblocking configuration, one can reduce the maximum number of active line-drivers in a chip by using extra columns of chips. Tight upper and lower bounds are derived for the number of additional columns required for a one-sided nonblocking crossbar network when a Delta-I constraint is imposed. By using algorithms that allocate paths intelligently, a substantial reduction in the Delta-I constraint is imposed. A substantial reduction in the Delta-I noise can be achieved with a modest hardware overhead, if a small blocking probability is acceptable. The first-fit and the best-fit case bus-allocation policies are introduced
Keywords :
VLSI; circuit reliability; driver circuits; multiprocessor interconnection networks; Delta-I constraint; Delta-I noise; VLSI crossbar networks; VLSI package; best-fit case bus-allocation; blocking probability; chip columns; intelligent path allocation algorithms; line-drivers; multichip nonblocking crossbars; one-sided nonblocking crossbar network; output leads; reliable design; simultaneous-switching noise; tight lower bounds; tight upper bounds; Active noise reduction; Circuit noise; Communication switching; Computer network reliability; Hardware; Noise reduction; Packaging; Reliability engineering; Switches; Very large scale integration;
Conference_Titel :
Computer Design: VLSI in Computers and Processors, 1990. ICCD '90. Proceedings, 1990 IEEE International Conference on
Conference_Location :
Cambridge, MA
Print_ISBN :
0-8186-2079-X
DOI :
10.1109/ICCD.1990.130164
