Title :
Improved cellular structures for bit-steered ROM finite ring systolic arrays
Author :
Jullien, G.A. ; Miller, W.C.
Author_Institution :
VLSI Res. Group, Windsor Univ., Ont., Canada
Abstract :
A discussion is presented of radical improvements to a small steerable ROM structure that is used in linear bit-level systolic arrays for finite ring computations. The new circuit allows a single bit computation, on a fixed coefficient inner product step, to be computed by the evaluation of individually pipelined dynamic nodes. The absence of a chain of logic gates (static or dynamic) within the bit-level cell allows very fast operation of the pipeline; mask extracted SPICE simulations predict 50-MHz pipeline rates for 3-μm CMOS. A complete word-level inner product step is available with a maximum latency of only 10 pipeline clock cycles using 5-bit ring moduli
Keywords :
CMOS integrated circuits; VLSI; digital signal processing chips; integrated memory circuits; pipeline processing; read-only storage; systolic arrays; 3 micron; 50 MHz; CMOS; bit-level cell; bit-steered ROM finite ring systolic arrays; cellular structures; evaluation of individually pipelined dynamic nodes; fast operation; finite ring computations; fixed coefficient inner product step; latency; linear bit-level systolic arrays; mask extracted SPICE simulations; ring moduli; single bit computation; steerable ROM structure; word-level inner product step; CMOS logic circuits; Circuit simulation; Computational modeling; Delay; Logic gates; Pipelines; Predictive models; Read only memory; SPICE; Systolic arrays;
Conference_Titel :
Circuits and Systems, 1990., IEEE International Symposium on
Conference_Location :
New Orleans, LA
DOI :
10.1109/ISCAS.1990.112396
