Title :
Robust design of low power CMOS analogue integrated circuits
Author :
Tarim, T.B. ; Ismail, Mahamod
Author_Institution :
Texas Instrum. Inc., Dallas, TX, USA
fDate :
8/1/2001 12:00:00 AM
Abstract :
As feature sizes move into the deep submicron ranges and power supply voltages are reduced, the effect of both device mismatch and inter-die process variations on the performance and reliability of analogue integrated circuits is magnified. The statistical MOS (SMOS) model accounts for both inter-die and intra-die variations. A low power analogue CMOS square-law cell, and a new transconductor and multiplier using this cell as the main building block, are presented in the paper. The paper focuses on the robust design of the transconductor and multiplier circuits. The circuits operate in the saturation region with fully balanced input signals. Initial circuit simulation results are given. Response surface methodology and design of experiment techniques were used as statistical VLSI design techniques combined with the SMOS model. Device size optimisation and yield enhancement are demonstrated
Keywords :
CMOS analogue integrated circuits; VLSI; design of experiments; integrated circuit design; integrated circuit modelling; low-power electronics; surface fitting; CMOS analogue integrated circuit; circuit simulation; deep-submicron VLSI technology; design of experiments; device mismatch; inter-die process variation; intra-die process variation; low-power design; multiplier; reliability; response surface methodology; square law cell; statistical MOS model; transconductor; yield optimisation;
Journal_Title :
Circuits, Devices and Systems, IEE Proceedings -
DOI :
10.1049/ip-cds:20010340
