Title :
Low-Power Dynamic Memory Word Line Decoding for Static Random Access Memories
Author :
Samson, Giby ; Ananthapadmanabhan, Nagaraj ; Badrudduza, Sayeed A. ; Clark, Lawrence T.
Author_Institution :
Dept. of Electr. Eng., Arizona State Univ., Tempe, AZ
Abstract :
Conventional memory address decoders based on static CMOS gates incur high clock loading and unnecessary power dissipation in unselected banks. This paper presents a dynamic word line decoder which is fast, has reduced active and leakage power dissipation, and also enables faster race-free sense timing. In a multi-bank memory array with sixteen decoders, the energy-delay product of the dynamic decoder is 66% lower than a low-power static version. The design leverages the predictability of dynamic circuits to provide significant decoder leakage reduction in unselected banks. The dynamic decoder has been fabricated on a 90 nm bulk CMOS process. The measured test chip address to word line delay is 170 ps at 1.5 V and the measured leakage reduction is over 20x at V DD greater than 0.8 V.
Keywords :
CMOS memory circuits; decoding; integrated circuit testing; low-power electronics; random-access storage; bulk CMOS process; conventional memory address decoders; decoder leakage reduction; energy-delay product; high clock loading; leakage power dissipation; low-power dynamic memory word line decoding; low-power static version; measured test chip; multibank memory array; race-free sense timing; size 90 nm; static CMOS gates; static random access memories; time 170 ps; voltage 1.5 V; Circuit testing; Clocks; Decoding; Delay; Power dissipation; Power measurement; Random access memory; SRAM chips; Semiconductor device measurement; Timing; Address decoder; dynamic circuits; leakage reduction; power dissipation; static random access memory;
Journal_Title :
Solid-State Circuits, IEEE Journal of
DOI :
10.1109/JSSC.2008.2005813
