Title :
AN ultra low power fault tolerant SRAM design in 90nm CMOS
Author :
Wang, Kuande ; Chen, Li ; Yang, Jinsheng
Abstract :
To mitigate the single-event effect, improve the stability and also maintain the low power characteristic of sub-threshold SRAM, a dual interlocked storage cell (DICE) based SRAM cell in 90 nm CMOS technology was proposed to eliminate the drawback of conventional DICE cell during read operation. In order to make the proposed SRAM cell work under different power supply voltages from 0.3 V to 0.6 V, an improved replica sense scheme is applied to produce a reference control signal, with which the optimal read time could be achieved. In this paper, a 256 times 8 bytes SRAM core was simulated and the operating frequency at VDD=0.3 V is up to 4.7 MHz with power dissipation 6.0 muW, while it is 45.5 MHz at VDD=0.6 V dissipating 140 muW. The layout of SRAM core was also done in 90 nm CMOS technology.
Keywords :
CMOS memory circuits; SRAM chips; fault tolerance; integrated circuit design; integrated circuit reliability; low-power electronics; nanoelectronics; radiation hardening (electronics); DICE cell; dual interlocked storage cell; memory size 8 Byte; power 140 muW; power 6.0 muW; power dissipation; reference control signal; replica sense scheme; single-event effect; size 90 nm; subthreshold SRAM design; ultra low-power fault tolerant design; voltage 0.3 V to 0.6 V; CMOS technology; Circuit stability; Fault tolerance; Large scale integration; Logic; Radiation hardening; Random access memory; Single event upset; Space technology; Voltage; Dual Interlocked cell (DICE); SRAM; Single Event Upset (SEU); fault tolerance; sub-threshold;
Conference_Titel :
Electrical and Computer Engineering, 2009. CCECE '09. Canadian Conference on
Conference_Location :
St. John´s, NL
Print_ISBN :
978-1-4244-3509-8
Electronic_ISBN :
0840-7789
DOI :
10.1109/CCECE.2009.5090294
