Title :
Dual-Sampling Skewed CMOS Design for Soft-Error Tolerance
Author :
Zhang, Ming ; Shanbhag, Naresh R.
Author_Institution :
Dept. of Electr. & Comput. Eng., Illinois Univ., Urbana, IL
Abstract :
Presented is a circuit technique that mitigates the impact of single-event transient (SET) in deep submicrometer circuits with minimal speed, power, and area penalty. The technique combines a novel dual-sampling flip-flop (DSFF) and the skewed CMOS (SCMOS) circuit style. The DSFF and SCMOS are designed to eliminate SETs with the polarity of 1rarr0 and 0rarr1, respectively. We study inverter chain circuits as well as sum-of-products implementation of random logic circuits in a typical 0.18-mum process under the influence of radiation induced soft errors. We quantify the SET tolerance of the proposed technique by using an error map and a recently developed tool soft-error rate analyzer (SERA). The results show that the DSFF incurs no speed penalty, if no SETs have reached the input of DSFF. Otherwise, the DSFF alone eliminates the 1rarr0 SETs while incurring a worst case speed and power penalty of 310 ps and 39 muW, respectively. The SCMOS eliminates the 0rarr1 SETs when the skewing factor is greater than four. Thus, the proposed technique potentially eliminates the impact of SETs with both polarities
Keywords :
CMOS integrated circuits; combinational circuits; flip-flops; integrated circuit reliability; 0.18 micron; CMOS design; combinational logic circuit; flip-flops; integrated-circuit reliability; single-event transient; soft-error tolerance; Combinational circuits; Flip-flops; Integrated circuit reliability; Inverters; Latches; Logic circuits; Power system reliability; Protection; Redundancy; Single event upset; Combinational logic circuit; flip-flop; integrated- circuit reliability; latch; single-event transient (SET); soft-error rate (SER);
Journal_Title :
Circuits and Systems II: Express Briefs, IEEE Transactions on
DOI :
10.1109/TCSII.2006.883829