Single event double upsets (SEDUs) caused by charge sharing have been an important contributor to the soft error in integrated circuits. Most of the up-to-date double-upset (DU) tolerant latches suffer from high costs in terms of delay, power and area. In this paper, we propose a novel high-performance low-cost double-upset tolerant (HLDUT) latch. Simulation waveforms have validated the double-upset tolerance of the proposed latch. Besides, detailed comparisons demonstrate that our design saves 805.24% delay-power-area product (DPAP) on average compared with other considered up-to-date double-upset tolerant latches, which means the proposed latch is a promising candidate for future highly reliable low-cost applications
A high-performance and low power consumption triple-node upset self-recoverable latch (HTNURL) is pr...
International audienceWith the advancement of semiconductor technologies, nano-scale CMOS circuits h...
Due to semiconductor technology scaling, integrated circuits have become more sensitive to soft erro...
To avoid soft errors in integrated circuits, this paper presents two high-performance latch designs,...
In this paper, a Soft Error Hardened D-latch with improved performance is proposed, also featuring ...
International audienceFirst, this paper proposes a double-node-upset (DNU)-completely-tolerant (DNUC...
This paper presents a single-event-upset tolerant latch design based on a redundant structure featur...
A single event causing a double-node upset is likely to occur in nanometric complementary metal-oxid...
International audienceTo meet the requirements of both costeffectiveness and high reliability for lo...
International audienceWith the reduction of technology nodes now reaching 2nm, circuits become incre...
This paper proposes two new slave latches for improving the Single Event Upset (SEU) tolerance of a ...
The last few years have seen the development and fabrication of nanoscale circuits at high density a...
This paper presents a set of eight novel configurations for the design of single event soft error (S...
International audienceThis paper presents a dual-modular-redundancy and dual-level error-interceptio...
This work was supported in part by the Spanish MCIN/AEI /10.13039/501100011033/ FEDER under Grant PI...
A high-performance and low power consumption triple-node upset self-recoverable latch (HTNURL) is pr...
International audienceWith the advancement of semiconductor technologies, nano-scale CMOS circuits h...
Due to semiconductor technology scaling, integrated circuits have become more sensitive to soft erro...
To avoid soft errors in integrated circuits, this paper presents two high-performance latch designs,...
In this paper, a Soft Error Hardened D-latch with improved performance is proposed, also featuring ...
International audienceFirst, this paper proposes a double-node-upset (DNU)-completely-tolerant (DNUC...
This paper presents a single-event-upset tolerant latch design based on a redundant structure featur...
A single event causing a double-node upset is likely to occur in nanometric complementary metal-oxid...
International audienceTo meet the requirements of both costeffectiveness and high reliability for lo...
International audienceWith the reduction of technology nodes now reaching 2nm, circuits become incre...
This paper proposes two new slave latches for improving the Single Event Upset (SEU) tolerance of a ...
The last few years have seen the development and fabrication of nanoscale circuits at high density a...
This paper presents a set of eight novel configurations for the design of single event soft error (S...
International audienceThis paper presents a dual-modular-redundancy and dual-level error-interceptio...
This work was supported in part by the Spanish MCIN/AEI /10.13039/501100011033/ FEDER under Grant PI...
A high-performance and low power consumption triple-node upset self-recoverable latch (HTNURL) is pr...
International audienceWith the advancement of semiconductor technologies, nano-scale CMOS circuits h...
Due to semiconductor technology scaling, integrated circuits have become more sensitive to soft erro...