In the previous three decades, many Radiation-Hardened-by-Design (RHBD) Flip-Flops (FFs) have been designed and improved to be immune to Single Event Upsets (SEUs). Their specifications are enhanced regarding soft error tolerance, area overhead, power consumption, and delay. In this review, previously presented RHBD FFs are classified into three categories with an overview of each category. Six well-known RHBD FFs architectures are simulated using a 180 nm CMOS process to show a fair comparison between them while the conventional Transmission Gate Flip-Flop (TGFF) is used as a reference design for this comparison. The results of the comparison are analyzed to give some important highlights about each design
Three layout-hardened Dual Interlocked Storage Cell (DICE) D Flip-Flops (DFFs) were designed and man...
Abstract—A new circuit-level single-event upset (SEU) hard-ening approach for high-speed SiGe HBT cu...
Abstract Conventional flip‐flops are more vulnerable to particle strikes in a radiation environment....
abstract: ABSTRACT The D flip flop acts as a sequencing element while designing any pipelined system...
In this paper, a variety of flip-flop (FF) designs fabricated in a commercial 28-nm Fully-Depleted S...
Abstract: A novel Single Event Upset (SEU) tolerant flip-flop design is proposed, which is well suit...
Numerous radiation-hardened-by-design (RHBD) flip-flops have been developed to increase the dependab...
Radiation induced soft errors is a well-known problem in electronic designs. It happens due to ioniz...
Radiation from terrestrial and space environments is a great danger to integrated circuits (ICs). A ...
SRAM based reprogrammable FPGAs are sensitive to radiation-induced Single Event Upsets (SEU), not on...
A guard-gate based flip-flop circuit temporally hardened against single-event effects is presented i...
Circuits that need to operate in harsh environments such as in space, military, nuclear reactors, et...
International audienceIn space, the impact of radiative particles, such as neutrons and heavy ions, ...
Down-scaling of the supply voltage is considered as the most effective means of reducing the power- ...
FPGAs are an attractive alternative for many space-based computing operations. While radiation harde...
Three layout-hardened Dual Interlocked Storage Cell (DICE) D Flip-Flops (DFFs) were designed and man...
Abstract—A new circuit-level single-event upset (SEU) hard-ening approach for high-speed SiGe HBT cu...
Abstract Conventional flip‐flops are more vulnerable to particle strikes in a radiation environment....
abstract: ABSTRACT The D flip flop acts as a sequencing element while designing any pipelined system...
In this paper, a variety of flip-flop (FF) designs fabricated in a commercial 28-nm Fully-Depleted S...
Abstract: A novel Single Event Upset (SEU) tolerant flip-flop design is proposed, which is well suit...
Numerous radiation-hardened-by-design (RHBD) flip-flops have been developed to increase the dependab...
Radiation induced soft errors is a well-known problem in electronic designs. It happens due to ioniz...
Radiation from terrestrial and space environments is a great danger to integrated circuits (ICs). A ...
SRAM based reprogrammable FPGAs are sensitive to radiation-induced Single Event Upsets (SEU), not on...
A guard-gate based flip-flop circuit temporally hardened against single-event effects is presented i...
Circuits that need to operate in harsh environments such as in space, military, nuclear reactors, et...
International audienceIn space, the impact of radiative particles, such as neutrons and heavy ions, ...
Down-scaling of the supply voltage is considered as the most effective means of reducing the power- ...
FPGAs are an attractive alternative for many space-based computing operations. While radiation harde...
Three layout-hardened Dual Interlocked Storage Cell (DICE) D Flip-Flops (DFFs) were designed and man...
Abstract—A new circuit-level single-event upset (SEU) hard-ening approach for high-speed SiGe HBT cu...
Abstract Conventional flip‐flops are more vulnerable to particle strikes in a radiation environment....