Low-Cost Soft Error Robust Hardened D-Latch for CMOS Technology Circuit

In this paper, a Soft Error Hardened D-latch with improved performance is proposed, also featuring Single Event Upset (SEU) and Single Event Transient (SET) immunity. This novel D-latch can tolerate particles as charge injection in different internal nodes, as well as the input and output nodes. The performance of the new circuit has been assessed through different key parameters, such as power consumption, delay, Power-Delay Product (PDP) at various frequencies, voltage, temperature, and process variations. A set of simulations has been set up to benchmark the new proposed D-latch in comparison to previous D-latches, such as the Static D-latch, TPDICE-based D-latch, LSEH-1 and DICE D-latches. A comparison between these simulations proves that the proposed D-latch not only has a better immunity, but also features lower power consumption, delay, PDP, and area footprint. Moreover, the impact of temperature and process variations, such as aspect ratio (W/L) and threshold voltage transistor variability, on the proposed D-latch with regard to previous D-latches is investigated. Specifically, the delay and PDP of the proposed D-latch improves by 60.3% and 3.67%, respectively, when compared to the reference Static D-latch. Furthermore, the standard deviation of the threshold voltage transistor variability impact on the delay improved by 3.2%, while its impact on the power consumption improves by 9.1%. Finally, it is shown that the standard deviation of the (W/L) transistor variability on the power consumption is improved by 56.2%

Rule-Based Design for Low-Cost Double-Node Upset Tolerant Self-Recoverable D-Latch

This paper presents a low-cost, self-recoverable, double-node upset tolerant latch aiming at nourishing the lack of these devices in the state of the art, especially featuring self-recoverability while maintaining a low-cost pro le. Thus, this D-latch may be useful for high reliability and high-performance safety-critical applications as it can detect and recover faults happening during holding time in harsh radiation environments. The proposed D-latch design is based on a low-cost single event double-node upset tolerant latch and a rule-based double-node upset (DNU) tolerant latch which provides it with the self-recoverability against DNU, but paired with a low transistor count and high performance. Simulation waveforms support the achievements and demonstrate that this new D-latch is fully self-recoverable against double-node upset. In addition, the minimum improvement of the delay-power-area product of the proposed rule-based design for the low-cost DNU tolerant self-recoverable latch (RB-LDNUR) is 59%, compared with the latest DNU self-recoverable latch on the literature.Spanish Government MCIN/AEI/10.13039/501100011033/FEDER PID2020-117344RB-I00Regional Government P20_00265 P20_00633 B-RNM-680-UGR2

STAHL: A Novel Scan-Test-Aware Hardened Latch Design

As modern technology nodes become more susceptible to soft errors, many radiation hardened latch designs have been proposed. However, redundant circuitry used to tolerate soft errors in such hardened latches also reduces the test coverage of cell-internal manufacturing defects. To avoid potential test escapes that lead to soft error vulnerability and reliability issues, this paper proposes a novel Scan-Test-Aware Hardened Latch (STAHL). Simulation results show that STAHL has superior defect coverage compared to previous hardened latches while maintaining full radiation hardening in function mode.24th IEEE European Test Symposium (ETS\u2719), May 27-31, 2019, Baden-Baden, German

Highly Reliable Quadruple-Node Upset-Tolerant D-Latch

This work was supported in part by the Spanish MCIN/AEI /10.13039/501100011033/ FEDER under Grant PID2020-117344RB-I00, and in part by the Regional Government under Grant P20_00265 and Grant P20_00633.As CMOS technology scaling pushes towards the reduction of the length of transistors, electronic circuits face numerous reliability issues, and in particular nodes of D-latches at nano-scale confront multiple-node upset errors due to their operation in harsh radiative environments. In this manuscript, a new high reliable D-latch which can tolerate quadruple-node upsets is presented. The design is based on a low-cost single event double-upset tolerant (LSEDUT) cell and a clock-gating triple-level soft-error interceptive module (CG-SIM). Due to its LSEDUT base, it can tolerate two upsets, but the combination of two LSEDUTs and the triple-level CG-SIM provides the proposed D-latch with remarkable quadruple-node upsets (QNU) tolerance. Applying LSEDUTs for designing a QNU-tolerant D-latch improves considerably its features; in particular, this approach enhances its reliability against process variations, such as threshold voltage and (W/L) transistor variability, compared to previous QNU-tolerant D-latches and double-node-upset tolerant latches. Furthermore, the proposed D-latch not only tolerates QNUs, but it also features a clear advantage in comparison with the previous clock gating-based quadruple-node-upset-tolerant (QNUTL-CG) D-latch: it can mask single event transients. Speci c gures of merit endorse the gains introduced by the new design: compared with the QNUTL-CG D-latch, the improvements of the maximum standard deviations of the gate delay, induced by threshold voltage and (W/L) transistors variability of the proposed D-latch, are 13.8% and 5.7%, respectively. Also, the proposed D-latch has 23% lesser maximum standard deviation in power consumption, resulting from threshold voltage variability, when compared to the QNUTL-CG D-latch.Spanish MCIN/AEI /10.13039/501100011033/ FEDER under Grant PID2020-117344RB-I00Regional Government under Grant P20_00265 and Grant P20_0063

Soft-Error Resilience Framework For Reliable and Energy-Efficient CMOS Logic and Spintronic Memory Architectures

The revolution in chip manufacturing processes spanning five decades has proliferated high performance and energy-efficient nano-electronic devices across all aspects of daily life. In recent years, CMOS technology scaling has realized billions of transistors within large-scale VLSI chips to elevate performance. However, these advancements have also continually augmented the impact of Single-Event Transient (SET) and Single-Event Upset (SEU) occurrences which precipitate a range of Soft-Error (SE) dependability issues. Consequently, soft-error mitigation techniques have become essential to improve systems\u27 reliability. Herein, first, we proposed optimized soft-error resilience designs to improve robustness of sub-micron computing systems. The proposed approaches were developed to deliver energy-efficiency and tolerate double/multiple errors simultaneously while incurring acceptable speed performance degradation compared to the prior work. Secondly, the impact of Process Variation (PV) at the Near-Threshold Voltage (NTV) region on redundancy-based SE-mitigation approaches for High-Performance Computing (HPC) systems was investigated to highlight the approach that can realize favorable attributes, such as reduced critical datapath delay variation and low speed degradation. Finally, recently, spin-based devices have been widely used to design Non-Volatile (NV) elements such as NV latches and flip-flops, which can be leveraged in normally-off computing architectures for Internet-of-Things (IoT) and energy-harvesting-powered applications. Thus, in the last portion of this dissertation, we design and evaluate for soft-error resilience NV-latching circuits that can achieve intriguing features, such as low energy consumption, high computing performance, and superior soft errors tolerance, i.e., concurrently able to tolerate Multiple Node Upset (MNU), to potentially become a mainstream solution for the aerospace and avionic nanoelectronics. Together, these objectives cooperate to increase energy-efficiency and soft errors mitigation resiliency of larger-scale emerging NV latching circuits within iso-energy constraints. In summary, addressing these reliability concerns is paramount to successful deployment of future reliable and energy-efficient CMOS logic and spintronic memory architectures with deeply-scaled devices operating at low-voltages

inSense: A Variation and Fault Tolerant Architecture for Nanoscale Devices

Transistor technology scaling has been the driving force in improving the size, speed, and power consumption of digital systems. As devices approach atomic size, however, their reliability and performance are increasingly compromised due to reduced noise margins, difficulties in fabrication, and emergent nano-scale phenomena. Scaled CMOS devices, in particular, suffer from process variations such as random dopant fluctuation (RDF) and line edge roughness (LER), transistor degradation mechanisms such as negative-bias temperature instability (NBTI) and hot-carrier injection (HCI), and increased sensitivity to single event upsets (SEUs). Consequently, future devices may exhibit reduced performance, diminished lifetimes, and poor reliability. This research proposes a variation and fault tolerant architecture, the inSense architecture, as a circuit-level solution to the problems induced by the aforementioned phenomena. The inSense architecture entails augmenting circuits with introspective and sensory capabilities which are able to dynamically detect and compensate for process variations, transistor degradation, and soft errors. This approach creates ``smart\u27\u27 circuits able to function despite the use of unreliable devices and is applicable to current CMOS technology as well as next-generation devices using new materials and structures. Furthermore, this work presents an automated prototype implementation of the inSense architecture targeted to CMOS devices and is evaluated via implementation in ISCAS \u2785 benchmark circuits. The automated prototype implementation is functionally verified and characterized: it is found that error detection capability (with error windows from $\approx$30-400ps) can be added for less than 2\% area overhead for circuits of non-trivial complexity. Single event transient (SET) detection capability (configurable with target set-points) is found to be functional, although it generally tracks the standard DMR implementation with respect to overheads

Radiation Tolerant Electronics, Volume II

Research on radiation tolerant electronics has increased rapidly over the last few years, resulting in many interesting approaches to model radiation effects and design radiation hardened integrated circuits and embedded systems. This research is strongly driven by the growing need for radiation hardened electronics for space applications, high-energy physics experiments such as those on the large hadron collider at CERN, and many terrestrial nuclear applications, including nuclear energy and safety management. With the progressive scaling of integrated circuit technologies and the growing complexity of electronic systems, their ionizing radiation susceptibility has raised many exciting challenges, which are expected to drive research in the coming decade.After the success of the first Special Issue on Radiation Tolerant Electronics, the current Special Issue features thirteen articles highlighting recent breakthroughs in radiation tolerant integrated circuit design, fault tolerance in FPGAs, radiation effects in semiconductor materials and advanced IC technologies and modelling of radiation effects

High-Performance Robust Latches

First, a new high-performance robust latch (referred to as HiPeR latch) is presented that is insensitive to transient faults affecting its internal and output nodes by design, independently of the size of its transistors. Then, a modified version of the HiPeR latch (referred as HiPeR-CG) is proposed that is suitable to be used together with clock gating. Both proposed latches are faster than the latches most recently presented in the literature, while providing better or comparable robustness to transient faults, at comparable or lower costs in terms of area and power, respectively. Therefore, thanks to the good trade-offs in terms of performance, robustness, and cost, our proposed latches are particularly suitable to be adopted on critical paths

Design and Robustness Analysis on Non-volatile Storage and Logic Circuit

By combining the flexibility of MOS logic and the non-volatility of spintronic devices, spin-MOS logic and storage circuitry offer a promising approach to implement highly integrated, power-efficient, and nonvolatile computing and storage systems. Besides the persistent errors due to process variations, however, the functional correctness of Spin-MOS circuitry suffers from additional non-persistent errors that are incurred by the randomness of spintronic device operations, i.e., thermal fluctuations. This work quantitatively investigates the impact of thermal fluctuations on the operations of two typical Spin-MOS circuitry: one transistor and one magnetic tunnel junction (1T1J) spin-transfer torque random access memory (STT-RAM) cell and a nonvolatile latch design. A new nonvolatile latch design is proposed based on magnetic tunneling junction (MTJ) devices. In the standby mode, the latched data can be retained in the MTJs without consuming any power. Two types of operation errors can occur, namely, persistent and non-persistent errors. These are quantitatively analyzed by including models for process variations and thermal fluctuations during the read and write operations. A mixture importance sampling methodology is applied to enable yield-driven design and extend its application beyond memories to peripheral circuits and logic blocks. Several possible design techniques to reduce thermal induced non-persistent error rate are also discussed