INVESTIGATING THE EFFECTS OF SINGLE-EVENT UPSETS IN STATIC AND DYNAMIC REGISTERS

Radiation-induced single-event upsets (SEUs) pose a serious threat to the reliability of registers. The existing SEU analyses for static CMOS registers focus on the circuit-level impact and may underestimate the pertinent SEU information provided through node analysis. This thesis proposes SEU node analysis to evaluate the sensitivity of static registers and apply the obtained node information to improve the robustness of the register through selective node hardening (SNH) technique. Unlike previous hardening techniques such as the Triple Modular Redundancy (TMR) and the Dual Interlocked Cell (DICE) latch, the SNH method does not introduce larger area overhead. Moreover, this thesis also explores the impact of SEUs in dynamic flip-flops, which are appealing for the design of high-performance microprocessors. Previous work either uses the approaches for static flip-flops to evaluate SEU effects in dynamic flip-flops or overlook the SEU injected during the precharge phase. In this thesis, possible SEU sensitive nodes in dynamic flip-flops are re-examined and their window of vulnerability (WOV) is extended. Simulation results for SEU analysis in non-hardened dynamic flip-flops reveal that the last 55.3 % of the precharge time and a 100% evaluation time are affected by SEUs

Circuit designs for low-power and SEU-hardened systems

The desire to have smaller and faster portable devices is one of the primary motivations for technology scaling. Though advancements in device physics are moving at a very good pace, they might not be aggressive enough for now-a-day technology scaling trends. As a result, the MOS devices used for present day integrated circuits are pushed to the limit in terms of performance, power consumption and robustness, which are the most critical criteria for almost all applications. Secondly, technology advancements have led to design of complex chips with increasing chip densities and higher operating speeds. The design of such high performance complex chips (microprocessors, digital signal processors, etc) has massively increased the power dissipation and, as a result, the operating temperatures of these integrated circuits. In addition, due to the aggressive technology scaling the heat withstanding capabilities of the circuits is reducing, thereby increasing the cost of packaging and heat sink units. This led to the increase in prominence for smarter and more robust low-power circuit and system designs. Apart from power consumption, another criterion affected by technology scaling is robustness of the design, particularly for critical applications (security, medical, finance, etc). Thus, the need for error free or error immune designs. Until recently, radiation effects were a major concern in space applications only. With technology scaling reaching nanometer level, terrestrial radiation has become a growing concern. As a result Single Event Upsets (SEUs) have become a major challenge to robust designs. Single event upset is a temporary change in the state of a device due to a particle strike (usually from the radiation belts or from cosmic rays) which may manifest as an error at the output. This thesis proposes a novel method for adaptive digital designs to efficiently work with the lowest possible power consumption. This new technique improves options in performance, robustness and power. The thesis also proposes a new dual data rate flipflop, which reduces the necessary clock speed by half, drastically reducing the power consumption. This new dual data rate flip-flop design culminates in a proposed unique radiation hardened dual data rate flip-flop, Firebird\u27. Firebird offers a valuable addition to the future circuit designs, especially with the increasing importance of the Single Event Upsets (SEUs) and power dissipation with technology scaling.\u2

Single event upset hardened CMOS combinational logic and clock buffer design

A radiation strike on semiconductor device may lead to charge collection, which may manifest as a wrong logic level causing failure. Soft errors or Single Event Upsets (SEU) caused by radiation strikes are one of the main failure modes in a VLSI circuit. Previous work predicts that soft error rate may dominate the failure rate in VLSI circuit compared to all other failure modes put together. The issue of single event upsets (SEU) need to be addressed such that the failure rate of the chips dues to SEU is in the acceptable range. Memory circuits are designed to be error free with the help of error correction codes. Technology scaling is driving up the SEU rate of combinational logic and it is predicted that the soft error rate (SER) of combinational logic may dominate the SER of unpro-tected memory by the year 2011. Hence a robust combinational logic methodology must be designed for SEU hardening. Recent studies have also shown that clock distribution network is becoming increasingly vulnerable to radiation strike due to reduced capaci-tance at the clock leaf node. A strike on clock leaf node may propagate to many flip-flops increasing the system SER considerably. In this thesis we propose a novel method to improve the SER of the circuit by filtering single event upsets in the combinational logic and clock distribution network. Our ap-proach results in minimal circuit overhead and also requires minimal effort by the de-signer to implement the proposed method. In this thesis we focus on preventing the propagation of SEU rather than eliminating the SEU on each sensitive gate

Single Event Effect Hardening Designs in 65nm CMOS Bulk Technology

Radiation from terrestrial and space environments is a great danger to integrated circuits (ICs). A single particle from a radiation environment strikes semiconductor materials resulting in voltage and current perturbation, where errors are induced. This phenomenon is termed a Single Event Effect (SEE). With the shrinking of transistor size, charge sharing between adjacent devices leads to less effectiveness of current radiation hardening methods. Improving fault-tolerance of storage cells and logic gates in advanced technologies becomes urgent and important. A new Single Event Upset (SEU) tolerant latch is proposed based on a previous hardened Quatro design. Soft error analysis tools are used and results show that the critical charge of the proposed design is approximately 2 times higher than that of the reference design with negligible penalty in area, delay, and power consumption. A test chip containing the proposed flip-flop chains was designed and exposed to alpha particles as well as heavy ions. Radiation experimental results indicate that the soft error rates of the proposed design are greatly reduced when Linear Energy Transfer (LET) is lower than 4, which makes it a suitable candidate for ground-level high reliability applications. To improve radiation tolerance of combinational circuits, two combinational logic gates are proposed. One is a layout-based hardening Cascode Voltage Switch Logic (CVSL) and the other is a fault-tolerant differential dynamic logic. Results from a SEE simulation tool indicate that the proposed CVSL has a higher critical charge, less cross section, and shorter Single Event Transient (SET) pulses when compared with reference designs. Simulation results also reveal that the proposed differential dynamic logic significantly reduces the SEU rate compared to traditional dynamic logic, and has a higher critical charge and shorter SET pulses than reference hardened design

Study of Layout Techniques in Dynamic Logic Circuitry for Single Event Effect Mitigation

Dynamic logic circuits are highly suitable for high-speed applications, considering the fact that they have a smaller area and faster transition. However, their application in space or other radiation-rich environments has been significantly inhibited by their susceptibility to radiation effects. This work begins with the basic operations of dynamic logic circuits, elaborates upon the physics underlying their radiation vulnerability, and evaluates three techniques that harden dynamic logic from the layout: drain extension, pulse quenching, and a proposed method. The drain extension method adds an extra drain to the sensitive node in order to improve charge sharing, the pulse quenching scheme utilizes charge sharing by duplicating a component that offsets the transient pulse, and the proposed technique takes advantage of both. Domino buffers designed using these three techniques, along with a conventional design as reference, were modeled and simulated using a 3D TCAD tool. Simulation results confirm a significant reduction of soft error rate in the proposed technique and suggest a greater reduction with angled incidence. A 130 nm chip containing designed buffer and register chains was fabricated and tested with heavy ion irradiation. According to the experiment results, the proposed design achieved 30% soft error rate reduction, with 19%, 20%, and 10% overhead in speed, power, and area, respectively

Study of Single Event Transient Error Mitigation

Single Event Transient (SET) errors in ground-level electronic devices are a growing concern in the radiation hardening field. However, effective SET mitigation technologies which satisfy ground-level demands such as generic, flexible, efficient, and fast, are limited. The classic Triple Modular Redundancy (TMR) method is the most well-known and popular technique in space and nuclear environment. But it leads to more than 200% area and power overheads, which is too costly to implement in ground-level applications. Meanwhile, the coding technique is extensively utilized to inhibit upset errors in storage cells, but the irregularity of combinatorial logics limits its use in SET mitigation. Therefore, SET mitigation techniques suitable for ground-level applications need to be addressed. Aware of the demands for SET mitigation techniques in ground-level applications, this thesis proposes two novel approaches based on the redundant wire and approximate logic techniques. The Redundant Wire is a SET mitigation technique. By selectively adding redundant wire connections, the technique can prohibit targeted transient faults from propagating on the fly. This thesis proposes a set of signature-based evaluation equations to efficiently estimate the protecting effect provided by each redundant wire candidates. Based on the estimated results, a greedy algorithm is used to insert the best candidate repeatedly. Simulation results substantiate that the evaluation equations can achieve up to 98% accuracy on average. Regarding protecting effects, the technique can mask 18.4% of the faults with a 4.3% area, 4.4% power, and 5.4% delay overhead on average. Overall, the quality of protecting results obtained are 2.8 times better than the previous work. Additionally, the impact of synthesis constraints and signature length are discussed. Approximate Logic is a partial TMR technique offering a trade-off between fault coverage and area overheads. The approximate logic consists of an under-approximate logic and an over-approximate logic. The under-approximate logic is a subset of the original min-terms and the over-approximate logic is a subset of the original max-terms. This thesis proposes a new algorithm for generating the two approximate logics. Through the generating process, the algorithm considers the intrinsic failure probabilities of each gate and utilizes a confidence interval estimate equation to minimize required computations. The technique is applied to two fault models, Stuck-at and SET, and the separate results are compared and discussed. The results show that the technique can reduce the error 75% with an area penalty of 46% on some circuits. The delay overheads of this technique are always two additional layers of logic. The two proposed SET mitigation techniques are both applicable to generic combinatorial logics and with high flexibility. The simulation shows promising SET mitigation ability. The proposed mitigation techniques provide designers more choices in developing reliable combinatorial logic in ground-level applications