Design of SEL Self-Recovery Hardness for 90nm COTS Devices Using R-C-S Network with DC-DC Converter

2022 IEEE Asia Pacific Conference on Circuits and Systems (APCCAS) Pub Date : 2022-11-11 DOI:10.1109/APCCAS55924.2022.10090280

Jindou Xin, Xiang Zhu, Yingqi Ma, Jianwei Han

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Abstract

An efficient Single Event Latch-up (SEL) self-recovery hardness design using an R-C-S network in the front of a DC-DC converter is proposed in this brief. Conventional SEL hardness assurance is suffering from increased circuit design area and low reliability of the COTS devices. To overcome these problems., the proposed design makes a further contribution to the hardness of SEL. The operational mechanism of the proposed design is that the R-C-S network changes the latch-up voltage of the device through the intrinsic properties of the DC-DC converter. The latch-up voltage is carried through three phases of dropping, oscillation and rising, enabling the device to implement hardness and self-recovery. Meanwhile, simulation and laser tests are employed to demonstrate the validity of the proposed method. Additionally, through comparison with conventional hardness designs of power-off restarting and current limiting by resistor, it is evidently observed that the proposed method has current continuity characteristics and uses 5 components instead of 11 for power-off restarting. And the proposed method effectively exits the device from SEL and reduces the error bits by 72.2% compared to conventional resistor hardness.

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基于R-C-S网络和DC-DC变换器的90nm COTS器件SEL自恢复硬度设计

本文提出了一种有效的单事件锁存(SEL)自恢复硬度设计，该设计采用DC-DC变换器前端的R-C-S网络。传统的SEL硬度保证存在电路设计面积增大和COTS器件可靠性低的问题。克服这些问题。提出的设计对SEL的硬度有进一步的贡献。所提出设计的工作机制是R-C-S网络通过DC-DC变换器的固有特性改变器件的锁存电压。锁存电压经过下降、振荡和上升三个阶段，使装置能够实现硬度和自恢复。同时，通过仿真和激光实验验证了该方法的有效性。此外，通过与传统的断电重启和电阻限流硬度设计的对比，可以明显看出，本文方法具有电流连续性特点，并且使用5个元件而不是11个元件进行断电重启。与传统电阻硬度相比，该方法有效地将器件从SEL中退出，并减少了72.2%的误差位。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2022 IEEE Asia Pacific Conference on Circuits and Systems (APCCAS)

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