基于亿门级UltraScale+架构FPGA的单粒子效应测试方法

doi:10.16257/j.cnki.1681-1070.2022.0706

电子与封装 ›› 2022, Vol. 22 ›› Issue (7): 070202 . doi: 10.16257/j.cnki.1681-1070.2022.0706

基于亿门级UltraScale+架构FPGA的单粒子效应测试方法

谢文虎;郑天池;季振凯;杨茂林

无锡中微亿芯有限公司，江苏无锡 ?214072

收稿日期:2021-12-12 出版日期:2022-07-28 发布日期:2022-01-27
作者简介:谢文虎（1988—），男，江西抚州人，硕士，工程师，主要研究方向为SRAM型FPGA测试与应用。

Single Event Effect Testing Method Based on Billion-GateUltraScale+Architecture FPGA

XIE Wenhu, ZHENG Tianchi, JI Zhenkai, YANG Maolin

Wuxi EsiontechCo., Ltd., Wuxi 214072, China

Received:2021-12-12 Online:2022-07-28 Published:2022-01-27

摘要/Abstract

摘要： UltraScale+架构FPGA采用16 nm FinFET工艺，功耗低且性能高，但存在粒子翻转阈值下降及多位翻转增多等风险。基于线性能量传输（LET）等效机理，选取⁷Li³⁺、¹⁹F⁹、³⁵Cl^11,14+、⁴⁸Ti^10,15+、⁷⁴Ge^11,20+、¹²⁷I^15,25+、¹⁸¹Ta、²⁰⁹Bi 8种重离子进行直接电离单粒子试验，建立单粒子闩锁（SEL）、翻转阈值、翻转截面及多位翻转的测定方法。结合LET通量及FinFET结构下的注射倾角，搭建甄别单位翻转及多位翻转的识别算法，能够实时处理并实现粒子翻转状态及多位翻转数据的可视化监控。所涉及的单粒子效应（SEE）分析方法能够较为全面地评估该电路的抗辐照特性。

关键词: FinFET, SRAM型FPGA, 单粒子效应, 多位翻转, 抗辐照测试

Abstract: The UltraScale+ architecture FPGA of 16 nm FinFET process has low power consumption and high performance, but there are risks such as the decrease of single event upset threshold and the increase of multi bit upset. Based on the linear energy transfer (LET) equivalent mechanism, eight heavy ions, namely ⁷Li³⁺, ¹⁹F⁹, ³⁵Cl^11,14+, ⁴⁸Ti^10,15+, ⁷⁴Ge^11,20+, ¹²⁷I^15,25+, ¹⁸¹Ta, ²⁰⁹Bi, are selected for direct ionization single event experiment. The measurement methods of single event latch (SEL), upset threshold, upset section and multi bit upset are established. Combined with the LET flux and the injection angle under the FinFET structure, the recognition algorithm for identifying single bit upset and multi bit upset is built, which can process and realize the visual monitoring of event upset status and multi bit upset data in real time. The single event effect analysis method involved can comprehensively evaluate the irradiation resistance properties of the circuit.

Key words: FinFET, SRAM FPGA, single event effect, multi bit upset, irradiation resistance test

中图分类号:

TN47

谢文虎;郑天池;季振凯;杨茂林. 基于亿门级UltraScale+架构FPGA的单粒子效应测试方法[J]. 电子与封装, 2022, 22(7): 070202 .

XIE Wenhu, ZHENG Tianchi, JI Zhenkai, YANG Maolin. Single Event Effect Testing Method Based on Billion-GateUltraScale+Architecture FPGA[J]. Electronics & Packaging, 2022, 22(7): 070202 .

参考文献

[1] QUINN H, WIRTHLIN M. Validation Techniques for Fault Emulation of SRAM-based FPGAs[J]. IEEE Transactions on Nuclear Science, 2015, 62(4): 1487-1500.
[2] BENFICA J, GREEN B, PORCHER B C, et al. Analysis of SRAM-Based FPGA SEU sensitivity to combined EMI and TID-imprinted effects[J]. IEEE Transactions on Nuclear Science, 2016, 63(2): 1294-1300.
[3] 陈鑫，施聿哲，白雨鑫，等. 单粒子翻转效应的FPGA模拟技术[J]. 电子与封装, 2021, 21(9): 090402.
[4] 于庆奎，王贺，曹爽，等. 空间质子直接和非直接电离引发单粒子效应的地面等效评估试验方法[J]. 航天器环境工程, 2021, 38(3): 351-357.
[5] 张庆祥，于登云，李衍存，等. 基于CYCIAE-100中能质子回旋加速器的单粒子效应敏感度评估[J]. 航天器环境工程, 2020, 37(3): 6.
[6] BLACK J D, BALL II D R, ROBINSON W H, et al. Characterizing SRAM single event upset in terms of single and multiple node charge collection[J]. IEEE Transactions on Nuclear Science, 2008, 55: 2943-2947.
[7] DAVID F H, PAUL W M, JONATHAN A P, et al. Single-event upsets and multiple-bit upsets on a 45 nm SOI SRAM[J]. IEEE Transactions on Nuclear Science, 2009, 56(6): 3499-3504.
[8] DODD P E, MASSENGILL L W. Basic mechanisms and modeling of single-event upset in digital microelectronics[J]. IEEE Transactions on Nuclear Science, 2003, 50(3): 583-602.
[9] 许北燕，郭刚，曾自强，等. 高能电子单粒子效应模拟试验研究[J]. 原子能科学技术, 2019, 53(2): 5.
[10] LEE S, KIM I, HA S, et al. Radiation-induced soft error rate analyses for 14 nm FinFET SRAM devices[J]. 2015 IEEE International Reliability Physics Symposium, 2015: 1-4.
[11] PETERSEN E L, PICKEL J C, ADAMS J H, et al. Rate prediction for single event effects-a critique[J]. IEEE Transactions on Nuclear Science, 1992, 39(6): 1577-1599.
[12] 彭惠薪，刘琳，郑宏超，等. 基于全物理模型的模块级SRAM的SEU仿真方法[J]. 电子技术应用, 2020, 46(6): 4.

中国半导体行业协会封装分会会刊

中国电子学会电子制造与封装技术分会会刊

基于亿门级UltraScale+架构FPGA的单粒子效应测试方法

Single Event Effect Testing Method Based on Billion-GateUltraScale+Architecture FPGA

PDF

可视化

摘要/Abstract

引用本文

使用本文

参考文献

相关文章 7

编辑推荐

Metrics

本文评价

[1]	张景波;朱亚男;彭春雨;赵强. 高可靠性的读写分离14T存储单元设计*[J]. 电子与封装, 2022, 22(1): 10303-.
[2]	陈鑫;施聿哲;白雨鑫;陈凯;张智维;张颖. 单粒子翻转效应的FPGA模拟技术^*[J]. 电子与封装, 2021, 21(9): 90402-.
[3]	张颖,毛志明,陈鑫. 基于静态随机存取存储器型FPGA的测试技术发展^*[J]. 电子与封装, 2021, 21(1): 10204-.
[4]	陈嘉鹏;何威;王威. 一种用于数字电路单粒子效应试验的系统设计[J]. 电子与封装, 2020, 20(11): 110304-.
[5]	金鑫，唐民，于庆奎，张洪伟，梅博，孙毅，唐路平. 粒子入射条件对28 nm SRAM 单元单粒子电荷共享效应影响的TCAD 仿真研究[J]. 电子与封装, 2019, 19(6): 32-40.
[6]	周昕杰，陈　瑶，花正勇，殷亚楠，郭　刚，蔡　丽. TCAD结合SPICE的单粒子效应仿真方法[J]. 电子与封装, 2019, 19(4): 32-35.
[7]	米　丹，左玲玲. 体硅CMOS集成电路抗辐射加固设计技术[J]. 电子与封装, 2016, 16(9): 40-43.