Self-healing strategy for transient fault cell reutilization of embryonic array circuit

被引:0
|
作者
Zhang Zhai [1 ]
Qiu Yao [1 ]
Yuan Xiaoliang [1 ]
Yao Rui [1 ]
Wang Youren [1 ]
机构
[1] Nanjing Univ Aeronaut & Astronaut, Coll Automat Engn, Nanjing 211106, Jiangsu, Peoples R China
来源
2018 NASA/ESA CONFERENCE ON ADAPTIVE HARDWARE AND SYSTEMS (AHS 2018) | 2018年
基金
中国国家自然科学基金;
关键词
Bio-inspired hardware; self-healing strategy; transient fault; cell reutilization; embryonic array; SYSTEMS;
D O I
暂无
中图分类号
V [航空、航天];
学科分类号
08 ; 0825 ;
摘要
Self-healing strategy is a key element in designing the embryonic array circuit. However, all existing strategies of embryonics circuit mainly aim at the permanent faults in cell, and lack of research about transient faults. It would be a huge waste of hardware resource if a cell was permanently eliminated due to a minor local transient fault, and the waste will result in seriously low hardware utilization in the sky environment dominated by transient faults that can repaired by reconfiguration mechanism. In this paper, a new self-healing strategy named fault cell reutilization self-healing strategy (FCRSS), which can reuse the transient fault cell, was proposed. In the new strategy, cell elimination and reconfiguration are bound together. In the period of cell elimination process, cells in transparent state due to transient failure can be reconfigured to achieve reutilization. Methods to design of all the modules are described in detail. Circuit simulation and reliability analysis results prove that the FCRSS can increase hardware availability rate and system reliability at the expense of a small amount of hardware and few of reconfiguration time.
引用
收藏
页码:225 / 232
页数:8
相关论文
共 50 条
  • [31] Self-Healing Kirigami Assembly Strategy for Conformal Electronics
    Liu, Jianpeng
    Jiang, Shan
    Xiong, Wennan
    Zhu, Chen
    Li, Kan
    Huang, YongAn
    ADVANCED FUNCTIONAL MATERIALS, 2022, 32 (12)
  • [32] GUIDED RESTORATION STRATEGY FOR ATM SELF-HEALING NETWORKS
    SLOMINSKI, MM
    SAITO, H
    OKAZAKI, H
    HASEGAWA, S
    NEC RESEARCH & DEVELOPMENT, 1995, 36 (04): : 523 - 534
  • [33] Restoration schedule strategy for ATM self-healing network
    Wang, Dongxia
    Dou, Wenhua
    Zhou, Xingming
    Tien Tzu Hsueh Pao/Acta Electronica Sinica, 2000, 28 (08): : 102 - 103
  • [34] Self-Healing Fault Reconstruction Strategy for Island Emergency Power Grid Based on Floyd-MPSO
    Li, Binghong
    Li, Weibo
    Pan, Junfeng
    Luo, Ji
    2022 IEEE/IAS INDUSTRIAL AND COMMERCIAL POWER SYSTEM ASIA (I&CPS ASIA 2022), 2022, : 2096 - 2100
  • [35] A HCI-hardened self-healing operational amplifier circuit
    Zhang, Jun -an
    Hu, Jinxin
    Jiang, Min
    Xiao, Yi
    Li, Tiehu
    Lu, Yunhua
    Zhang, Qingwei
    MICROELECTRONICS RELIABILITY, 2023, 151
  • [36] ATP Simulation hybrid electrode capacitor self-healing circuit
    Kong Zhonghua
    Wu Ligang
    Luo Zaifei
    ADVANCED DESIGN AND MANUFACTURING TECHNOLOGY III, PTS 1-4, 2013, 397-400 : 1893 - 1896
  • [37] The Upset-Fault-Observer: A Concept for Self-healing Adaptive Fault Tolerance
    Navas, Byron
    Oberg, Johnny
    Sander, Ingo
    2014 NASA/ESA CONFERENCE ON ADAPTIVE HARDWARE AND SYSTEMS (AHS), 2014, : 89 - 96
  • [38] Superimposed In-Circuit Debugging for Self-Healing FPGA Overlays
    Kourfali, Alexandra
    Stroobandt, Dirk
    2018 IEEE 19TH LATIN-AMERICAN TEST SYMPOSIUM (LATS), 2018,
  • [39] Comparisons of Self-Healing Fault-Tolerant Computing Schemes
    Tu, Huan-yu
    WORLD CONGRESS ON ENGINEERING AND COMPUTER SCIENCE, VOLS 1 AND 2, 2010, : 87 - 92
  • [40] Self-healing network for scalable fault tolerant runtime environments
    Angskun, Thara
    Fagg, Graham E.
    Bosilca, George
    Pjesivac-Grbovic, Jelena
    Dongarra, Jack J.
    DISTRIBUTED AND PARALLEL SYSTEMS: FROM CLUSTER TO GRID COMPUTING, 2007, : 73 - 80