Safety Design and Implementation of FAO Automatic Wake-up Function Based on FMEA#br#

doi:10.3969/j.issn.1673-4440.2024.06.014

Railway Signalling & Communication Engineering ›› 2024, Vol. 21 ›› Issue (6): 84-88,95.DOI: 10.3969/j.issn.1673-4440.2024.06.014

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Safety Design and Implementation of FAO Automatic Wake-up Function Based on FMEA#br#

Jia Jia

Beijing Urban Construction Design & Development Group Co., Ltd., Beijing 100037, China

Received:2023-05-19 Revised:2024-04-10 Online:2024-06-25 Published:2024-06-25

基于FMEA的FAO自动唤醒功能安全设计与实现

贾佳

北京城建设计发展集团股份有限公司，北京 100037

作者简介:贾佳（1985—），女，工程师，硕士，主要研究方向：轨道交通系统RAMS，邮箱：jiajia1@bjucd.com。

Abstract

Abstract: In this paper, an in-depth study is conducted regarding the train automatic wake-up function of fully automatic driverless trains using FMEA method. The study analyzes the failure modes that may produce dangerous consequences, identifies their corresponding failure causes, and designs appropriate safety measures based on these failure modes and causes. This approach ensures that the fully automatic unmanned driving system reduces the original risks of the system, as well as the risks caused by new functions, to an acceptable degree, and achieves safe and reliable operation.

Key words: FAO, automatic wake-up, safety analysis, safety design, FMEA

摘要： 采用FMEA的分析方法对全自动无人驾驶列车自动唤醒功能进行深入研究，分析可能产生危险后果的失效模式以及对应的失效原因，并结合失效模式和失效原因设计相应的安全措施，保证全自动无人驾驶系统将系统原有风险以及新增功能引发的风险均减轻至可接受程度，真正实现安全可靠的运行。

关键词: 全自动无人驾驶, 自动唤醒, 安全分析, 安全设计, FMEA

CLC Number:

U284.48

Jia Jia. Safety Design and Implementation of FAO Automatic Wake-up Function Based on FMEA#br#[J]. Railway Signalling & Communication Engineering, 2024, 21(6): 84-88,95.

贾佳. 基于FMEA的FAO自动唤醒功能安全设计与实现[J]. 铁路通信信号工程技术, 2024, 21(6): 84-88,95.

Figures/Tables 3

References

[1]国家质量监督检验检疫总局，中国国家标准化管理委员会.系统可靠性分析技术失效模式和影响分析：GB/T 7826-2012[S].北京:中国标准出版社，2013.
[2]国家质量监督检验检疫总局，中国国家标准化管理委员会.电气/电子/可编程电子安全相关系统的功能安全第1部分:一般要求:GB/T 20438.1-2017[S].北京:中国质检出版社，2017.
[3]文峥，吴卫平，路向阳.城市轨道交通全自动无人驾驶系统国际标准研究[J].控制与信息技术，2023（2）：85-89.
Wen Zheng, Wu Weiping, Lu Xiangyang. Research on the International Standards of Fully Automatic Operation System in Urban Rail Transit[J]. Control and Information Technology, 2023(2): 85-89.
[4]薛巧丽，杨海鹏.基于FMEA的城市轨道交通信号系统与站台门系统接口危害分析[J].控制与信息技术，2023（1）：101-106.
Xue Qiaoli, Yang Haipeng. Interface Hazard Analysis between Urban Rail Signal System and Platform Screen Door System Based on Functional FMEA[J]. Control and Information Technology, 2023(1): 101-106.
[5]姚媛，唐涛，吕继东，等.基于HAZOP的列控系统安全分析与验证[J].铁道通信信号，2016，52（3）：50-53.
Yao Yuan, Tang Tao, Lu Jidong, et al. Safety Analysis and Confirmation of HAZOP-Based Train Control System[J]. Railway Signalling & Communication, 2016, 52(3): 50-53.
[6]郑鸿昌，张涛，何敏学.无人驾驶信号系统中休眠和唤醒功能的设计[J].电声技术，2018，42（6）：51-52，57.
Zheng Hongchang, Zhang Tao, He Minxue. The Design of the Dormancy and Wake-up Function of UGTMS[J]. Audio Engineering, 2018, 42(6): 51-52, 57.
[7]丰文胜，王永星，薛强.轨道交通全自动无人驾驶场景的新功能需求[J].铁道通信信号，2020，56（2）：83-85.
Feng Wensheng, Wang Yongxing, Xue Qiang. New Function Requirement of Completely Automatic Driverless Operation Scenarios in Rail Transi[J]. Railway Signalling & Communication, 2020, 56(2): 83-85.
[8]冯晶玮，赵红芳.ZPW-2000G型无绝缘轨道电路系统安全分析与验证[J].铁路通信信号工程技术，2022，19（S1）：80-84.
Feng Jingwei, Zhao Hongfang. Safety Analysis and Verification of ZPW-2000G Jointless Track Circuit System[J]. Railway Signalling & Communication Engineering, 2022, 19(S1): 80-84.
[9]张坤，张豪.全自动驾驶列车唤醒逻辑流程阐述与分析[J].现代城市轨道交通，2023（12）：46-50.
Zhang Kun, Zhang Hao. Explanation and Analysis of the Wake-up Logic Flow of Fully-Automated Operation Trains[J]. Modern Urban Transit, 2023(12): 46-50.
[10]闫宏伟，燕飞.城市轨道交通全自动运行系统及安全需求[J].都市快轨交通，2017，30（3）：50-55，87.
Yan Hongwei, Yan Fei. Fully Automatic Operation System and Its Safety Requirement of Urban Rail Transit[J]. Urban Rapid Rail Transit, 2017, 30(3): 50-55, 87.
[11]武长海.城市轨道全自动无人驾驶技术应用探讨[J].铁路通信信号工程技术，2016，13（5）：54-58.
Wu Changhai. Application of Full Automatic Driverless Technology in Urban Rail Transit[J]. Railway Signalling & Communication Engineering, 2016, 13(5): 54-58.
[12]宋传龙.基于CBTC控制的列车全自动驾驶系统(FAO)的发展及应用[J].电子世界，2014（3）：31-32.
[13]彭懿.列车全自动驾驶系统休眠唤醒子系统可靠性研究[D].南京:南京理工大学，2020.
[14]陈宁宁，张琦，郜洪民，等.城市轨道交通列车全自动运行系统的列车唤醒休眠方法研究[J].城市轨道交通研究，2022，25（4）：160-164.
Chen Ningning, Zhang Qi, Gao Hongmin, et al. Research on Train Wake-up and Sleep Method of Urban Rail Transit FAO System[J]. Urban Mass Transit, 2022, 25(4): 160-164.
[15]刘海涛，王雨婷.全自动驾驶车辆休眠逻辑说明[J].数字通信世界，2021（1）：123-124，205.
[16]范晓栋.全自动驾驶系统列车正线休眠唤醒区域全覆盖的研究[J].城市轨道交通研究，2020，23（11）：166-168.
Fan Xiaodong. Research on Train Main Line Dormancy and Awakening Area Full Coverage in Fully Automatic Driving System[J]. Urban Mass Transit, 2020, 23(11): 166-168.
[17]冯玮.城市轨道交通全自动运行列车休眠与唤醒的执行方式[J].城市轨道交通研究，2019，22（S2）：106-108.
[18]戴成岩，邱兆阳.FMEA在铁路信号安全产品配置数据安全分析中的应用[J].铁路通信信号工程技术，2019，16（11）：13-16，43.
Dai Chengyan, Qiu Zhaoyang. Application of FMEA in Safety Analysis of Railway Signal Safety Product Configuration Data[J]. Railway Signalling & Communication Engineering, 2019, 16(11): 13-16, 43.
[19]付文佳，韩涛，刘倩，等.基于场景的全自动运行系统安全分析方法[J].铁路通信信号工程技术，2023，20（12）：83-87.
Fu Wenjia, Han Tao, Liu Qian, et al. Scenario-Based Safety Analysis Method for Fully Automatic Train Operation Systems[J]. Railway Signalling & Communication Engineering, 2023, 20(12): 83-87.

Safety Design and Implementation of FAO Automatic Wake-up Function Based on FMEA#br#

基于FMEA的FAO自动唤醒功能安全设计与实现

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