散装货船模糊综合安全性评估的实现方法

基于模糊数学的理论,将模糊多级综合评判方法运用于散装货船的综合性评估。通过综合分析与模糊化处理影响散装货船安全笥的船舶、船员及环境三方面的各种因素,建立了模糊综合安全性评估的数学库和计算机程序。     

试论标准化管理与铁路运输安全的关联度

从近几年铁路部门发生行车事故原因剖析的视角出发，阐述标准化管理工作与铁路运输安全相互间密不可分的关系，并就标准化管理工作如何紧贴铁道部“高标准、讲科学、不懈怠”要求和保障铁路运输安全，提出具体的对策和措施。     

船舶应变部署表的应用探讨

船舶应变部署表是在紧急情况下保障船舶和人员安全的应急计划,对于保障航行安全和海洋清洁有着重要的作用和意义。文章介绍了国际公约和国内法律对船舶应变部署表的相关规定,阐述了应变部署表的填写规则,分析了应变部署表与船舶安全的关系,并针对船舶安检中发现的应变部署表的常见缺陷,提出了相应的建议和对策。     

铁路计量与安全

结合铁道技术监督工作,从铁路安全的重要关注点、铁道技术监督工作安全的基本要求和保证铁道技术监督工作质量安全的措施3个方面,介绍铁路计量与安全的关系。详细阐述计量与测量的区别和联系,总结铁路计量的特点、主要工作内容和发展方向。     

阿拉山口口岸站货运安全问题的分析及对策

针对阿拉山口站货运作业中存在散堆装货物超载、成件小包装货物超载、集装箱偏载等问题,提出严格执行作业流程,约束和规范装载机械司机的操作行为,消除监控盲区,建立抽检制度、建立超偏载检测装置故障停用应急机制,建立装车前对货件标重检斤的制度,约束国外发货人的行为,保证货物装箱质量等保障货物运输安全的对策。     

基于知识积累的软件运行剖面生成方法及黑箱测试技术

软件的黑箱测试是一个面向用户的软件测试方法，当它以运行剖面为基础生成测试案例时，运行剖面的完备性将直接影响其测试结果的可信性，基于知识积累的软件运行剖面生成方法就是试图通过知识的获取和积累使生成的运行剖面日趋完备，从而达到黑箱测试技术在某些特殊的软件测试领域中更具实用和可信。文章讨论了软件 运行剖面的完备性和软件失效类等概念，提出了一种基于知识各界的软件运行剖面生成广阔圾黑箱测试技术，这种技术现已     

中小型车站Smart2.0系统的方案与安全性分析

作者介绍了适合中小型车站Smart 2.0系统的一种可行方案,通过对该系统安全性的分析,该方案具有结构简单、安全可靠、节约投资等特点。     

京津城际轨道交通防灾安全监控系统简析

本文重点介绍了京津客运专线防灾安全监控系统中的防风预警监测子系统、异物侵限监控子系统的设备组成及实现安全监测、控制列车运行的基本原理。     

基于CarSim自适应巡航控制建模与仿真

文章首先利用模糊法则建立能够反映驾驶员反应时间的隶属度函数,并根据制动过程理论建立安全距离模型,通过安全距离模型建立期望加速度模型。然后分别建立加速和制动模型,在此基础上制定控制模式转换策略,基于PID算法设计巡航控制器。最后在Matlab/Simulink和CarSim联合仿真环境中验证所设计的控制系统的有效性。     

The future of road safety: A worldwide perspective

Estimates by the World Health Organization suggest that, on a yearly basis, road crashes kill 1.25 million people—nearly 3400 road fatalities per day—and injure up to 50 million. Traffic injuries are not equally spread over the world, however; some countries are hit harder than others, and the chance of being killed in a road crash depends on where one lives. Almost 90% of all traffic casualties occur in low- and middle-income countries (LMIC). Globally, the number of fatalities per 100,000 population (mortality rate) ranges from less than 3 to almost 40. The rate is less than 9 in high-income countries (HIC) but averages around 20 in LMIC, with the African region demonstrating the highest rate (26.6). While road safety trends have been positive in HIC over the last few decades, trends in LMIC are not telling a positive story: road fatalities are expected to increase to almost 2 million road fatalities per year by 2020.The United Nations has adopted several resolutions on road safety and proposes actions to tackle the global road safety crisis. Considering the current level of road safety to be unacceptable, the UN has taken several initiatives. One effort, the Decade of Action for Road Safety 2011–2020, has generated substantial activity around the world over the last couple of years. Furthermore, it is very encouraging that the UN included road safety in the Sustainable Development Goals that it laid out in September 2015. Road safety is part of the public health agenda and the urban development agenda. Measured in “real actions,” however, the responses so far from the overall global community and individual countries do not suggest that we are already on the right track to bringing down the death toll on roads.The future of road safety is uncertain and definitely not the same for all regions of the world. Countries with a mature road safety approach and an ambition to make further progress are expected to move in the direction of a pro-active approach: a Safe System approach. It is reported that many LMIC, meanwhile, are on the brink of designing road safety strategies and implementing action plans. The international community is willing to support LMIC, but LMIC cannot simply copy successful HIC strategies because local circumstances differ. The principles of successful HIC strategies are applicable, but the priorities and action plans should take root in and align with local conditions.