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121.
刘庆永 《中国人民武装警察部队学院学报》2011,(10):50-51
根据西藏文物古建筑历年来典型火灾事故原因和火灾危险源分布,针对消防安全管理工作,提出了加强火灾危险源管理和控制的措施、手段。 相似文献
122.
介绍了目前大中型医院广泛采用的医用制氧机系统供氧原理和特性,分析了其火灾危险性,并与液氧储罐供氧系统进行了对比,提出了消防设计的具体要求。 相似文献
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以战时交通运输路径优化问题为研究对象,分析问题特点,考虑多式联运,以运输时间代价、运输费用代价、路段和运输节点的危险性代价为优化目标,建立起广义运输代价最小的运输路径优化模型,并设计了蚁群算法来求解问题模型。给出的算例表明,文中模型符合战时交通运输的特点和实际需要,可为确定战时运输路径提供决策支持,而采用的蚁群算法是求解该问题的一种有效方法。 相似文献
124.
郭艳丽 《中国人民武装警察部队学院学报》2006,22(6):18-21
分析了液态烃泵在设计制造、密封失效、静电危害、安全管理等方面存在的火灾危险性,并从密封技术的改进、泵结构的改造、生产操作安全规程的制定和实施等方面探讨其预防对策,为石油化工行业液态烃泵的安全使用和消防技术管理工作提供参考依据。 相似文献
125.
The deterministic problem for finding an aircraft's optimal risk trajectory in a threat environment has been formulated. The threat is associated with the risk of aircraft detection by radars or similar sensors. The model considers an aircraft's trajectory in three‐dimensional (3‐D) space and represents the aircraft by a symmetrical ellipsoid with the axis of symmetry directing the trajectory. Analytical and discrete optimization approaches for routing an aircraft with variable radar cross‐section (RCS) subject to a constraint on the trajectory length have been developed. Through techniques of Calculus of Variations, the analytical approach reduces the original risk optimization problem to a vectorial nonlinear differential equation. In the case of a single detecting installation, a solution to this equation is expressed by a quadrature. A network optimization approach reduces the original problem to the Constrained Shortest Path Problem (CSPP) for a 3‐D network. The CSPP has been solved for various ellipsoid shapes and different length constraints in cases with several radars. The impact of ellipsoid shape on the geometry of an optimal trajectory as well as the impact of variable RCS on the performance of a network optimization algorithm have been analyzed and illustrated by several numerical examples. © 2006 Wiley Periodicals, Inc. Naval Research Logistics, 2006 相似文献
126.
把AHP(Analytic H ierarchy Process)方法运用于装备研制项目风险分析,实现了风险因素的排序、系统总风险的评价以及风险响应措施的选择。在风险发生概率和风险损失的基础上,将风险因素的可控制性和用户满意度风险也同时作为风险判断准则,使得风险的评价更合理、更准确地反映项目实际。最后给出了风险因素排序及风险响应措施选择的应用实例。 相似文献
127.
讨论了广生灭过程的积分型随机泛函的概率分布,给出了分布的拉氏变换所满足的差分方程,且求出了它们的解 相似文献
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129.
Stephen J. Cimbala 《Defense & Security Analysis》2017,33(1):57-67
Deterioration in security relations as between NATO and Russia reached boiling point in the aftermath of Russia’s annexation of Crimea in 2014 and its subsequent destabilization of Eastern Ukraine. As a result, some voices in the West look forward to the departure of Vladimir Putin from power, and others to the possible disintegration of Russia as a unitary state. However, both the departure of Putin and the collapse of Russia have a nuclear dimension. Putin has issued pointed reminders of Russia’s status as a nuclear great power, and Russian military doctrine allows for nuclear first use in the event of a conventional war with extremely high stakes. Beyond Putin, a breakup of Russia would leave political chaos in Eastern Europe, Central Asia and elsewhere, inviting ambiguous command and control over formerly Russian nuclear forces. 相似文献
130.
A mathematical model of portfolio optimization is usually represented as a bicriteria optimization problem where a reasonable tradeoff between expected rate of return and risk is sought. In a classical Markowitz model, the risk is measured by a variance, thus resulting in a quadratic programming model. As an alternative, the MAD model was developed by Konno and Yamazaki, where risk is measured by (mean) absolute deviation instead of a variance. The MAD model is computationally attractive, since it is easily transformed into a linear programming problem. An extension to the MAD model proposed in this paper allows us to measure risk using downside deviations, with the ability to penalize larger downside deviations. Hence, it provides for better modeling of risk averse preferences. The resulting m‐MAD model generates efficient solutions with respect to second degree stochastic dominance, while at the same time preserving the simplicity and linearity of the original MAD model. © 2001 John Wiley & Sons, Inc. Naval Research Logistics 48: 185–200, 2001 相似文献