火控系统最佳采样率问题的研究

先从滤波器和信号的频域特性出发给出了滤波器在频域的采样率匹配原则。第二部分从滤波器预测误差最小的原则出发导出了一组求解最佳采样时间的方程,并给出部分计算结果。第三部分提出了速度平滑处理法,解决了提高采样率引起的速度估计误差增大的矛盾。随后给出了典型航路下,综合各影响因素的模拟跟踪结果,并与“×型”指挥仪的跟踪结果作了分析对比。最后提出了针对不同空中目标的最佳采样率的建议     

基于全局时态逻辑(GTL)的验证和测试生成研究

基于时态逻辑,定义了标准的逻辑操作公式、公理和扩展定理。根据测试生成和验证所要求的初始特性,提出了全局时态逻辑（Global Temporal Logic）GTL,避免了验证和测试中的回溯问题,从而提高验证和测试的效率。另外根据电路节点的扇入和扇出特性,介绍了利用时序线等启发知识来提高搜索策略的方法。     

载人飞船返回段的最优控制

本文介绍空间飞船再入段最优制导方法。纵向制导采用二次型性能指标最优的线性系统,得到最优控制规律。侧向制导利用庞特里亚金最小原理,得到最优开关曲线。结果表明,这些控制规律优于Rodney C.所介绍的制导方法。     

Poisson方程生成数值网格方法中的源项计算法

网格生成是数值研究方法得以实现的基础。本文采用了Ｐｏｉｓｓｏｎ方程生成数值网格，并针对方程源项的选择问题，对两种形式的源项作了比较研究。     

软件构件可靠性与费用分配最优模型

针对软件构件可靠性和费用分配问题,给出一种可靠性和费用分配最优模型。文中将软件系统可靠性定义为软件构件失效密度、操作剖面、构件使用矩阵以及软件无失效运行时间的函数,描述了费用最优模型的建立和利用非线性规划理论求解模型的步骤,有效地处理了带有复杂计算的目标函数和约束条件的可靠性和费用最优分配问题。计算实例表明,利用该模型进行可靠性和费用分配是可行的。     

舰载机回收任务的优化调度算法及仿真

针对舰载机回收过程中,飞行甲板跑道容量的瓶颈问题,比较了几种常见的排序算法,并运用Mat-lab和Lingo软件分别对先来先服务、基于最早到达时刻、滑动窗3种算法进行了计算机仿真。仿真结果表明,滑动窗排序法排序结果最好。最后,指出了滑动窗初始窗口飞机数目和移动步长对算法复杂度和排序结果的影响。     

灭雷具CGF仿人操控行为建模

灭雷具在动力上受海流和电缆的非线性耦合作用力影响,其水下操控十分复杂。针对灭雷具CGF(Computer Generation Force)系统行为建模的需求,建立了简化的四自由度动力学模型,同时考虑了海流和电缆扰动的影响并对缆长和动力分配进行优化计算以实现最优缆长控制和最短路径规划;综合分析了灭雷具水下操控规则,从动力控制和路径规划两个层次来建立其行为规则库,得到了与实际相符的灭雷具智能体仿人操控轨迹。仿真结果表明了该行为模型的正确性和有效性,能较好的满足仿真系统的需求。     

舰炮对岸应召射击最优火力分配

针对舰炮射击特点,分析了海上射击误差,探讨了集群目标的简化处理方法,给出了最优火力分配时表尺差和弹药消耗量计算模型,并进行了举例分析。利用最优火力分配方法来计算舰炮效力射表尺差和弹药消耗量,避免了指挥员战场射击指挥的盲目性,可以在相同弹药消耗量情况下取得最佳射击效果。     

Determination of burn‐in parameters and residual life for highly reliable products

Today, many products are designed and manufactured to function for a long period of time before they fail. Determining product reliability is a great challenge to manufacturers of highly reliable products with only a relatively short period of time available for internal life testing. In particular, it may be difficult to determine optimal burn‐in parameters and characterize the residual life distribution. A promising alternative is to use data on a quality characteristic (QC) whose degradation over time can be related to product failure. Typically, product failure corresponds to the first passage time of the degradation path beyond a critical value. If degradation paths can be modeled properly, one can predict failure time and determine the life distribution without actually observing failures. In this paper, we first use a Wiener process to describe the continuous degradation path of the quality characteristic of the product. A Wiener process allows nonconstant variance and nonzero correlation among data collected at different time points. We propose a decision rule for classifying a unit as normal or weak, and give an economic model for determining the optimal termination time and other parameters of a burn‐in test. Next, we propose a method for assessing the product's lifetime distribution of the passed units. The proposed methodologies are all based only on the product's initial observed degradation data. Finally, an example of an electronic product, namely contact image scanner (CIS), is used to illustrate the proposed procedure. © 2002 Wiley Periodicals, Inc. Naval Research Logistics, 2003     

Exact algorithms for scheduling multiple families of jobs on parallel machines

In many practical manufacturing environments, jobs to be processed can be divided into different families such that a setup is required whenever there is a switch from processing a job of one family to another job of a different family. The time for setup could be sequence independent or sequence dependent. We consider two particular scheduling problems relevant to such situations. In both problems, we are given a set of jobs to be processed on a set of identical parallel machines. The objective of the first problem is to minimize total weighted completion time of jobs, and that of the second problem is to minimize weighted number of tardy jobs. We propose column generation based branch and bound exact solution algorithms for the problems. Computational experiments show that the algorithms are capable of solving both problems of medium size to optimality within reasonable computational time. © 2003 Wiley Periodicals, Inc. Naval Research Logistics 50: 823–840, 2003.