作战飞机可靠性与维修性仿真模型

通过故障树分析建立了作战飞机仿真逻辑关系。在修正线性同余法的基础上获得了随机数模型。在各设备故障发生状态和修复状态识别的基础上,建立了可靠性维修性仿真模型,确定了作战飞机在仿真过程中的工作状态,并根据故障模式影响分析预计了设备故障对作战飞机的影响。最后以F/A-18为例进行可靠性维修性仿真,获得了实时的故障信息和修复信息,验证了仿真模型的可行性。     

蒙特卡洛法的截击空战仿真

针对具体空战环节,应用蒙特卡洛方法仿真了截击空战的全过程,提出了截击空战仿真的程序逻辑方案;并结合具体实例,得出仿真数据,定量分析了空战毁伤概率,进而分析了截击空战的作战效能。仿真结果比较符合实际空战情况,具有一定的创新性和实际应用价值,其分析问题解决问题的方法和过程对解决类似的问题有一定的借鉴意义。     

基于BP神经化贝叶斯网络的空袭目标毁伤效果评估

针对空袭目标毁伤因素的复杂多样性,以及贝叶斯网络在评估时对先验知识获取和对网络节点限制方面存在的不足,提出一种BP神经化贝叶斯网络的评估方法,解决空袭目标的毁伤问题。分析了空袭目标毁伤的影响因素,并进行了知识表示;分析了贝叶斯网络结构处理多个父节点问题时存在的几个缺陷,建立了空袭目标毁伤评估的BP神经化网络结构,给出了"BP神经化模块"的决策方法。通过实例分析,结合Netica仿真,验证了该评估方法的准确性,操作简单、有效性好。     

有限维修能力下作战单元时变可用度评估模型

针对作战单元任务期内备件需求随任务阶段动态变化的现实情况,考虑作战单元因携行维修能力有限而导致可修件具有一定报废概率的影响,通过引入报废因子,建立两级保障体制下,故障件具有一定报废概率且不考虑外部补给的作战单元时变可用度评估模型。采用Extend Sim仿真软件进行计算,根据仿真值进行参数拟合得到模型中报废因子的近似解析表达形式。研究表明,报废因子能够适应不同的可靠性维修性参数值,模型具有较强的适应性。该模型有效解决了备件非平衡状态下的装备时变可用度评估问题,可为装备管理人员制定合理的保障方案提供支撑。     

复杂电磁环境中水面舰艇作战效能评估的指数模型

复杂电磁环境中水面舰艇作战效能评估对于信息化海战场中水面舰艇兵力的战术运用极为重要,目前还处于一个探索阶段.分析了复杂电磁环境对舰艇装备的作用机理和对舰艇作战活动的影响,建立了效能评估指标体系,针对复杂电磁环境对武器装备作战效能的影响难以定量描述的问题,提出了复杂电磁环境作战效能影响因子这一概念,研究了其求解方法,在此基础上,采用指数法构造了复杂电磁环境中水面舰艇作战效能评估模型,并通过仿真验证了其可用性.     

潜艇通信方式与现状及激光对潜通信的地位和作用

以超短波潜对岸通信和超长波岸对潜通信为基础,概述了激光通信的发展、激光传输的特性、激光器件特性和接收滤光器特性及其发展动向。     

软件工程在模拟潜艇指控台上的应用

介绍了模拟潜艇指控台在军事应用软件的计划与开发过程中所面临的各种困难,提出并采用了软件工程设计的方法来解决此类问题的思路与方法。     

正规战中作战效率变化初探

本文以描述常规战最基本的模型——Lanchester方程为基础,就影响作战效率的一些因素进行了分析并定量化地表现在作战模型中,然后运用有关系统学理论讨论了作战效率变化对战斗进程的影响程度。     

A model for geographically distributed combat interactions of swarming naval and air forces

This article describes the Distributed Interaction Campaign Model (DICM), an exploratory campaign analysis tool and asset allocation decision‐aid for managing geographically distributed and swarming naval and air forces. The model is capable of fast operation, while accounting for uncertainty in an opponent's plan. It is intended for use by commanders and analysts who have limited time for model runs, or a finite budget. The model is purpose‐built for the Pentagon's Office of Net Assessment, and supports analysis of the following questions: What happens when swarms of geographically distributed naval and air forces engage each other and what are the key elements of the opponents’ force to attack? Are there changes to force structure that make a force more effective, and what impacts will disruptions in enemy command and control and wide‐area surveillance have? Which insights are to be gained by fast exploratory mathematical/computational campaign analysis to augment and replace expensive and time‐consuming simulations? An illustrative example of model use is described in a simple test scenario. © 2016 Wiley Periodicals, Inc. Naval Research Logistics 63: 562–576, 2016     

Analysis of artillery shoot‐and‐scoot tactics

Firing multiple artillery rounds from the same location has two main benefits: a high rate of fire at the enemy and improved accuracy as the shooter's aim adjusts to previous rounds. However, firing repeatedly from the same location carries significant risk that the enemy will detect the artillery's location. Therefore, the shooter may periodically move locations to avoid counter‐battery fire. This maneuver is known as the shoot‐and‐scoot tactic. This article analyzes the shoot‐and‐scoot tactic for a time‐critical mission using Markov models. We compute optimal move policies and develop heuristics for more complex and realistic settings. Spending a reasonable amount of time firing multiple shots from the same location is often preferable to moving immediately after firing an initial salvo. Moving frequently reduces risk to the artillery, but also limits the artillery's ability to inflict damage on the enemy.