基于引力搜索算法的漏磁缺陷重构

缺陷重构,即从漏磁信号反演出铁磁性材料的缺陷轮廓或几何参数,是漏磁无损评估中的一个重要研究方向。针对缺陷漏磁信号特征及缺陷轮廓特征的复杂性,提出基于引力搜索算法的漏磁缺陷重构方法。依据磁偶极子模型理论分析提取实测漏磁信号有效信息段,径向基函数神经网络作为前向模型,引力搜索算法作为迭代算法,利用其在高维解空间中避免陷入局部最优的能力,得到最优缺陷轮廓,实现缺陷重构。仿真和实验结果表明,基于引力搜索算法的缺陷重构方法能提高重构精度和效率,具有较高的实用价值。     

基于BIST的3D SRAM中TSV开路测试算法研究与实现

基于3D-IC技术实现的3D SRAM,其电路中使用了大量的TSV。目前TSV制造工艺尚未成熟,使得TSV容易出现开路或短路故障,从而给3D SRAM的测试带来新的挑战。现有的2D BIST测试方式能够探测到3D SRAM中存在的故障,但并不能判定是TSV故障还是存储器本身故障；TSV专用测试电路虽然能够探测出TSV的故障,但需要特定的测试电路来实现,这就增加了额外的面积开销,同时加大了电路设计复杂度。基于此,本文提出了一种使用测试算法来探测TSV开路故障的方法,在不使用TSV专用测试电路且不增加额外面积开销的情况下通过BIST电路解决3D SRAM中TSV的开路故障检测问题。结果显示该TSV测试算法功能正确,能够准确探测到TSV的开路故障,并快速定位TSV的开路位置。     

天地测控资源调度的两阶段递进遗传算法

为对天地测控资源调度进行高效求解,设计了两阶段递进遗传算法对其进行优化调度。鉴于问题的目标具有一定的可分性,以时间为依据将被调度弧段划分成两个部分,在对第一部分形成种群并作进化求解的基础上,将其最优解与第二部分弧段组合,并作进一步的进化求解。为了缓解两阶段优化的局部搜索特性,在第一阶段个体适应度计算中,以一定概率设定虚拟弧段,保留具有潜在全局优势的个体。仿真表明该方法能在确保求解质量的前提下明显减少运算时间。     

任务空间概念模型VV&A研究

任务空间概念模型是现实世界军事知识的第一层抽象,是仿真系统开发的业务基础。所以任务空间概念模型的质量直接影响到仿真系统的质量,任务空间概念模型自身的VV&A是一个非常值得关注的问题。任务空间概念建模本质上看是军事领域的知识表示或者需求描述,定性描述占主要,定量成分非常少。因此,传统的通过分析输出数据的方法不能适应任务空间概念模型的特点。概要介绍了任务空间概念模型建模,并且提出了从专家法、静态校核机制、概念执行机制三个角度来考察模型质量的思路。     

云模型及其在指挥控制系统可靠性分析中的应用

根据指挥控制系统的特点及作战应用的具体情况,从指挥控制系统的可靠性出发,提出了适合指控系统可靠性分析的云模型。通过拟定性能评价指标,导出各指标的云模型及其多维加权综合云的重心,应用云重心评价方法进行分析;并通过案例,运用基于PC-L INM AP的云重心评价方法,以影响指挥控制系统可靠性的两个重要性能指标为依据,分析了未来联合作战中指挥控制系统的可靠性,比较贴近作战实际,可信度较高。     

基于自适应小波正交基神经网络的参数辨识

提出了一种基于小波正交基神经网络的非线性在线辨识方法.小波变换具有良好的收敛速度和逼近精度,神经网络具有强大的非线性映射能力、自学习、自适应等优势,采用正交基小波函数作为神经网络的基函数构成小波神经网络,该网络兼有小波函数和神经网络的优点;制导航弹数字仿真结果表明, 该方法对含噪声数据进行处理效果好,能很好地满足非线性在线辨识的需求.     

如何改善路径测试用例生成的搜索算法

软件结构测试数据生成一直是软件测试领域一个较为复杂的问题,方法和手段尚未成熟。基于程序直接执行的测试数据生成方法因其动态性,显示出一定的优越性,本文主要针对该方法的核心部分——搜索算法进行讨论,探讨了有助于改善其功能的若干手段,目的在于提高算法效率,提高其实用化程度,显示出较好的实验效果。     

海战场态势评估问题的研究

对海战场综合态势进行态势评估和威胁分析是信息融合系统的最高层级,态势评估结果将对指挥员的指挥决策起到非常重要的作用。根据海军作战理论分析了海战场态势的表示方法,并基于模板方法设计了一种战场当前态势与模板数据库中态势进行匹配的算法。该算法特别适用于高层推理如态势或威胁评估。     

Optimal pricing and inventory control policy in periodic‐review systems with fixed ordering cost and lost sales

This paper studies a periodic‐review pricing and inventory control problem for a retailer, which faces stochastic price‐sensitive demand, under quite general modeling assumptions. Any unsatisfied demand is lost, and any leftover inventory at the end of the finite selling horizon has a salvage value. The cost component for the retailer includes holding, shortage, and both variable and fixed ordering costs. The retailer's objective is to maximize its discounted expected profit over the selling horizon by dynamically deciding on the optimal pricing and replenishment policy for each period. We show that, under a mild assumption on the additive demand function, at the beginning of each period an (s,S) policy is optimal for replenishment, and the value of the optimal price depends on the inventory level after the replenishment decision has been done. Our numerical study also suggests that for a sufficiently long selling horizon, the optimal policy is almost stationary. Furthermore, the fixed ordering cost (K) plays a significant role in our modeling framework. Specifically, any increase in K results in lower s and higher S. On the other hand, the profit impact of dynamically changing the retail price, contrasted with a single fixed price throughout the selling horizon, also increases with K. We demonstrate that using the optimal policy values from a model with backordering of unmet demands as approximations in our model might result in significant profit penalty. © 2005 Wiley Periodicals, Inc. Naval Research Logistics, 2006     

Algorithms for the multi‐item multi‐vehicles dynamic lot sizing problem

We consider a two‐stage supply chain, in which multi‐items are shipped from a manufacturing facility or a central warehouse to a downstream retailer that faces deterministic external demand for each of the items over a finite planning horizon. The items are shipped through identical capacitated vehicles, each incurring a fixed cost per trip. In addition, there exist item‐dependent variable shipping costs and inventory holding costs at the retailer for items stored at the end of the period; these costs are constant over time. The sum of all costs must be minimized while satisfying the external demand without backlogging. In this paper we develop a search algorithm to solve the problem optimally. Our search algorithm, although exponential in the worst case, is very efficient empirically due to new properties of the optimal solution that we found, which allow us to restrict the number of solutions examined. Second, we perform a computational study that compares the empirical running time of our search methods to other available exact solution methods to the problem. Finally, we characterize the conditions under which each of the solution methods is likely to be faster than the others and suggest efficient heuristic solutions that we recommend using when the problem is large in all dimensions. © 2005 Wiley Periodicals, Inc. Naval Research Logistics, 2006.