On efficient algorithms for finding efficient salvo policies

We consider the salvo policy problem, in which there are k moments, called salvos, at which we can fire multiple missiles simultaneously at an incoming object. Each salvo is characterized by a probability p_i: the hit probability of a single missile. After each salvo, we can assess whether the incoming object is still active. If it is, we fire the missiles assigned to the next salvo. In the salvo policy problem, the goal is to assign at most n missiles to salvos in order to minimize the expected number of missiles used. We consider three problem versions. In Gould's version, we have to assign all n missiles to salvos. In the Big Bomb version, a cost of B is incurred when all salvo's are unsuccessful. Finally, we consider the Quota version in which the kill probability should exceed some quota Q. We discuss the computational complexity and the approximability of these problem versions. In particular, we show that Gould's version and the Big Bomb version admit pseudopolynomial time exact algorithms and fully polynomial time approximation schemes. We also present an iterative approximation algorithm for the Quota version, and show that a related problem is NP-complete.     

Technical note: Finite-time regret analysis of Kiefer-Wolfowitz stochastic approximation algorithm and nonparametric multi-product dynamic pricing with unknown demand

We consider the problem of nonparametric multi-product dynamic pricing with unknown demand and show that the problem may be formulated as an online model-free stochastic program, which can be solved by the classical Kiefer-Wolfowitz stochastic approximation (KWSA) algorithm. We prove that the expected cumulative regret of the KWSA algorithm is bounded above by where κ₁, κ₂ are positive constants and T is the number of periods for any T = 1, 2, … . Therefore, the regret of the KWSA algorithm grows in the order of , which achieves the lower bounds known for parametric dynamic pricing problems and shows that the nonparametric problems are not necessarily more difficult to solve than the parametric ones. Numerical experiments further demonstrate the effectiveness and efficiency of our proposed KW pricing policy by comparing with some pricing policies in the literature.     

应急装备保障多阶段长途运输模型研究

通过对应急装备保障实际场景的分析，提出装备应急运输过程应分2个不同的阶段进行研究。重点讨论了第1阶段涉及的运输问题，并建立相应数学模型。通过数学软件matlab实现了模型的求解，最后通过算例分析证明了模型的有效性。为相关运输问题的解决提供了一种有效的方法。     

高动态GNSS信号多普勒模拟任意阶直接数字合成器设计

为高精度模拟高动态条件下GNSS信号的多普勒特性,提出一种任意阶直接数字合成信号合成器的设计方法。设计任意阶直接数字合成信号合成器的结构;通过理论分析,推导各级累加器相位初值的计算公式;给出字长选择方法。经仿真验证,该方法能精确模拟GNSS信号的多普勒特性。此外,提出的直接数字合成器设计方法不受阶数的限制,可普遍应用于各类信号模拟器的设计。     

弹道导弹威胁估计模型构建

简要分析了弹道导弹飞行3个阶段的不同特点及各阶段导弹预警探测手段的侧重点,结合威胁估计的特征构建了弹道导弹威胁估计模型结构框架,运用多阶段贝叶斯网络理论,构造了主动段、自由段和再入段威胁估计模型,并明确了三阶段间的转换时机。采用动态贝叶斯方法对弹道导弹作战全过程进行威胁估计仿真推理,仿真结果能够反映导弹在飞行过程中威胁程度的变化特点,为反导指挥员作出辅助决策提供智力支持。     

动态滑翔运动建模、机理分析与航迹优化

信天翁凭借动态滑翔的飞行技巧从梯度风中获取能量,从而在几乎不拍翅膀的情况下进行长时间、长距离飞行,这种技巧应用于小型无人机上可拓展其完成任务的能力。基于飞行器动力学对梯度风场中的无人机运动方程进行推导和简化处理;利用简化的运动方程,分别从非惯性参考系中的动能定理和机械能变化的角度,对动态滑翔获取能量的机理进行分析;利用微分平坦法,以最小平均控制输入变化率为目标函数,对徘徊模式和平移模式的动态滑翔航迹进行优化计算。分析结果表明:逆风爬升、顺风下滑是动态滑翔基本获能方式。优化结果表明:控制输入变得更加平滑,甚至出现阶段性的常值,使得控制更加简化;徘徊模式下,当风梯度作为决策变量时,优化过程可在[0,0.5 s-1]的区间上找到使得目标函数值最小的风梯度;平移模式下,目标函数值在该区间上单调递减。     

基于DDS的虚拟信号发生器LabVIEW程序设计

针对传统信号发生器存在的成本高、功能单一、电子线路复杂等缺点,设计了一种基于频率合成技术的虚拟任意信号发生器。通过动态链接库(DLL)与下位机设备DDS-3X25进行通信,基于"模块化"和事件结构的设计思想,用LabVIEW编程实现了基本波形、任意波形、噪声叠加、波形数据载入、波形数据量化转换和线性插值等程序模块。实验结果表明,该设计不仅能产生纯净和叠加噪声的正弦波、方波、三角波和锯齿波等基本波形,而且可以输出手绘的任意波形,验证了设计的有效性。     

“过渡衔接词语”在大学英语短文写作中的作用

短文写作是大学英语四级考试的一个重要组成部分 ,短文写作的成功与否将直接影响到是否通过四级。本文将从三个方面归纳、分析三段式短文中常用的过渡衔接词语在英语短文写作中的“闪光”点作用。旨在帮助学生认识过渡衔接词语的重要性 ,从而提高写作水平     

目的论在翻译理论中的地位

目的论是功能翻译理论的核心思想，它强调的是目的决定手段，它包括译者、文本、语言、文化等为一体的综合性研究。