基于模态与遗传优化的某卡车振动特性分析

针对汽车驾驶室在常用高速(65～80 km/h)时,驾驶室左右晃动的振动问题,分别建立了车体、车体与板簧的系统模型,通过试验和仿真计算得到了其自由与约束状态下的振动模态分布,找到了驾驶室产生晃动的主要原因.以板簧刚度、车体刚度为变量,将约束模态分析与遗传算法相结合,对板簧和车体组成的系统进行了优化,并通过改进使常用车速下的驾驶室响应达到了舒适性要求.     

基于神经网络的二维随机翼型优化设计方法(英文)

为避免翼型单点优化设计存在的非设计状态气动性能损失,改进对实际飞行环境中不确定性因素的适应能力,提出了基于神经网络的二维随机翼型优化设计方法。采用4个BP神经网络作为代理模型,用于预测翼型的气动系数与几何参数,以提供高效和可靠的分析。同时联合服从正态分布的概率密度函数和遗传算法构成了优化设计方法。采用该方法,对GA(W)-2翼型,在关于马赫数和迎角的二维飞行区域内进行了随机优化设计。通过与原始翼型和单点优化设计翼型的结果对比,表明该二维随机优化方法能够在指定飞行区域内改进翼型的整体性能,提高了翼型对多个飞行参数随机变化的适应能力。     

基因方法在网格结点位置优化中的应用

将基因方法应用于网格结点位置的优化中。文中首先简单介绍了基因优化方法中基于达尔文进化论和Ｍｅｎｄｅｌ基因理论的基本原理,其中包括插索空间表达、三个基因作用器（选择、交配和变异）等要点;然后着重阐述了相关偏微分方程的离散误差和三角形网格几何形状的适应度函数的定义、结点位置的二进制基因表达及基因方法的优化进程。离散误差是在二次非连续彭鼓包（ｂｕｍｐ）函数的空间中近似定义的,并且在点移动过程中相关解的二     

基于形貌优化法的无轴承开关磁阻电机减振降噪

脉振的径向电磁力作为激励源作用于12/8极单绕组宽转子齿无轴承开关磁阻电机（Bearingless switched reluctance motor with wider rotor teeth,BSRMWR）的定子齿面并传送至定子轭部及机壳,会引发较大的振动噪声,阻碍其推广应用。针对这一问题,本文从本体结构的角度入手对电机壳体进行优化改进。采用三维多物理场有限元模型,建立了BSRMWR电磁-结构-振动-声场耦合模型。通过对BSRMWR电磁场进行瞬态分析,得到径向电磁力。将模态应变能方法应用于BSRMWR的壳体得到电机外壳结构有较大的应变能,说明电机壳体结构的薄弱。基于此,通过形貌优化的方法对电机的壳体结构进行优化。结果表明,采用形貌优化后机壳结构的BSRMWR,其振动和噪声均有显著改善。     

纯模态试验中的作动器/传感器优化配置

基于有效独立法,研究了逐步消减法在纯模态试验作动器/传感器优化配置中的应用。对一给定自由度的结构系统,由系统的模态动能可得系统的F isher信息阵。在优化过程中,根据F isher信息阵可得到各自由度节点所对应的E fI值,由E fI值的大小来确定每次要删除的作动器/传感器。在逐步消减的过程中,把E fI的值表示为一个矩阵的形式,使得优化过程清晰明了,提高了优化效率。最后,通过对一个20自由度的离散悬臂梁的激振器布设进行优化,验证了本文方法的有效性。     

关于厚薄板弯曲分析的内位移杂交元法

 本文通过引入单元内位移和优化处理的单元应力场,以计入剪切变形的板弯曲能量泛函为基础,导出适用于厚、薄板分析的四边形杂交应力元。内力场和内位移的合理选择避免了单元零能模式的出现、避免了解的剪切自锁现象。该优化单元显示了较好的通用性和收敛性。对关于剪切自锁的RCI判据提出了反例、说明了它的局限性。     

气动弹性剪裁中的设计变量和约束导数

1.前言 设计变量的取法和约束导数的计算,不但影响气动弹性剪裁的结果,而且决定着它的工作量。本文对于两种不同的设计变量取法进行了讨论。在约束导数计算方面,通过一个盒段模型和一个三角翼模型的计算,进行了对比。     

Landing of the asteroid probe with three-legged cushioning: Planar asymmetric dynamics and safety margin

The probes landing on the surfaces of the asteroids can increase the scientific return of the exploration missions and also promote the development of deep space resources. Because of its excellent applicability to the uneven terrain and a lighter configuration than the four-legged mechanisms, the three-legged cushioning mechanisms are suitable for dissipating the impact energy and then quickly stabilizing the probe attitude when the probe lands on the micro-gravitational surfaces of the asteroids. Research on the landing dynamics of the probe facilitates to the design of the landing-cushioning mechanism and the optimization of its configuration, as well as the assessment of the landing safety. Comparing with the previous extensive related literature focusing on landing dynamics of the probes assisted by the four-legged cushioning mechanisms, this paper studies creatively the planar dynamics considering the asymmetric characteristic and the leg-leg coupling to understand the landing process of the asteroid probe with the three-legged cushioning mechanism and thereby to optimize the configuration of cushioning mechanism and assess safety margin of the landing. According to the touchdown status, the asymmetric landing modes are classified and the coupling issue in the construction of the landing models is explained. Consequently, two types of dynamics models describing the two-stages touchdown cushioning process of the probe are established. Then, five significant configuration factors of the cushioning mechanism are extracted, and their values combinations are designed according to the Taguchi orthogonal method. On this basis, the maximum safe landing attitude angles of the probe are solved by using these values combinations as the input conditions under the dangerous situations in different landing modes. The range analysis and nonlinear fitting methods are employed to discuss the influence of the configuration factors on the landing safety margin, and the favorable parameter values of the configuration factors are determined. Next, the influence of the ground obstacle on the landing safety margin and several methods to improve the margin are researched. Finally, the complete attitude changes of the probe in two representative landing cases are analyzed. The results studied in this paper can contribute to configuration optimization of the three-legged cushioning mechanisms and safety assessment of the legged probes landing on the asteroids, as well as to provide a reference for discussing the leg-leg coupling issue received less attention in landing dynamics of the probes with the four-legged cushioning mechanisms.     

虚拟远海环境的建模与渲染技术

通过分波幅和分相位的扰动算法,改进了基于线性风浪谱的圆滑波峰现象;结合SNE(Synthetic Natural Environment)的浪级、风级、浪高,以及平均周期等信息,实现了与环境结合的风浪可视化算法;综合心理声学和音乐声学等主观声音学科,提出了风浪波谱参数的修正方案,并实现了实时风浪噪音算法的均衡器特性参数与增益调参;采用基于流动纹理的过程着色方案;并将环境纹理镜像化后合并,然后进行景象的高斯模糊;着色后修饰环境图像噪声,提高了适用于海洋景象模拟的纹素质量;实现了基于SNE综合自然环境信息的实时远海视听一体化系统,验证了视听算法的有效性.     

On the different approaches of Rayleigh optical depth determination

Rayleigh optical depth is an integral part of many radiative transfer problems. This paper discusses different elements and approaches of its determination. Then, it presents a method, which ensures more realistic estimate of Rayleigh optical depth by using refractive index and depolarization factor (including rotational Raman lines) adjusted according to the state and composition of the atmosphere. It is based on the published experimental and theoretical results. The Rayleigh optical depth calculations are compared with the Elterman’s model calculations for trend analysis purpose. Rayleigh optical depths are found to be around 3.4% lower than previous researchers, as they ignored the constraints of conservation of angular momentum in the rotational/vibrational transitions of the molecules during scattering.