基于离散等价方程的非结构网格有限差分法

激波装配法把解析关系式嵌入流场避免了间断引起的理论问题，使全场一致高精度的实现成为可能，有望解决超声速流动转捩研究中的感受性模拟难题。但装配复杂激波结构以后，被分割的流场空间常出现不规则的几何形状，这给常规的基于结构网格的有限差分法应用带来困难。基于离散等价方程理论，提出了一种新的基于非结构网格的有限差分法，在空间二维离散点附近仅用3条网格线就可以构造出一阶迎风格式。数值算例表明收敛过程对网格质量不敏感，解决了激波装配法模拟激波相交出现小夹角后使用结构网格进行计算存在的难题。根据这种方法的特点展望了未来的应用前景。     

非结构混合网格自适应并行技术

计算流体力学（CFD）模拟实际工程问题所采用的网格规模可达千万量级，并行技术是减少计算时间的有效方法。耦合流场信息的网格自适应技术能有效动态优化计算网格，被NASA视为一项亟待发展的CFD关键技术。混合网格自适应系统包含网格分布优化、表面网格投影和空间网格匹配等关键技术。针对以上3项关键技术分别建立了高效的并行算法。首先，提出了"先唯一后同一"的两步法策略实现了网格单元分布优化过程的并行相容性；其次，基于局部曲面拟合思想，实现了曲面重构和新增物理网格点投影的完全并行；再次，提出了空间网格匹配技术的半并行算法，快速解决了网格单元交错问题。为了提高后续流场计算的并行效率，发展了基于并行重分区-网格数据迁移方法的动态负载平衡技术，并采用圆柱激波流场自适应模拟对动态负载平衡技术进行初步验证。最后，采用三角翼自适应加密测试了自适应系统的并行效率。结果表明，建立的混合网格自适应系统并行效率较高，且相比流场求解耗费总时间的比例低于1%。     

一类二维非结构网格DSMC方法的实现策略及其应用

研究了一类二维非结构网格DSMC方法的实现策略。在数据结构方面，设计了局部化的数据组织方式，节约了内存与计算时间。发展了一种跟踪模拟分子迁移的算法，该算法仅需少量的逻辑运算与代数运算，不仅可以快速跟踪模拟分子在网格之间的迁移，而且可以准确判别分子与物面是否相互作用，搜索过程中的附带信息给出了分子与物面碰撞的精确时间与位置，避免了重新计算。引入碰撞距离的思想，既减少存储又保证正确的模拟结果。在程序编制过程中，我们充分展现了Fortran90高级语言的主要特性，引入动态数组、指针、链表以及派生类型数据，编制了计算程序。最后对过渡流域高超声绕流进行了数值试验。     

非结构网格上欧拉方程的自适应逆风隐式有限元解法

本文发展了一种解二维欧拉方程的隐式逆风有限元格式。空间近似应用的是二阶精度逆风方法；时间近似上根据数值通量函数的线性化处理导出了有限元的隐格式。为减少数值振荡，引入了基于特征变量的限制因子。在经自适应处理的非结构网络上，本文对跨、超、高超声速绕流进行了数值模拟。计算实践表明发展的隐式有限元格式与显格式相比具有较高的计算效率和较强的适应性。     

规划未来 塑造自我

通过对有关大学生心理困惑方面的问卷调查分析,笔者发现目前大学生在学习生活中存在着很大的盲目性,解决问题的出路之一是把握学年特点,根据自己的实际情况,作出合理规划,并付诸实践。     

F-22未能成为舰载战斗机原因浅析

从经济可承受性、进度、海上作战需求和航母适配性等方面，论述F-22未能成为舰载战斗机的原因。     

A critical evaluation of two Reissner–Mindlin type models for composite laminated plates

The purpose of this paper is to critically evaluate two Reissner–Mindlin type theories developed recently for composite laminated plates, namely, VAPAS (Variational Asymptotic Plate And Shell analysis) and EFSDT (Enhanced First-Order Shear-Deformation Theory). The fundamentals of both models are briefly summarized along with their unique features in comparison to most other existing models. The similarities and differences between VAPAS and EFSDT are also examined. Exact solutions of three-dimensional elasticity theory for the cylindrical bending problems are used as the arbiter to assess the accuracy of both models. Such a systematic assessment demonstrates that both models have achieved an excellent compromise between the layer-wise theories, which are accurate but computationally demanding, and the first-order shear deformation theories, which are computationally cheap but not accurate.     

A mesh optimization method using machine learning technique and variational mesh adaptation

Computational mesh is an important ingredient that affects the accuracy and efficiency of CFD numerical simulation. In light of the introduced large amount of computational costs for many adaptive mesh methods, moving mesh methods keep the number of nodes and topology of a mesh unchanged and do not increase CFD computational expense. As the state-of-the-art moving mesh method, the variational mesh adaptation approach has been introduced to CFD calculation. However, quickly estimating the flow fi...     

Aeroacoustic and aerodynamic optimization of propeller blades

It is of great significance to develop a high-efficiency and low-noise propeller optimization method for new-generation propeller aircraft design. Coupled with free form deformation method, dynamic mesh interpolation technology, optimization algorithm, surrogate model, aerodynamic calculation and aeroacoustic prediction model module, the integrated aerodynamic and aeroacoustic design method of propeller is built. The optimization design for the six-blade propeller is carried out. The non-reduction in efficiency, thrust coefficient and the minimum of aerodynamic noise is treated as the optimization design objective. The spatial vorticity distribution of the propeller before and after the design is also analyzed by using unsteady computational fluid dynamics method. The results show that the optimized propeller can effectively reduce the aerodynamic noise level. The maximum total sound pressure level can be reduced by 5 dB without reducing its aerodynamic performance. The developed method has good application potential in low-noise optimization design of propeller and other rotating machinery.     

基于CFD数值仿真技术的飞行器动导数计算

为了研究表征飞行器动态稳定特性的动导数,结合计算流体力学方法,基于滑移网格技术,采用小幅度强迫振动法和差分法两种非定常方法,推导了俯仰组合动导数以及滚转阻尼导数的计算表达式,并结合多参考系模型采用准定常方法计算滚转阻尼导数。建立了基于计算流体力学技术的飞行器动导数计算方法。对国际动导数标模Finner导弹进行了计算验证。两种非定常方法对俯仰组合动导数的计算误差分别为0.65%、6.13%,对滚转阻尼导数的计算误差分别为2.5%、0.06%。求解滚转阻尼的准定常方法对于滚转阻尼导数的计算误差为2.67%。三种方法的计算结果与风洞试验结果吻合的很好。非定常方法计算精度高,准定常方法可以快捷迅速得到结果。本文的数值方法不仅适用于超声速,同样可以用于亚、跨声速时的动导数计算。