云中基于蚁群算法改进的负载均衡策略

针对云计算虚拟化资源中,提高资源利用率、负载均衡度的问题,在蚁群算法的基础上,提出云中节点间负载均衡的改进算法。前向蚂蚁检测节点的类型、记录节点信息,遇到负载节点时留下觅食信息素;后向蚂蚁依据循迹信息素追溯回负载节点,合理分配超载节点任务。所有蚂蚁不再更新自己的结果集,而是致力于更新单个结果集,在搜索过程中依据节点类型动态地修改路径信息素。在Cloudsim平台下进行的仿真实验验证了改进算法的有效性。     

尖晶石型铁酸镉纳米粉体的超声化学法合成

超声波辐射下前驱体法合成了纳米铁酸镉（CdFe2O4）粉末。以硝酸镉、硝酸铁和脲为原料用超声化学法制得前驱体，再在950℃焙烧15h，得到平均粒径约56nm的铁酸镉粉末。得到的纳米铁酸镉粉末用X射线衍射（XRD）、扫描电镜（SEM）、傅里叶转换红外光谱（FT—IR）进行表征并得到确认，用样品振动磁强计（VSM）对其磁学参数进行了测定。     

聚醚型聚氨酯增强增韧环氧树脂的研究

用聚丙二醇(PPG400,PPG1000)与异佛尔酮二异氰酸酯(IPDI)反应制备了聚氨酯(PU)预聚体,然后通过与环氧树脂(EP)的加成反应和环氧树脂的固化反应将聚氨酯引入环氧固化物网络,并研究了两种聚醚型聚氨酯对环氧树脂的改性效果。结果发现,聚氨酯的引入不但起到了增韧的作用,而且使体系的强度有了很大的提高。随聚氨酯用量增大,PU/EP材料拉伸强度、弯曲强度、冲击强度均先增大后减小,过多的聚氨酯用量导致其不能接人环氧固化物网络;分子链较短的PPG400型聚氨酯的改性效果优于PPG1000,PU与EP的质量之比的最佳值为15%～20%;1,4-丁二醇/三羟甲基丙烷的引入能够使体系中聚氨酯分子链增长并交联成网状,但并不能进一步提高PU/EP材料的强度和韧性。     

RGA-D：一种无线传感器网络覆盖优化方法

研究了无线传感器网络覆盖优化问题,针对传感器节点随机部署、分布不均,传统覆盖优化算法一般只考虑网络部署后单次优化的问题,提出基于节点冗余和覆盖集冗余的计算方法,用网络的局部特征表征全局特征,改进了网络覆盖模型。并在此基础上提出RGA-D算法,利用遗传算法计算覆盖集,同时考虑节点和覆盖集冗余度,对网络整个生存期进行全局优化。仿真实验表明,RGA-D算法能在活跃节点数和网络覆盖率之间达到平衡,解决了网络生存期后期容易出现覆盖盲区的问题。     

基于改进离散粒子群禁忌算法的并行测试任务调度

针对并行测试任务调度问题特点,提出了一种解决并行测试任务调度的离散粒子群禁忌算法,设计了符合并行测试任务调度特点的粒子初始化编码方式、粒子位置转移公式以及禁忌搜索邻域。通过与禁忌搜索相结合,避免了离散粒子群算法早熟问题。通过实验以及算法对比,表明提出的算法是快速有效的,能够很好地解决并行测试任务调度问题,求得测试总时间最短的任务调度序列。     

超细聚苯乙烯(PS)树脂的制备工艺研究

采用O/W型苯乙烯微乳液体系,研究了乳化剂OP-10、助乳化剂DBS、交联剂DVB等对聚苯乙烯(PS)粒径分布的影响,基于正交试验,找出了量佳微乳液体系配方。采用激光粒度仪与透射电镜(TEM)对纳米PS粒子的粒径进行了测量研究,结果表明:交联PS粒子单分散性好,大小较均匀。     

基于差分算法的反渗透海水淡化优化调度

以系统运行费用为目标的反渗透海水淡化优化调度是一类带有约束的非线性优化问题。针对这一问题,提出一种改进的差分进化算法。该算法对基本差分进化算法中的变异因子和交叉因子进行改进;定义约束违反度函数,将约束优化问题转化为无约束的优化问题。以24小时为一个周期,通过改进的差分进化算法对系统模型进行优化调度。仿真结果表明,改进的算法可以对机组进行优化操作,有效的降低了系统的生产成本。     

Prediction of minimum fluidization velocity for vibrated fluidized bed

The prediction of minimum fluidization velocity for vibrated fluidized bed was performed. The Geldart group A and C particles were used as the fluidizing particles. The method based on Ergun equation was used to predict the minimum fluidization velocity. The calculated results were compared with the experimental data.The calculated results of minimum fluidization velocity are in good agreement with experimental data for Geldart group A particles. For group C particles, the difference between the calculated results and experimental data is large because of the formation of agglomerates. In this case, the determination of agglomerate diameter is considered to be necessary to predict the minimum fluidization velocity.     

氮化硅基陶瓷连接技术的研究进展

陶瓷连接技术是结构陶瓷实用化的有效手段，焊料成分对连接体的性能具有决定性作用。本文主要从焊料成分选择的角度，总结了氮化硅基陶瓷连接技术的发展现状；并重点讨论了陶瓷／玻璃复合焊料在β-Sialon陶瓷连接中的应用。     

Development of a bio‐based composite material from soybean oil and keratin fibers

A novel bio‐based composite material, suitable for electronic as well as automotive and aeronautical applications, was developed from soybean oils and keratin feather fibers (KF). This environmentally friendly, low‐cost composite can be a substitute for petroleum‐based composite materials. Keratin fibers are a hollow, light, and tough material and are compatible with several soybean (S) resins, such as acrylated epoxidized soybean oil (AESO). The new KFS lightweight composites have a density ρ ≈ 1 g/cm³, when the KF volume fraction is 30%. The hollow keratin fibers were not filled by resin infusion and the composite retained a significant volume of air in the hollow structure of the fibers. Due to the retained air, the dielectric constant, k, of the composite material was in the range of 1.7–2.7, depending on the fiber volume fraction, and these values are significantly lower than the conventional silicon dioxide or epoxy, or polymer dielectric insulators. The coefficient of thermal expansion (CTE) of the 30 wt % composite was 67.4 ppm/°C; this value is low enough for electronic application and similar to the value of silicon materials or polyimides used in printed circuit boards. The water absorption of the AESO polymer was 0.5 wt % at equilibrium and the diffusion coefficient in the KFS composites was dependent on the keratin fiber content. The incorporation of keratin fibers in the soy oil polymer enhanced the mechanical properties such as storage modulus, fracture toughness, and flexural properties, ca. 100% increase at 30 vol %. The fracture energy of a single keratin fiber in the composite was determined to be about 3 kJ/m² with a fracture stress of about 100–200 MPa. Considerable improvements in the KFS composite properties should be possible by optimization of the resin structure and fiber selection. © 2005 Wiley Periodicals, Inc. J Appl Polym Sci 95: 1524–1538, 2005