系统级封装SiP(System in a Package)已成为后摩尔时代延续摩尔定律的主要技术路线,电子装备小型化和多功能化的推动,使其在领域具有广阔前景。描述了一种基于SiP技术小型化多核信号处理的实现方案,详细讲述了芯片级设计及封装的具体方...系统级封装SiP(System in a Package)已成为后摩尔时代延续摩尔定律的主要技术路线,电子装备小型化和多功能化的推动,使其在领域具有广阔前景。描述了一种基于SiP技术小型化多核信号处理的实现方案,详细讲述了芯片级设计及封装的具体方法和思路,提出了一种基于SiP技术的多核处理器微系统设计及实现。展开更多
This article presents information on the distribution of Ferula tadshikorum Pimenov species in the botanical—geographical region of Uzbekistan, based on data collected from available resources, including internationa...This article presents information on the distribution of Ferula tadshikorum Pimenov species in the botanical—geographical region of Uzbekistan, based on data collected from available resources, including international sites, and databases, completed papers and directly conducted field studies. At the same time, under the circumstance that the natural area is directly getting smaller, the necessity and relevance of the thesis work on the evaluation of species’ natural reserves and the evaluation of the modern situations are demonstrated through examples. The Surkhandarya region is considered to have the largest number of plant species in Uzbekistan, and it is also distinguished by the variety of species. According to the location of the botanical-geographical regions of Uzbekistan, the territory of the Surkhandarya region is divided into five botanical-geographical regions (BGR). The 5 × 5 km2 grid system map includes 882 cells. Surkhan-Sherabod (BGR), Baisun (BGR), Sangardak-Topalang (BGR), Babatag (BGR), and Kuhitang (BGR) corresponded to these. Simultaneously, the 5 × 5 km2 grid system map of Uzbekistan’s flora in the Surkhandarya region revealed the presence of F. tadshikorum in 109 indices. On the territory of the region, the botanic-geographic region mainly includes the F. tadshikorum, Babatag (BGR), Baisun (BGR), and Kohitang (BGR) indices. The natural resources of F. tadshikorum in these areas were also analyzed.展开更多
采用同源建模的方法构建了斑马鱼γ-氨基丁酸A型(GABAA)受体和果蝇RDL(resistance to dieldrin)受体跨膜区的三维结构,研究了氟虫腈在两个受体中作用位点的差异;采用分子对接和分子动力学方法,探讨了氟虫腈与斑马鱼GABAA受体和果...采用同源建模的方法构建了斑马鱼γ-氨基丁酸A型(GABAA)受体和果蝇RDL(resistance to dieldrin)受体跨膜区的三维结构,研究了氟虫腈在两个受体中作用位点的差异;采用分子对接和分子动力学方法,探讨了氟虫腈与斑马鱼GABAA受体和果蝇RDL受体的结合模式,并比较了氟虫腈与两个受体作用的差异性。结果表明:斑马鱼 GABAA受体和氟虫腈作用位点的结构与果蝇RDL受体和氟虫腈作用位点的结构存在一定的差异,果蝇 RDL 受体中的 Ala301对应斑马鱼GABAA受体α1亚基中的Val284和γ2亚基中的Ser306,氨基酸构象的差异较大;氟虫腈与斑马鱼GABAA受体的结合位点靠近胞内区一端,而与果蝇RDL受体的结合位点则位于受体第二跨膜区的Ala301~Leu308区域内。复合物分子动力学模拟结果表明,在模拟过程中,两个受体与氟虫腈复合物体系的势能可很快达到平衡状态。斑马鱼GABAA受体与氟虫腈之间形成4个氢键,其中概率大于60%的氢键有2个;而尽管果蝇RDL受体与氟虫腈形成了6个氢键,但只有1个氢键的概率大于50%,其复合物结合的稳定性比前者低。展开更多
为科学确定气象站点地形起伏特征,基于先进星载热发射和反射辐射仪全球数字高程模型(Advanced Spaceborne Thermal Emission and Reflection Radiometer Global Digital Elevation Model,ASTER GDEM)30 m数据,利用均值变点分析法确定四...为科学确定气象站点地形起伏特征,基于先进星载热发射和反射辐射仪全球数字高程模型(Advanced Spaceborne Thermal Emission and Reflection Radiometer Global Digital Elevation Model,ASTER GDEM)30 m数据,利用均值变点分析法确定四川省地形起伏度模型的最佳分析窗口。提取地面气象观测站所处的地形起伏特征,探究气象站点布设的区域代表性空间格局。结果表明:(1)四川省地形起伏度的最佳窗口为39×39个像元矩形邻域,对应面积1.369 km^(2)。建立的地形起伏度模型与山脉走向一致,能够捕捉到地表各种尺度的地形起伏状况,符合四川省地貌特征。(2)国家站和区域站所处地势以台地、丘陵和小起伏山地为主,地形起伏较小的国家站占比明显高于区域站,即国家站更具有区域代表性。(3)四川省气象观测站点布设的适宜地区主要集中在盆地、川西高原的北部和西部及攀西地区的东部和南部,占全省面积的69.74%。均值变点分析法确定的分析窗口面积可以兼顾各种地貌类型,提取的地形起伏度能较好地反映气象站点所处地形特征,可为气象站点布局和站网优化提供重要参考依据。展开更多
文摘系统级封装SiP(System in a Package)已成为后摩尔时代延续摩尔定律的主要技术路线,电子装备小型化和多功能化的推动,使其在领域具有广阔前景。描述了一种基于SiP技术小型化多核信号处理的实现方案,详细讲述了芯片级设计及封装的具体方法和思路,提出了一种基于SiP技术的多核处理器微系统设计及实现。
文摘This article presents information on the distribution of Ferula tadshikorum Pimenov species in the botanical—geographical region of Uzbekistan, based on data collected from available resources, including international sites, and databases, completed papers and directly conducted field studies. At the same time, under the circumstance that the natural area is directly getting smaller, the necessity and relevance of the thesis work on the evaluation of species’ natural reserves and the evaluation of the modern situations are demonstrated through examples. The Surkhandarya region is considered to have the largest number of plant species in Uzbekistan, and it is also distinguished by the variety of species. According to the location of the botanical-geographical regions of Uzbekistan, the territory of the Surkhandarya region is divided into five botanical-geographical regions (BGR). The 5 × 5 km2 grid system map includes 882 cells. Surkhan-Sherabod (BGR), Baisun (BGR), Sangardak-Topalang (BGR), Babatag (BGR), and Kuhitang (BGR) corresponded to these. Simultaneously, the 5 × 5 km2 grid system map of Uzbekistan’s flora in the Surkhandarya region revealed the presence of F. tadshikorum in 109 indices. On the territory of the region, the botanic-geographic region mainly includes the F. tadshikorum, Babatag (BGR), Baisun (BGR), and Kohitang (BGR) indices. The natural resources of F. tadshikorum in these areas were also analyzed.
文摘为科学确定气象站点地形起伏特征,基于先进星载热发射和反射辐射仪全球数字高程模型(Advanced Spaceborne Thermal Emission and Reflection Radiometer Global Digital Elevation Model,ASTER GDEM)30 m数据,利用均值变点分析法确定四川省地形起伏度模型的最佳分析窗口。提取地面气象观测站所处的地形起伏特征,探究气象站点布设的区域代表性空间格局。结果表明:(1)四川省地形起伏度的最佳窗口为39×39个像元矩形邻域,对应面积1.369 km^(2)。建立的地形起伏度模型与山脉走向一致,能够捕捉到地表各种尺度的地形起伏状况,符合四川省地貌特征。(2)国家站和区域站所处地势以台地、丘陵和小起伏山地为主,地形起伏较小的国家站占比明显高于区域站,即国家站更具有区域代表性。(3)四川省气象观测站点布设的适宜地区主要集中在盆地、川西高原的北部和西部及攀西地区的东部和南部,占全省面积的69.74%。均值变点分析法确定的分析窗口面积可以兼顾各种地貌类型,提取的地形起伏度能较好地反映气象站点所处地形特征,可为气象站点布局和站网优化提供重要参考依据。