基于CNN-Transformer混合结构的遥感影像变化检测模型

卷积神经网络和Transformer模型的出现,使得遥感影像变化检测技术不断进步,但是目前这2种方法仍存在不足:一方面,卷积神经网络由于其卷积核局部感知的特点无法对遥感影像进行全局信息建模;另一方面,Transformer虽然可以捕获遥感影像的全局信息,但是对影像变化的细节信息不能很好地建模,且其计算复杂度随图像的分辨率呈二次方增长。为了解决上述问题,获得更稳健的变化检测结果,本文提出一种基于卷积神经网络和Transformer混合结构的变化检测模型(CNN-Transformer Change Detection Network,CTCD-Net)。首先,CTCD-Net串联使用卷积神经网络和基于Transformer编解码结构来有效地编码遥感影像的局部特征和全局特征,从而提升网络的特征学习能力。其次,提出跨通道的Transformer自注意力模块(CSA)和注意力前馈网络(A-FFN),有效地降低了Transformer的计算复杂度。在LEVIRCD和CDD数据集上进行了充分的实验,实验结果表明,CTCD-Net的检测精确度显著优于目前其他主流方法。

Statistical Method for Block in Replication Design and Its SAS Program

Large-scale genetic population used for genetic breeding researches covers a large area in the field experiment,and the effect of local control would be gradually weakened.The block in replication(BIR)design is suitable for large population,which is applied to the field experiment of genetic population.The statistical methods of analysis of variance(ANOVA)and heritability estimation in single and multiple environments were derived and implemented using the statistical analysis system(SAS)program for the analysis of BIR.As a work example,a comparison of statistical analysis between BIR design and the completely random block(CRB)design were conducted for the protein content from a panel containing 455 soybean germplasms.The results indicated the different estimates of average heritability in multiple environments.The research results provided technical support for the application of BIR design in genetics and breeding studies.

基于农学应用型人才培养的项目化教学模式研究

项目化教学是培养农学应用型人才的有效模式,对发展现代农业、培养高素质农业人才、提高农业院校科研水平等方面起重要作用。本文结合东北农业大学进行项目化教学的实践经验,设计了农学专业项目化教学模式的流程,并提出为保证项目化教学实施效果的相应改革措施。

大豆产量相关性状的遗传分析

为促进大豆高产育种过程中后代性状的选择,运用加性-显性-上位性基因效应的遗传模型和统计分析方法,对15个大豆品种配制的15个不完全双列杂交组合在2个环境下的6个性状进行遗传分析。结果表明:单株荚数适宜在低世代选择,株高、主茎节数、单株粒数、单株粒重和百粒重适宜在高世代选择,环境条件对株高和百粒重的选择效果影响较大,对其他性状影响较小;株高和主茎节数、主茎节数和单株粒数、主茎节数和单株粒重、单株荚数和单株粒数、单株荚数和单株粒重、单株粒数和单株粒重在后代的选择中可协同改良,其中主茎节数与单株粒数的改良效果不受环境影响;选择单株粒数显性效应高的组合,容易获得较高的单株粒重,在特定的环境条件下间接选择单株荚数,可对单株粒重的提高产生一定效果。

慕课整合“田间试验与统计方法”教学资源

伴随着互联网科技的飞速发展,网络课堂教学日渐应用于教学改革当中,并且已经成为当代教育的亮点。其中,应用最多的慕课为课堂教学开辟了新途径,为教学改革注入了新鲜血液和活力。可以说,慕课的兴起与21世纪教育信息化的发展趋势相吻合,是教学改革中出现的大手笔。本文以"田间试验与统计方法"课程为着眼点深入浅出地分析慕课在教学资源中的应用与整合。

大豆荚数垂直分布的遗传分析与QTL定位

大豆荚数类型和空间分布决定产量的形成。以有一个共同亲本的两个重组自交系群体为遗传材料,按照植株的上、中、下3个部位调查一粒荚、二粒荚、三粒荚和四粒荚的数量,采用完备复合区间作图法进行QTL定位。结果表明:在两个群体中一粒荚、二粒荚、三粒荚、四粒荚在空间分布存在极显著的变异,部位间不同豆荚类型组成有显著差异,并且两个群体不同类型豆荚在不同部位分布的遗传基础不同,共检测到59个控制荚数性状的QTL,解释了0～11.45%的表型变异;两个群体检测到的荚数QTL中有30个QTL是本研究首次发现的。

高压密闭消解-电感耦合等离子体质谱法测定和田玉中15种稀土元素

和田玉的稀土元素丰富,准确测定稀土元素含量对于揭示和田玉成矿物质来源、成矿流体的性质和矿床成因具有重要的意义。本文通过比较硝酸-氢氟酸、四硼酸锂-偏硼酸锂碱熔两种前处理方法,确定了使用硝酸-氢氟酸溶样,再采用电感耦合等离子体质谱法(ICP-MS)测定和田玉中钇镧铈镨钕钐铕钆铽镝钬铒铥镱镥15种稀土元素的含量。为降低基体效应,以103Rh和49In作内标补偿基体效应和校正灵敏度漂移,样品检出限为0.0008~0.0091μg/L,回收率为101.0%~120.0%,精密度(RSD)为0.55%~1.83%(n=11)。本方法的用酸量少,空白值低,应用于不同地区和田玉的分析,其稀土元素的配分模式特征为右倾型轻稀土富集,初步探讨的稀土元素丰度特征可为研究主产区宝玉石的矿床成因提供依据。

Identifying Genomic Regions Conferring Morphological and Yield-related Traits in Soybean Based On A Four-way Recombinant Inbred Line Population

Improvement of seed yield of soybean(Glycine max(L.)Merr.)is generally achieved by combining morphological and yield-related traits,such as plant height(PH),node number on main stem(NN),pod number per plant(NP),seed number per plant(NS),100-seed weight(HSW)and seed weight per plant(SWPP).Identifying quantitative trait loci(QTLs)for morphological and yield-related traits is therefore important for breeding.In this study,a four-way recombinant inbred line population comprising 160 lines derived from the cross(Kenfeng14×Kenfeng15)×(Heinong48×Kenfeng19)was planted in five different environments and morphological and yield-related trait data were used to identify QTLs by the inclusive composite interval mapping method.Totally 38 QTLs for PH,40 QTLs for NN,26 QTLs for NP,10 QTLs for NS,26 QTLs for HSW and 49 QTLs for SWPP were detected in 125 genomic regions.Single QTLs explained 2.17%-14.60%,2.00%-10.04%,2.37%-9.77%,2.62%-8.61%,0.47%-6.51%and 0.14%-12.39%of the phenotypic variation for PH,NN,NP,NS,HSW and SWPP,respectively.Among these 125 genomic regions,120 were newly associated with morphological and yield-related traits.The results would facilitate the molecular breeding of morphological and yield-related traits in soybean.