基于OpenCV的烟叶图像处理技术

以OpenCV底层函数为基础,在分析图像区域分割特点的基础上,提出了建立颜色模板的方法。研究了在不同目标区域和不同帧情况下剔除烟叶杂质的方法,给出了软件设计的基本思想,有较好的工程指导意义。     

植被信息提取过程中ETM+遥感影像融合和分类试验

利用HIS、PCA、Brovey及小波变换4种图像融合方法对南京地区植被信息提取过程中ETM 遥感影像进行融合和分类试验。从信息量、高分辨率信息的融入度和分类精度三方面,对融合图像进行光谱质量和空间结构信息的定量评价。试验结果表明,Brovey变换更适合植被信息提取时的ETM 图像融合,并能够较明显提高影像的分类精度。     

基于简化脉冲耦合神经网络的蝗虫图像二值分割

采用参数简化的脉冲耦合神经网络（PCNN）分割图像,进行了蝗虫图像分割实验,区域正确识别率达94％,为蝗虫自动侦测系统中的数据处理提供了技术支持。计算机仿真表明,采用PCNN图像分割算法,图像中的目标（蝗虫）易于发现,分割效果明显好于采用开操作处理的图像。     

消费者视角下特色农产品品牌形象研究 ——以烟台海参为例

以海参消费者为调查对象,采用设计调查问卷以及实地考察的方法进行调研。研究发现：烟台海参企业的品牌知名度不高,海产品市场为购买海参的主要途径,购买的产品种类主要为淡干海参,用途以送父母为主,获取海参信息的方式有传统媒体、新媒体及亲朋推荐,消费者购买海参时最看重的是质量;烟台海参品牌形象测量指标可以提取为三个主要因子：企业形象因子、产品形象因子和产地形象因子。最后,从企业层面、产品层面和产地层面提出烟台特色农产品品牌建设的建议。     

融合光谱与图像信息的河套蜜瓜糖度在线检测试验系统

针对蜜瓜糖度在线检测的需求,设计了融合漫透射光谱与图像信息的河套蜜瓜糖度在线检测试验系统,该系统包括硬件平台和软件系统两部分。硬件平台主要包括蜜瓜输送装置、光谱采集装置、图像采集装置和控制系统4部分。软件系统基于Microsoft Visual C++6.0语言,结合Omni Driver软件、Fly Capture2及Open CV软件开发。系统可实现蜜瓜光谱与图像信息的自动采集、显示及保存,可实现对漫透射光谱预处理,获取糖度检测所需光谱数据,对图像预处理,提取蜜瓜外观特征图像信息(R、G、B颜色值和蜜瓜体积)。在此基础上,系统可通过融合漫透射光谱与图像信息的蜜瓜糖度检测模型,计算蜜瓜糖度。系统同时可实现检测个数统计,外观特征信息及糖度的实时显示、保存等功能。测试试验表明,该试验系统检测1个样品用时1.2 s,糖度检测均方根误差为1.22,可满足河套蜜瓜糖度在线检测试验需求,为进一步开展河套蜜瓜糖度在线检测研究奠定了基础。     

排种器性能检测中种子位置智能检测方法

根据基于计算机视觉的排种器性能检测的特点，提出了基于神经网络的种子位置智能检测方法。采用两个光轴互相垂直的摄像机监测投种规律，并把以矩法求取的质心图像坐标作为输入节点，构造检测种子质心实际坐标的两个神经网络，并行处理左右两幅图像，从而快速求得种子位置。实践表明，此方法不仅能求出种子位置，而且可全面监测种子的运动情况。     

回转筒内秸秆碎料回转周期和料层完全混合时间研究

基于试验和理论分析,研究了回转筒型固态发酵罐内秸秆粉碎料的料床回转周期,建立了数学模型,其计算准确度达95%以上;结合图像分析法和料床回转周期,发现筒内上下料层完全混合时料层所转圈数与筒体转速关系不大,与筒内料体积填充率呈线性关系。由此回归并推导出只需知道筒内料体积填充率和筒体转速,便可预测上下料层完全混合的公式,其计算准确度达90%以上。提出了以上研究成果在工业级发酵罐中应用的方法。     

基于对数相似度约束Otsu的自然场景病害果实图像分割

针对自然场景下,由于复杂背景以及多变环境,水果病害果实图像分割难的问题,提出了一种基于对数相似度约束Otsu和水平集活动轮廓的近椭圆形病害果实图像分割方法。考虑背景的复杂多变,提出对数相似度约束Otsu分割来区分病害果实与背景;由于水平集活动轮廓模型的局部最优性,提出采用自适应膨胀系数的改进距离规则水平集活动轮廓模型来精确演化轮廓。先对病害果实区域样本的颜色进行混合高斯建模,获得整个病害果实图像与样本模型的对数相似度;对对数相似度进行约束Otsu阈值分割以及形态学滤波;采用最小二乘法对滤波后的曲线轮廓进行椭圆拟合,对拟合后的椭圆采用自适应膨胀系数的距离规则水平集活动轮廓演化,得到病害果实完整轮廓。对18个不同场景的病害果实进行分割,平均误判率和漏判率分别为1.77%和1.6%,实验结果表明,该方法可以从复杂自然场景图像中分割出病害果实。     

Desiccation and cracking behaviour of clay layer from slurry state under wetting-drying cycles

Laboratory tests were conducted to investigate the effect of wetting-drying (W-D) cycles on the initiation and evolution of cracks in clay layer. Four identical slurry specimens were prepared and subjected to five subsequent W-D cycles. The water evaporation, surface cracks evolution and structure evolution during the W-D cycles were monitored. The effect of W-D cycles on the geometric characteristics of crack patterns was analyzed by image processing. The results show that the desiccation and cracking behaviour was significantly affected by the applied W-D cycles: the measured cracking water content θ_c, surface crack ratio R_sc and final thickness h_f of the specimen increased significantly in the first three W-D cycles and then tended to reach equilibrium; the formed crack patterns after the second W-D cycle were more irregular than that after the first W-D cycle; the increase of surface cracks was accompanied by the decrease of pore volume shrinkage during drying. In addition, it was found that the applied W-D cycles resulted in significant rearrangement of specimen structure: the initially homogeneous and non-aggregated structure was converted to a clear aggregated-structure with obvious inter-aggregate pores after the second W-D cycle; the specimen volume generally increased with increasing cycles due to the aggregation and increased porosity. The image analysis results show that the geometric characteristics of crack pattern were significantly influenced by the W-D cycles, but this influence was reduced after the third cycle. This is consistent with the observations over the experiment, and indicates that the image processing can be used for quantitatively analyzing the W-D cycle dependence of clay desiccation cracking behaviour.     

A morphological approach to understanding preferential flow using image analysis with dye tracers and X-ray Computed Tomography

A key problem facing soil physics and hydropedology at present is some of the standard theories of water flow in soils do not fully reflect the processes at the pore scale, and thus, cannot be adequately used for prediction. As such, examination of soil structure is vital for hydropedologists. Realisation that solutes move preferentially through soil into groundwaters has meant research in this area has increased in importance. This paper describes a multi-scale approach to analyse transport mechanisms using visualisation techniques. Chloride and Brilliant Blue tracers were applied to undisturbed soil cores to examine the physical and morphological properties associated with preferential flow in a range of soil types. Following collection of serial digital images, it was possible to examine and quantify the nature of active water flow mechanisms in terms of both dye-stained pathways and spatial distribution of dye concentration, using image analysis. Preferential flow linked to water potential and soil structural discontinuity was observed in all but the coarsest textured soil which conformed to uniform flow theory. A high level of variability in flow patterns was noted between the soil types. Such information as to how a soil dynamically re-wets is key for hydropedologists involved in applications such as pollution modelling. This is especially significant when considering a wetting mechanism, such as preferential flow, that cannot be adequately described by conventional soil physics.