跨平台高性能地图渲染技术研究

随着终端设备及操作系统多样化的发展,对地图的渲染性能提出了更高的要求.传统的地图渲染引擎,依赖于相应操作系统图形库,存在不能跨操作系统、渲染性能低、渲染风格不一致等问题.针对上述问题,本文提出一种跨平台的高性能地图渲染技术,采用蒙板绘制技术、纹理字典文本绘制技术,基于OpenGL(open graphics library)图形库,实现了在不同的硬件平台、不同的操作系统下,统一的高性能地图渲染引擎,保持了在不同平台下一致的地图渲染风格,性能比通用地图(MapBox)渲染引擎性能提高了1.75倍,矢量切片渲染性能为MapBox的80倍.     

复杂机场环境的多维动态可视化方法

针对飞行器可视导航中复杂机场空地环境多维要素动态交互可视化的难题,基于空地环境要素威胁语义统一的信息场模型,采用体绘制、面绘制与切片绘制混合的方法对机场近区域复杂多样的地形地貌、电磁和气象等威胁态势信息进行交互式动态可视化表达。以某机场的典型模拟数据为例,实现了威胁态势的动态交互可视化,验证了该方法的实用性和有效性。     

正二十面体全球剖分模型的Geometry Clipmap球面绘制

地形绘制一直是图形学研究的热点问题,尤其是球面地形绘制,其在形状和数据组织方面比平面地形绘制更加复杂。在已有球面地形绘制算法的基础上,提出一种基于Geometry Clipmap的球面地形剖分与绘制方法。该方法以构建正二十面体球面网格为基础,将正二十面体划分为十个菱形区域,采用球面菱形网格的剖分,针对每个菱形区域的周边网格进行重新剖分和组合,形成一个虚拟的3×3的大菱形区域,扩大了Clipmap的活动范围,并在一定程度上解决了Clipmap的跨边界问题。实验结果表明了本文方法的可行性和有效性。     

水利断面图绘制程序的设计与实现

断面图在水利建设的各个环节都有着十分重要的运用,目前随着测绘技术的更新换代,原来单一的、自动化程度差的断面绘制方式越来越不能适应当前水利工程建设的实际需要。本文结合多年水利测绘实践,设计出适应当前测绘方式多样化特点的水利断面绘制程序,为长期从事水利断面测绘的工作者提供方便。     

三维地形可视化中不同图元渲染效率比较分析

大规模地形场景一般由几百万甚至更多的顶点构成,地形瓦片的图元组织与绘制效率直接决定了地形渲染的速度和质量。为明确Triangles,Triangle Strip,Triangle Fan和优化的Triangle Strip图元渲染效率,选取常用的11种大小瓦片样本进行对比试验。从初始化时间、索引缓存大小和实时绘制时间3个方面评估图元效率。结果表明：在地形瓦片小于256时,Triangles和优化的Triangle Strip具备较高的渲染效率,Triangles会占用较大的索引缓存;在地形瓦片超过256时,优化后的Triangle Strip图元具有最高绘制效率,并且占用最小的索引缓存。     

水准路线图自动绘制实现方法

本文以某工程为例,介绍了水准路线图绘制方法,并编制自动绘制软件。软件可根据提供的点位信息自动绘制标准图幅的路线图,并具有点位标定准确、图幅信息完整、界面整饰美观的特点,同时极大提高了作业效率。     

降雨量等值线图的自动绘制方法

针对当前等值线自动绘制方法中存在的不足,该文以四川区域降雨量为例,分析降雨等值线的特点,依据计算机自动化等值线绘制的基本原则,给出了降雨量等值线的网格区域插值、等值线追踪、等值线平滑和等值线标注整个自动绘制流程的算法设计与具体实现。实验证明该方法易行、准确,可以拓展到更多的等值线绘制领域。     

折射波时距曲线及解释剖面的自动绘制

本文提出并解决了折射波时距曲线及解释剖面的自动绘制问题。通过自动的绘制，输出美观、准确的时距曲线及解释剖面，避免了清绘等过程，节省了大量的人力、物力。     

Systems for Hazards Identification in High Mountain Areas： An Example from the Kullu District, Western Himalaya

Methods and techniques for the identification, monitoring and management of natural hazards in high mountain areas are enumerated and described. A case study from the western Himalayan Kullu District in Himachal Pradesh, India is used to illustrate some of the methods. Research on the general topic has been conducted over three decades and that in the Kullu District has been carried out since 1994. Early methods of hazards identification in high mountain areas involved intensive and lengthy fieldwork and mapping with primary reliance on interpretation of landforms, sediments and vegetation thought to be indicative of slope fail ures, rock falls, debris flows, floods and accelerated soil surface erosion. Augmented by the use of airphotos and ad hoc observations of specific events over time, these methods resulted in the gradual accumulation of information on hazardous sites and the beginnings of a chronology of occurrences in an area. The use of historical methods applied to written and photographic material, often held in archives and libraries, further improved the resolution of hazards information. In the past two decades, both the need for, and the ability to, accurately identify potential hazards have increased. The need for accurate information and monitoring comes about as a result of rapid growth in population, settlements, transportation infrastructure and intensified land uses and, therefore, risk and vulnerability in mountain areas. Ability has improved as the traditional methods of gathering and manipulating data have been supplemented by the use of remotesensing, automated terrain modeling, global positioning systems and geographical information systems. This paper focuses on the development and application of the latter methods and techniques to characterize and monitor hazards in high mountain areas.