analytic phototriangulation

简明释义

解析摄影三角测量;

英英释义

例句

1.Researchers utilized analytic phototriangulation 解析摄影三角测量 to accurately model the changes in glacier size over time.

研究人员利用解析摄影三角测量 analytic phototriangulation准确建模冰川规模随时间变化的情况。

2.By employing analytic phototriangulation 解析摄影三角测量, surveyors can achieve higher accuracy in mapping terrain.

通过采用解析摄影三角测量 analytic phototriangulation，测量员可以在地形绘图中获得更高的精度。

3.The integration of analytic phototriangulation 解析摄影三角测量 with GIS technology provides powerful tools for environmental analysis.

将解析摄影三角测量 analytic phototriangulation与GIS技术相结合，为环境分析提供了强大的工具。

4.In the context of urban planning, analytic phototriangulation 解析摄影三角测量 helps create detailed topographic maps.

在城市规划的背景下，解析摄影三角测量 analytic phototriangulation有助于创建详细的地形图。

5.The use of analytic phototriangulation 解析摄影三角测量 has revolutionized the field of aerial surveying.

使用解析摄影三角测量 analytic phototriangulation彻底改变了航空测量领域。

作文

In the field of photogrammetry, the concept of analytic phototriangulation plays a crucial role in accurately determining the three-dimensional coordinates of points on the Earth's surface using photographic images. This method relies on the principles of geometry and the use of specialized software to process aerial or terrestrial photographs. The term analytic phototriangulation refers to a mathematical approach that allows for the precise calculation of the relative positions of various points captured in overlapping photographs. By analyzing multiple images taken from different angles, surveyors can create accurate maps and models of the terrain. This technique is particularly valuable in fields such as cartography, architecture, and environmental monitoring.The process begins with the collection of overlapping photographs, which are typically taken from an aircraft or a drone. These images must have sufficient overlap to ensure that the same points are visible in multiple photographs. Once the images are acquired, the next step involves identifying common points across the photographs. This is where analytic phototriangulation comes into play. Using sophisticated algorithms, the software calculates the positions of these points in three-dimensional space by establishing a network of geometric relationships between them.One of the key advantages of analytic phototriangulation is its ability to produce high-precision results without the need for extensive ground control points. Traditional surveying methods often require numerous physical markers placed throughout the area of interest, which can be time-consuming and expensive to establish. In contrast, analytic phototriangulation minimizes this requirement by leveraging the inherent geometric relationships in the photographs themselves.Moreover, analytic phototriangulation is not limited to just aerial images; it can also be applied to terrestrial photography. This versatility makes it an essential tool for various applications, including urban planning, disaster management, and archaeological site documentation. For instance, archaeologists can use analytic phototriangulation to create detailed 3D models of excavation sites, allowing for better analysis and preservation of cultural heritage.As technology continues to advance, the methods and tools associated with analytic phototriangulation are becoming increasingly sophisticated. Modern software solutions incorporate machine learning algorithms that enhance the accuracy and efficiency of the triangulation process. Additionally, the integration of Geographic Information Systems (GIS) with analytic phototriangulation allows for more comprehensive data analysis and visualization, facilitating informed decision-making in various sectors.In conclusion, analytic phototriangulation is a vital technique in the realm of photogrammetry that enables the accurate mapping and modeling of the Earth's surface. Its reliance on geometric principles and advanced software has revolutionized the way we capture and analyze spatial data. As we continue to explore new technologies and methodologies, the significance of analytic phototriangulation will only grow, paving the way for innovative applications across multiple disciplines.

在摄影测量领域，解析光三角测量这一概念在准确确定地球表面点的三维坐标方面发挥着至关重要的作用，使用摄影图像。这种方法依赖于几何原理和使用专门的软件来处理航空或地面照片。术语解析光三角测量指的是一种数学方法，它允许精确计算在重叠照片中捕捉到的各种点的相对位置。通过分析从不同角度拍摄的多张图像，测量员可以创建地形的准确地图和模型。这项技术在制图、建筑和环境监测等领域特别有价值。该过程始于收集重叠的照片，这些照片通常是从飞机或无人机上拍摄的。这些图像必须具有足够的重叠，以确保在多张照片中可见相同的点。一旦图像被获取，下一步涉及识别照片中的共同点。这就是解析光三角测量发挥作用的地方。使用复杂的算法，软件通过建立这些点之间的几何关系网络来计算这些点在三维空间中的位置。解析光三角测量的一个主要优点是能够在没有大量地面控制点的情况下产生高精度的结果。传统的测量方法通常需要在感兴趣的区域放置许多物理标记，这可能耗时且费用昂贵。相比之下，解析光三角测量通过利用照片本身固有的几何关系来最小化这一要求。此外，解析光三角测量不仅限于航空图像；它也可以应用于地面摄影。这种多功能性使其成为各种应用的重要工具，包括城市规划、灾害管理和考古遗址文档。例如，考古学家可以使用解析光三角测量创建详细的3D模型，以便更好地分析和保护文化遗产。随着技术的不断进步，与解析光三角测量相关的方法和工具变得越来越复杂。现代软件解决方案结合了机器学习算法，提高了三角测量过程的准确性和效率。此外，将地理信息系统（GIS）与解析光三角测量相结合，允许更全面的数据分析和可视化，从而促进各个领域的明智决策。总之，解析光三角测量是摄影测量领域的一项重要技术，使得地球表面的准确绘图和建模成为可能。它依赖于几何原理和先进软件的特征，彻底改变了我们捕捉和分析空间数据的方式。随着我们继续探索新技术和方法，解析光三角测量的重要性只会增加，为多个学科的创新应用铺平道路。