goniometric network

简明释义

测向网络

英英释义

例句

1.In geodesy, a well-established goniometric network allows for more reliable mapping of the Earth's surface.

在大地测量中，一个完善的测角网络可以更可靠地绘制地球表面地图。

2.Using a goniometric network, we can improve the precision of our geographical data collection.

通过使用测角网络，我们可以提高地理数据收集的精确度。

3.The survey team set up a goniometric network to accurately measure the angles between various landmarks.

测量小组建立了一个测角网络，以准确测量各个地标之间的角度。

4.The goniometric network was essential for the construction of the new bridge, ensuring all angles were correctly aligned.

这个测角网络对于新桥的建设至关重要，确保所有角度都正确对齐。

5.The researchers utilized a goniometric network to study the tectonic movements in the region.

研究人员利用测角网络研究该地区的构造运动。

作文

In the field of geodesy and surveying, precise measurements are crucial for various applications, including mapping, construction, and navigation. One of the essential tools used in these disciplines is the goniometric network, which refers to a system of points established for the purpose of measuring angles between them. This network allows surveyors to determine the relative positions of different locations with high accuracy. The term 'goniometric' derives from the Greek word 'gonia,' meaning angle, and it emphasizes the importance of angular measurement in this context.A goniometric network typically consists of a series of interconnected points, each equipped with specialized instruments such as theodolites or total stations. These instruments enable surveyors to measure horizontal and vertical angles between points, which can then be used to calculate distances and positions through triangulation. By establishing a network of points, surveyors can create a comprehensive framework that enhances the precision of their measurements.The significance of a goniometric network extends beyond mere measurement. It plays a pivotal role in various scientific and engineering projects. For instance, in civil engineering, accurate positioning is vital for the successful execution of large-scale projects like bridges, roads, and buildings. A well-established goniometric network ensures that all measurements taken during the construction process are reliable, reducing the risk of errors that could lead to costly delays or structural failures.Moreover, goniometric networks are essential in the field of geophysics, where they are used to monitor tectonic movements and study seismic activities. By continuously measuring the angles between fixed points over time, scientists can detect subtle shifts in the Earth's crust, providing valuable data for understanding earthquakes and other geological phenomena.The establishment of a goniometric network involves meticulous planning and execution. Surveyors must carefully select locations for the points to ensure optimal visibility and accessibility. Additionally, they must account for potential obstacles, such as buildings or trees, that could interfere with measurements. Once the network is in place, regular maintenance and calibration are necessary to ensure its continued accuracy.In recent years, advancements in technology have further enhanced the capabilities of goniometric networks. The integration of satellite-based systems, such as Global Positioning System (GPS) technology, has revolutionized traditional surveying methods. While conventional goniometric networks relied solely on ground-based measurements, GPS allows for real-time data collection and analysis, significantly increasing efficiency and accuracy.In conclusion, the goniometric network is a fundamental component of modern surveying and geodesy. Its ability to provide precise angular measurements facilitates a wide range of applications, from civil engineering to geophysical research. As technology continues to evolve, the role of goniometric networks will undoubtedly expand, paving the way for even more accurate and efficient surveying practices in the future.

在大地测量和测绘领域，精确的测量对于各种应用至关重要，包括制图、建筑和导航。其中一个在这些学科中使用的重要工具是测角网络，它指的是为测量点之间的角度而建立的一系列点。这种网络使测量员能够高精度地确定不同位置的相对位置。术语“测角”源自希腊词“gonia”，意为角度，强调了角度测量在此背景下的重要性。一个测角网络通常由一系列互连的点组成，每个点都配备有专业仪器，如经纬仪或全站仪。这些仪器使测量员能够测量点之间的水平和垂直角度，然后可以通过三角测量计算距离和位置。通过建立一个点的网络，测量员可以创建一个全面的框架，从而提高测量的精度。测角网络的重要性不仅仅体现在测量上。它在各种科学和工程项目中发挥着关键作用。例如，在土木工程中，准确的定位对于大型项目（如桥梁、道路和建筑物）的成功执行至关重要。一个良好建立的测角网络确保在施工过程中进行的所有测量都是可靠的，减少了可能导致昂贵延误或结构故障的错误风险。此外，测角网络在地球物理学领域也是必不可少的，常用于监测构造运动和研究地震活动。通过持续测量固定点之间的角度，科学家可以检测到地壳的微小变化，为理解地震和其他地质现象提供宝贵的数据。建立一个测角网络需要细致的规划和执行。测量员必须仔细选择点的位置，以确保最佳的可见性和可达性。此外，他们还必须考虑可能的障碍物，如建筑物或树木，这可能会干扰测量。一旦网络建立，就需要定期维护和校准，以确保其持续的准确性。近年来，技术的进步进一步增强了测角网络的能力。卫星系统（如全球定位系统（GPS）技术）的整合彻底改变了传统的测量方法。虽然传统的测角网络仅依赖于基于地面的测量，但GPS允许实时数据收集和分析，大大提高了效率和准确性。总之，测角网络是现代测量和大地测量的基本组成部分。它提供的精确角度测量促进了从土木工程到地球物理研究的广泛应用。随着技术的不断发展，测角网络的角色无疑将扩展，为未来更加准确和高效的测量实践铺平道路。