geostatics

简明释义

英[ˌdʒiːəʊˈstætɪks]美[ˌdʒiːəˈstætɪks]

n. [力] 刚体静力学

英英释义

单词用法

同义词

反义词

例句

1.The method and step of physical movement simulation of rigid body in real time are stated with geostatics and computer technology.

将刚体力学与计算机技术相结合，介绍了对刚体的物理运动进行实时模拟的方法和步骤。

2.The method and step of physical movement simulation of rigid body in real time are stated with geostatics and computer technology.

将刚体力学与计算机技术相结合，介绍了对刚体的物理运动进行实时模拟的方法和步骤。

3.The existing law of position setting comes from geostatics. It is confusable in application.

夹具设计六点定位法则出自刚体力学，离工程实际甚远，应用中有许多混乱。

4.Non-slippage rolling of a rigid body is a difficulty of teaching of geostatics.

刚体无滑滚动的问题是刚体力学的一个教学难点。

5.In our engineering class, we learned about geostatics 地质静力学 to understand the forces acting on structures.

在我们的工程课上，我们学习了关于geostatics 地质静力学的知识，以理解作用于结构上的力量。

6.The study of geostatics 地质静力学 is crucial for predicting how soil will behave under load.

研究geostatics 地质静力学对于预测土壤在荷载下的行为至关重要。

7.Civil engineers often rely on geostatics 地质静力学 when designing foundations for buildings.

土木工程师在设计建筑物基础时常常依赖于geostatics 地质静力学。

8.The principles of geostatics 地质静力学 help in understanding the stability of slopes and hillsides.

了解坡度和山坡的稳定性需要应用geostatics 地质静力学的原理。

9.During the project, we used geostatics 地质静力学 to assess the risk of landslides in the area.

在项目中，我们使用geostatics 地质静力学来评估该地区滑坡的风险。

作文

Geostatics is a branch of geophysics that deals with the study of forces acting on the Earth's crust. It involves understanding how these forces affect the stability and behavior of geological materials. The term 'geostatics' encompasses various aspects of geology, physics, and engineering, making it an interdisciplinary field that is crucial for many applications in civil engineering, mining, and environmental science. In essence, geostatics (地静力学) helps us understand the balance of forces within the Earth's crust, which is vital for constructing stable structures and predicting geological hazards. One of the primary applications of geostatics (地静力学) is in the design and analysis of foundations for buildings and other structures. Engineers must consider the weight of the structure and the soil's ability to support it. By applying principles of geostatics (地静力学), they can calculate the stress distribution within the soil and ensure that the foundation will remain stable under various loads. This knowledge is crucial, especially in areas prone to earthquakes or landslides where the ground may shift unexpectedly. Moreover, geostatics (地静力学) plays a significant role in the field of mining. When extracting minerals from the Earth, understanding the stresses and forces at play can help engineers design safer and more efficient mining operations. For instance, by analyzing the geostatic pressures within a mine, engineers can prevent collapses and ensure the safety of workers. This application highlights the importance of geostatics (地静力学) in resource extraction and management. In addition to its applications in engineering and mining, geostatics (地静力学) is also essential for environmental studies. Understanding the forces acting on geological formations can help predict how pollutants might spread through the ground or how water tables might be affected by human activities. Environmental scientists use geostatics (地静力学) to model the movement of contaminants and to design remediation strategies that minimize their impact on ecosystems. The study of geostatics (地静力学) is not without its challenges. One of the main difficulties lies in accurately measuring the various forces acting on geological materials. Factors such as soil composition, moisture content, and temperature can all influence the behavior of the ground. Therefore, researchers often rely on advanced modeling techniques and simulations to predict the outcomes of different scenarios. These models are essential for making informed decisions in engineering, mining, and environmental management. As technology advances, the field of geostatics (地静力学) continues to evolve. New tools and methods, such as remote sensing and computational modeling, are enhancing our ability to understand the complex interactions within the Earth's crust. These innovations are paving the way for safer construction practices, more efficient resource extraction, and improved environmental protection measures. In conclusion, geostatics (地静力学) is a vital field that bridges the gap between geology, physics, and engineering. Its applications are far-reaching, impacting everything from the stability of buildings to the safety of mining operations and the health of our environment. As we continue to explore and understand the forces that shape our planet, the importance of geostatics (地静力学) will only grow, highlighting the need for ongoing research and innovation in this critical area.