automatic residual statics

简明释义

自动剩余静校正;

英英释义

例句

1.During the seismic survey, automatic residual statics helped in correcting the variations caused by surface topography.

在地震勘测过程中，自动残余静态校正帮助修正了由地表地形引起的变化。

2.The results improved significantly after implementing automatic residual statics in the data processing workflow.

在数据处理工作流程中实施自动残余静态校正后，结果显著改善。

3.By applying automatic residual statics, we can significantly reduce the time spent on manual corrections.

通过应用自动残余静态校正，我们可以显著减少手动校正所花费的时间。

4.The software uses automatic residual statics to enhance the accuracy of seismic data interpretation.

该软件使用自动残余静态校正来提高地震数据解释的准确性。

5.The new processing algorithm incorporates automatic residual statics for better handling of complex geological structures.

新的处理算法结合了自动残余静态校正，以更好地处理复杂的地质结构。

作文

In the field of geophysics, particularly in seismic data processing, the term automatic residual statics refers to a method used to correct for time delays in seismic signals caused by variations in the Earth's surface and subsurface. This technique is crucial for enhancing the quality of seismic images, which are essential for oil and gas exploration, as well as for understanding geological formations. The process involves identifying and removing residual time shifts that remain after initial static corrections have been applied. These shifts can be caused by factors such as changes in elevation, near-surface velocity variations, and other geological complexities.The implementation of automatic residual statics has revolutionized the way geophysicists analyze seismic data. Traditionally, these corrections were performed manually, requiring extensive expertise and time. However, with advancements in computational techniques and algorithms, the automatic approach allows for a more efficient and accurate correction process. By utilizing sophisticated algorithms, the system can automatically detect and apply the necessary corrections to the seismic data, significantly reducing the time required for data processing.Moreover, the use of automatic residual statics enhances the reliability of the seismic interpretation. By minimizing the impact of residual statics, geophysicists can obtain clearer and more precise images of subsurface structures. This clarity is vital for making informed decisions in exploration and production activities. For instance, in oil and gas exploration, accurate seismic imaging can lead to better identification of potential reservoirs, ultimately impacting the success of drilling operations.In addition to its applications in oil and gas, automatic residual statics also plays a significant role in environmental studies, mineral exploration, and civil engineering projects. The ability to produce high-quality seismic data is essential for assessing risks, monitoring subsurface conditions, and designing safe structures. As the demand for natural resources continues to grow, the importance of effective seismic data processing becomes increasingly evident.Furthermore, ongoing research and development in the field of geophysics are likely to enhance the capabilities of automatic residual statics. As new algorithms and technologies emerge, the accuracy and efficiency of seismic data processing will continue to improve. This progress will not only benefit the energy sector but will also contribute to advancements in various scientific fields, including geology, environmental science, and engineering.In conclusion, automatic residual statics is a vital component of modern seismic data processing that significantly improves the quality of seismic images. Its automatic nature allows for faster and more accurate corrections, leading to better decision-making in exploration and resource management. As technology evolves, the impact of automatic residual statics will likely expand, further emphasizing its importance in both industry and research. Understanding this concept is essential for anyone involved in geophysical studies, as it underpins many of the advancements in the field today.

在地球物理学领域，特别是在地震数据处理方面，术语自动残余静态指的是一种用于修正地震信号中因地球表面和地下变化而产生的时间延迟的方法。这种技术对于提高地震图像的质量至关重要，这些图像对于石油和天然气勘探以及理解地质构造是必不可少的。该过程涉及识别并去除在初始静态修正后仍然存在的残余时间偏移。这些偏移可能是由诸如高程变化、近地表速度变化以及其他地质复杂性等因素引起的。自动残余静态的实施彻底改变了地球物理学家分析地震数据的方式。传统上，这些修正是手动进行的，需要大量的专业知识和时间。然而，随着计算技术和算法的进步，自动化方法使得修正过程更加高效和准确。通过利用复杂的算法，系统可以自动检测并应用必要的修正，从而显著减少数据处理所需的时间。此外，使用自动残余静态增强了地震解释的可靠性。通过最小化残余静态的影响，地球物理学家可以获得更清晰、更精确的地下结构图像。这种清晰度对于在勘探和生产活动中做出明智的决策至关重要。例如，在石油和天然气勘探中，准确的地震成像可以更好地识别潜在的储层，最终影响钻探作业的成功。除了在石油和天然气中的应用外，自动残余静态在环境研究、矿产勘探和土木工程项目中也发挥着重要作用。生产高质量地震数据的能力对于评估风险、监测地下条件和设计安全结构至关重要。随着对自然资源需求的不断增长，有效的地震数据处理的重要性变得愈加明显。此外，地球物理学领域的持续研究和开发可能会增强自动残余静态的能力。随着新算法和技术的出现，地震数据处理的准确性和效率将继续提高。这一进展不仅将使能源部门受益，还将促进包括地质学、环境科学和工程等多个科学领域的进步。总之，自动残余静态是现代地震数据处理中一个至关重要的组成部分，显著提高了地震图像的质量。其自动化特性允许更快、更准确的修正，从而促进了勘探和资源管理中的更好决策。随着技术的发展，自动残余静态的影响可能会扩大，进一步强调其在工业和研究中的重要性。理解这一概念对于任何参与地球物理研究的人来说都是必不可少的，因为它支撑着今天该领域的许多进步。