combined echo ranging echo sounding

简明释义

组合回声测距与测深

英英释义

例句

1.The research team used combined echo ranging echo sounding to map the underwater terrain accurately.

研究小组使用综合回声测距和回声探测准确绘制水下地形。

2.With combined echo ranging echo sounding, we can determine the depth of the ocean floor with high precision.

通过综合回声测距和回声探测，我们可以高精度地确定海底的深度。

3.The fishing industry relies on combined echo ranging echo sounding to find the best fishing spots.

渔业依赖于综合回声测距和回声探测来寻找最佳捕鱼地点。

4.Using combined echo ranging echo sounding, scientists were able to discover new underwater features.

科学家们利用综合回声测距和回声探测发现了新的水下特征。

5.The vessel employed combined echo ranging echo sounding techniques to locate shipwrecks.

该船采用综合回声测距和回声探测技术定位沉船。

作文

In the realm of marine exploration and underwater research, various technologies have been developed to enhance our understanding of the oceanic environment. One such technology is the technique known as combined echo ranging echo sounding, which plays a crucial role in mapping the seafloor and studying underwater ecosystems. This method integrates two essential processes: echo ranging and echo sounding, allowing researchers to obtain detailed information about underwater topography and the presence of marine life.Echo ranging involves sending sound waves from a vessel or underwater device and measuring the time it takes for these waves to return after bouncing off an object. This technique is widely used in navigation, helping ships avoid obstacles and safely traverse through complex underwater landscapes. On the other hand, echo sounding specifically focuses on measuring the depth of water bodies by emitting sound pulses and analyzing the returning echoes. This process is vital for creating accurate maps of the seafloor, which can reveal important geological features and habitats.The combined echo ranging echo sounding approach merges these two techniques to provide a comprehensive view of the underwater environment. By utilizing both echo ranging and echo sounding simultaneously, researchers can generate high-resolution images of the seafloor while also determining the distance to various underwater objects. This dual capability is particularly beneficial in areas where traditional methods may fall short, such as in deep-sea exploration or regions with complex underwater topography.Moreover, the application of combined echo ranging echo sounding extends beyond mere mapping. It is instrumental in ecological studies, helping scientists monitor fish populations and assess the health of marine ecosystems. For instance, by analyzing the data obtained from this combined technique, researchers can identify habitats that are critical for the survival of various marine species. This information is invaluable for conservation efforts, as it allows for targeted protection of vulnerable areas.In addition to its scientific applications, combined echo ranging echo sounding has significant implications for industries such as fishing and oil exploration. Fishermen can use this technology to locate schools of fish more effectively, ensuring sustainable practices and minimizing overfishing. Similarly, oil and gas companies rely on accurate seafloor mapping to identify potential drilling sites, reducing the environmental impact of their operations.As technology advances, the combined echo ranging echo sounding method continues to evolve, incorporating more sophisticated sensors and data analysis techniques. Innovations such as autonomous underwater vehicles (AUVs) equipped with advanced sonar systems are enhancing the precision and efficiency of this approach. These developments not only improve our ability to explore and understand the ocean but also contribute to better management of marine resources.In conclusion, the combined echo ranging echo sounding technique represents a significant advancement in marine science and exploration. Its ability to provide detailed insights into underwater environments makes it an invaluable tool for researchers, conservationists, and industry professionals alike. As we continue to explore the mysteries of the ocean, the importance of such technologies will only grow, fostering a deeper appreciation for the complexities of our planet's aquatic ecosystems.

在海洋探索和水下研究领域，各种技术的发展增强了我们对海洋环境的理解。其中一种技术是被称为联合回声测距回声探测的技术，它在绘制海底地图和研究水下生态系统中发挥着至关重要的作用。这种方法结合了两个基本过程：回声测距和回声探测，使研究人员能够获得关于水下地形和海洋生物存在的详细信息。回声测距涉及从船只或水下设备发送声波，并测量这些声波在碰撞到物体后返回所需的时间。这种技术广泛用于导航，帮助船只避免障碍物并安全通过复杂的水下地形。另一方面，回声探测专注于通过发射声脉冲并分析返回的回声来测量水体的深度。这个过程对于创建准确的海底地图至关重要，这些地图可以揭示重要的地质特征和栖息地。联合回声测距回声探测方法将这两种技术合并，以提供对水下环境的全面视图。通过同时利用回声测距和回声探测，研究人员可以生成海底的高分辨率图像，同时确定各种水下物体的距离。这种双重能力在传统方法可能不够有效的区域尤为有利，例如在深海探索或具有复杂水下地形的地区。此外，联合回声测距回声探测的应用超越了单纯的绘图。它在生态研究中发挥着重要作用，帮助科学家监测鱼类种群并评估海洋生态系统的健康。例如，通过分析从这种组合技术获得的数据，研究人员可以识别对各种海洋物种生存至关重要的栖息地。这些信息对于保护工作至关重要，因为它允许针对性地保护脆弱区域。除了科学应用外，联合回声测距回声探测对渔业和石油勘探等行业也有重要影响。渔民可以利用这项技术更有效地定位鱼群，确保可持续做法并最小化过度捕捞。同样，石油和天然气公司依赖准确的海底绘图来识别潜在的钻探地点，从而减少其操作对环境的影响。随着技术的进步，联合回声测距回声探测方法不断演变，结合了更复杂的传感器和数据分析技术。配备先进声纳系统的自主水下航行器（AUV）的创新正在提高这种方法的精确性和效率。这些发展不仅改善了我们探索和理解海洋的能力，也有助于更好地管理海洋资源。总之，联合回声测距回声探测技术代表了海洋科学和探索的重要进展。它提供的对水下环境的详细洞察使其成为研究人员、保护主义者和行业专业人士都不可或缺的工具。随着我们继续探索海洋的奥秘，这种技术的重要性将只会增加，促进我们对地球水生生态系统复杂性的更深刻理解。