acoustic sounding

简明释义

回声测深

英英释义

例句

1.Using acoustic sounding, they discovered a new coral reef.

通过使用声学探测，他们发现了一个新的珊瑚礁。

2.The marine biologist used acoustic sounding to map the ocean floor.

海洋生物学家使用声学探测来绘制海底地图。

3.The acoustic sounding data revealed important information about sediment layers.

声学探测数据揭示了关于沉积层的重要信息。

4.The team employed acoustic sounding techniques to assess fish populations.

团队采用声学探测技术评估鱼类种群。

5.During the research, acoustic sounding helped identify underwater structures.

在研究过程中，声学探测帮助识别水下结构。

作文

The exploration of underwater environments has always fascinated scientists and researchers. One of the most effective methods for studying these vast, hidden realms is through techniques such as acoustic sounding. This method utilizes sound waves to map and analyze the seabed and the various structures that lie beneath the water's surface. The principle behind acoustic sounding is relatively simple: sound waves are emitted from a transducer, travel through the water, bounce off the seabed, and return to the source. By measuring the time it takes for the echoes to return, scientists can determine the depth of the water and the topography of the ocean floor. 声学探测是通过声波来绘制和分析海床及水下结构的一种有效方法。 One of the key advantages of acoustic sounding is its ability to cover large areas quickly and efficiently. Traditional methods of surveying the ocean floor, such as diving or using remotely operated vehicles (ROVs), can be time-consuming and limited in scope. In contrast, acoustic sounding can provide comprehensive data over extensive regions in a fraction of the time. This efficiency is particularly important for tasks such as mapping shipping routes, identifying potential fishing grounds, and assessing environmental impacts. Moreover, acoustic sounding is not limited to just measuring depth; it can also provide valuable information about the composition of the seabed. Different materials reflect sound waves differently, allowing researchers to infer what types of sediments or geological formations exist beneath the water. For instance, hard surfaces like rocks will produce a distinct echo compared to soft sediments like mud. This capability enhances our understanding of marine habitats and the distribution of resources. 声学探测不仅限于测量水深，还能提供关于海床组成的有价值信息。 In recent years, advancements in technology have further improved the effectiveness of acoustic sounding. High-resolution sonar systems can now create detailed three-dimensional images of the ocean floor, revealing features that were previously hidden from view. These innovations have opened new avenues for research, including studies on underwater ecosystems, shipwrecks, and even archaeological sites submerged for centuries. As a result, acoustic sounding has become an indispensable tool in marine science and exploration. However, despite its many benefits, acoustic sounding is not without its challenges. The accuracy of the data collected can be affected by various factors, including water temperature, salinity, and the presence of marine life. Additionally, there are concerns about the impact of sound pollution on aquatic ecosystems, as the use of high-intensity sound waves may disrupt the behavior of marine animals. Therefore, it is crucial for researchers to balance the need for data with the responsibility of protecting the delicate underwater environment. In conclusion, acoustic sounding is a powerful technique that has revolutionized our understanding of underwater landscapes. Its ability to provide quick and detailed insights into the ocean floor makes it an essential tool for scientists and researchers alike. As technology continues to evolve, the potential applications of acoustic sounding will undoubtedly expand, leading to further discoveries in the depths of our oceans. Understanding and mastering this technique will be vital for future explorations and conservation efforts in marine environments.

对水下环境的探索一直吸引着科学家和研究人员。研究这些广阔、隐秘领域的最有效方法之一是通过像声学探测这样的技术。这种方法利用声波来绘制和分析海床以及水面下各种结构。声学探测的原理相对简单：声波从换能器发出，穿过水面，反弹到海床，再返回到源头。通过测量回声返回所需的时间，科学家可以确定水深和海底地形。声学探测是通过声波来绘制和分析海床及水下结构的一种有效方法。声学探测的一个主要优点是它能够快速高效地覆盖大面积区域。传统的海床勘测方法，如潜水或使用遥控操作车辆（ROV），可能耗时且范围有限。相比之下，声学探测可以在短时间内提供广泛区域的综合数据。这种效率对于绘制航运路线、识别潜在渔场和评估环境影响等任务尤为重要。此外，声学探测不仅限于测量深度；它还可以提供有关海床组成的有价值信息。不同材料对声波的反射方式不同，使研究人员能够推断水下存在的沉积物或地质构造。例如，坚硬的岩石表面与柔软的泥沙相比，会产生明显不同的回声。这种能力增强了我们对海洋栖息地和资源分布的理解。声学探测不仅限于测量水深，还能提供关于海床组成的有价值信息。近年来，技术的进步进一步提高了声学探测的有效性。高分辨率声纳系统现在可以创建海底的详细三维图像，揭示以前隐藏的特征。这些创新为研究打开了新的途径，包括对水下生态系统、沉船甚至数百年来被淹没的考古遗址的研究。因此，声学探测已成为海洋科学和探索中不可或缺的工具。然而，尽管有许多好处，声学探测并非没有挑战。收集的数据的准确性可能受到多种因素的影响，包括水温、盐度和海洋生物的存在。此外，人们对声污染对水生生态系统的影响表示担忧，因为高强度声波的使用可能会干扰海洋动物的行为。因此，研究人员必须平衡数据需求与保护脆弱水下环境的责任。总之，声学探测是一种强大的技术，彻底改变了我们对水下景观的理解。其快速和详细的海底洞察能力使其成为科学家和研究人员的重要工具。随着技术的不断发展，声学探测的潜在应用无疑将扩大，导致我们在海洋深处的进一步发现。理解和掌握这一技术对未来在海洋环境中的探索和保护工作至关重要。