sono-radio buoy

简明释义

防潜浮标防潜浮标

英英释义

例句

1.The research team deployed a sono-radio buoy to monitor oceanic sound levels.

研究小组部署了一个声波无线浮标来监测海洋声音水平。

2.The sono-radio buoy helped track underwater noise pollution in the area.

这个声波无线浮标帮助追踪了该地区的水下噪音污染。

3.We set up a network of sono-radio buoys to create a comprehensive acoustic map of the sea.

我们建立了一套声波无线浮标网络，以创建海洋的综合声学地图。

4.The data from the sono-radio buoy indicated an increase in ship traffic noise.

来自声波无线浮标的数据表明船只交通噪音有所增加。

5.Using the sono-radio buoy, we can gather data on marine life communication.

通过使用声波无线浮标，我们可以收集关于海洋生物交流的数据。

作文

In recent years, advancements in technology have significantly transformed various fields, including oceanography and marine research. One of the most notable innovations is the development of the sono-radio buoy, a sophisticated device that combines acoustic and radio technologies to enhance underwater communication and data collection. The sono-radio buoy serves as a vital tool for researchers studying marine ecosystems, monitoring environmental changes, and conducting underwater surveys.The primary function of the sono-radio buoy is to transmit and receive sound waves underwater. This capability is crucial because sound travels much better in water than light, making it the ideal medium for communication in aquatic environments. The sono-radio buoy can send acoustic signals to submarines or other underwater vehicles, enabling real-time data transmission from depths that are otherwise inaccessible. This feature allows scientists to gather valuable information about marine life, underwater topography, and even geological activity beneath the ocean floor.Moreover, the sono-radio buoy is equipped with advanced sensors that can measure various environmental parameters such as temperature, salinity, and pressure. These sensors provide critical data that help researchers understand the dynamics of marine ecosystems. For instance, by analyzing temperature variations over time, scientists can assess the impact of climate change on coral reefs and other sensitive habitats. The integration of radio technology allows the sono-radio buoy to relay this information to surface stations or satellites, ensuring that data is accessible for further analysis.Another significant advantage of the sono-radio buoy is its ability to operate autonomously for extended periods. Equipped with solar panels or other renewable energy sources, these buoys can function without human intervention, reducing operational costs and increasing efficiency. This autonomy is particularly beneficial for long-term studies, where continuous monitoring is essential. Researchers can deploy multiple sono-radio buoys across vast ocean areas, creating a network that provides comprehensive data coverage.Furthermore, the deployment of the sono-radio buoy contributes to improved safety in marine navigation. By transmitting real-time information about underwater conditions, such as currents and obstacles, these buoys can assist ships in avoiding hazardous areas. This capability not only enhances maritime safety but also helps protect fragile marine environments from accidental damage caused by vessels.In conclusion, the sono-radio buoy represents a significant leap forward in marine research and environmental monitoring. Its ability to combine acoustic and radio technologies opens up new avenues for understanding our oceans and the complex ecosystems they harbor. As we face increasing environmental challenges, the role of the sono-radio buoy will undoubtedly become more critical in our efforts to study and protect marine environments. The future of oceanography lies in innovative tools like the sono-radio buoy, which empower scientists to explore the depths of our oceans and gain insights that are essential for sustainable management of marine resources.

近年来，科技的进步显著改变了各个领域，包括海洋学和海洋研究。其中最显著的创新之一是声波无线浮标的开发，这是一种结合了声学和无线电技术的复杂设备，旨在增强水下通信和数据收集。声波无线浮标作为研究人员研究海洋生态系统、监测环境变化和进行水下调查的重要工具。声波无线浮标的主要功能是传输和接收水下声波。这一能力至关重要，因为声音在水中传播的效果远好于光，这使其成为水域内通信的理想媒介。声波无线浮标可以向潜艇或其他水下载具发送声学信号，实现来自深度区域的实时数据传输。这一特性使科学家能够收集有关海洋生物、水下地形甚至海底地质活动的宝贵信息。此外，声波无线浮标配备了先进的传感器，可以测量温度、盐度和压力等各种环境参数。这些传感器提供的关键数据有助于研究人员了解海洋生态系统的动态。例如，通过分析温度随时间的变化，科学家可以评估气候变化对珊瑚礁和其他敏感栖息地的影响。无线电技术的整合使得声波无线浮标能够将这些信息传递给水面站或卫星，从而确保数据可供进一步分析。声波无线浮标的另一个显著优势是其能够在较长时间内自主运行。配备太阳能电池板或其他可再生能源，这些浮标可以在没有人工干预的情况下工作，从而降低运营成本，提高效率。这种自主性对于长期研究尤为重要，因为持续监测至关重要。研究人员可以在广阔的海域中部署多个声波无线浮标，形成网络，为全面的数据覆盖提供支持。此外，声波无线浮标的部署有助于提高海洋导航的安全性。通过传输有关水下条件（如洋流和障碍物）的实时信息，这些浮标可以帮助船只避免危险区域。这一能力不仅增强了海上安全，还帮助保护脆弱的海洋环境免受船舶意外损害。总之，声波无线浮标代表了海洋研究和环境监测的重大进步。其将声学和无线电技术相结合的能力为理解我们的海洋及其复杂生态系统开辟了新的途径。随着我们面临日益严峻的环境挑战，声波无线浮标在研究和保护海洋环境方面的作用无疑会变得更加重要。海洋学的未来依赖于像声波无线浮标这样的创新工具，使科学家能够探索海洋深处，并获得对可持续管理海洋资源至关重要的见解。