fixed acoustic buoy

简明释义

定声浮标固定音响浮筒

英英释义

例句

1.Fishermen rely on information gathered from the fixed acoustic buoy to find the best fishing spots.

渔民依靠从固定声学浮标收集的信息来寻找最佳捕鱼地点。

2.The research team deployed a fixed acoustic buoy to monitor marine life in the area.

研究小组部署了一个固定声学浮标以监测该地区的海洋生物。

3.Using a fixed acoustic buoy, scientists can track the movements of fish populations over time.

科学家们可以利用固定声学浮标跟踪鱼类种群的移动情况。

4.Data from the fixed acoustic buoy indicated changes in water temperature and salinity.

来自固定声学浮标的数据表明水温和盐度发生了变化。

5.The fixed acoustic buoy was installed to help detect underwater noise pollution.

安装固定声学浮标是为了帮助检测水下噪音污染。

作文

In recent years, the importance of marine research has grown significantly, leading to advancements in various technologies designed to monitor and understand our oceans. One such technology is the fixed acoustic buoy, which plays a crucial role in underwater acoustics and marine biology. A fixed acoustic buoy is essentially a stationary device that uses sound waves to collect data about the underwater environment. These buoys are equipped with hydrophones, which are sensitive microphones capable of picking up sounds from marine life, underwater currents, and even human activities such as shipping and fishing. The operation of a fixed acoustic buoy is relatively straightforward. Once deployed in a specific location, it continuously records sounds and sends this data to researchers for analysis. This real-time monitoring allows scientists to study various phenomena, such as fish migration patterns, the presence of marine mammals, and the effects of noise pollution on ocean ecosystems. For instance, by analyzing the acoustic data collected by a fixed acoustic buoy, researchers can determine when and where certain species are most active, which is vital for conservation efforts. Moreover, the data obtained from fixed acoustic buoys can contribute to understanding broader environmental changes. For example, changes in sound levels in the ocean can indicate shifts in marine populations or alterations in their habitats due to climate change. By integrating the information gathered from multiple buoys, scientists can create comprehensive models of marine ecosystems and predict future trends. One significant advantage of using fixed acoustic buoys is their ability to operate independently for extended periods. Unlike traditional research vessels, which require constant human presence and resources, these buoys can function autonomously, reducing operational costs and allowing for more extensive data collection over time. This is particularly beneficial for remote areas of the ocean, where access is challenging and costly. However, the deployment of fixed acoustic buoys is not without challenges. Environmental factors such as storms, currents, and marine life interactions can affect the performance and durability of these devices. Researchers must carefully select locations for deployment and ensure that the buoys are robust enough to withstand harsh conditions. Additionally, data management and analysis pose significant challenges, as the volume of information collected can be overwhelming. Advanced algorithms and machine learning techniques are increasingly being utilized to process and interpret this data effectively. In conclusion, fixed acoustic buoys represent a significant advancement in marine research technology. Their ability to provide continuous, real-time data on underwater acoustics makes them invaluable tools for scientists studying marine ecosystems. As we continue to face environmental challenges, the insights gained from these buoys will be crucial in informing conservation strategies and ensuring the sustainability of our oceans. The ongoing development and refinement of fixed acoustic buoys will undoubtedly enhance our understanding of the complex dynamics of marine environments, ultimately benefiting both science and society at large.

近年来，海洋研究的重要性显著增加，促使各种技术的进步，以监测和理解我们的海洋。其中一种技术是固定声学浮标，它在水下声学和海洋生物学中发挥着至关重要的作用。固定声学浮标本质上是一种静态设备，利用声波收集有关水下环境的数据。这些浮标配备了水听器，这是一种敏感的麦克风，能够捕捉来自海洋生物、水流甚至人类活动（如航运和捕鱼）的声音。固定声学浮标的操作相对简单。一旦在特定位置部署，它就会持续记录声音，并将这些数据发送给研究人员进行分析。这种实时监测使科学家能够研究各种现象，例如鱼类迁徙模式、海洋哺乳动物的存在以及噪声污染对海洋生态系统的影响。例如，通过分析固定声学浮标收集的声学数据，研究人员可以确定某些物种最活跃的时间和地点，这对保护工作至关重要。此外，从固定声学浮标获得的数据可以有助于理解更广泛的环境变化。例如，海洋中声音水平的变化可以表明海洋种群的变化或其栖息地因气候变化而发生的变化。通过整合从多个浮标收集的信息，科学家可以创建全面的海洋生态系统模型，并预测未来趋势。使用固定声学浮标的一个显著优势是它们能够独立运行较长时间。与传统研究船只需要不断的人力和资源相比，这些浮标可以自主工作，从而降低运营成本，并允许更广泛的数据收集。这对于海洋偏远地区尤其有利，因为那里获取数据既困难又昂贵。然而，部署固定声学浮标并非没有挑战。环境因素如风暴、水流和海洋生物的相互作用可能会影响这些设备的性能和耐用性。研究人员必须仔细选择部署位置，并确保浮标足够坚固以抵御恶劣条件。此外，数据管理和分析也面临重大挑战，因为收集到的信息量可能会令人不知所措。先进的算法和机器学习技术正越来越多地被用于有效处理和解释这些数据。总之，固定声学浮标代表了海洋研究技术的重要进步。它们提供连续的实时水下声学数据，使其成为科学家研究海洋生态系统的宝贵工具。随着我们继续面临环境挑战，从这些浮标获得的见解对于制定保护策略和确保海洋可持续性至关重要。固定声学浮标的持续发展和完善无疑将增强我们对海洋环境复杂动态的理解，最终使科学和社会整体受益。