underwater acoustic communication set
简明释义
水声通讯设备
英英释义
A system designed for transmitting and receiving acoustic signals underwater, typically used in marine communication, data transfer, and monitoring applications. | 一种用于水下传输和接收声学信号的系统,通常用于海洋通信、数据传输和监测应用。 |
例句
1.Using the underwater acoustic communication set, divers were able to communicate effectively while exploring the shipwreck.
潜水员使用水下声学通信设备能够在探索沉船时有效沟通。
2.The research team deployed an underwater acoustic communication set to monitor marine life in real-time.
研究小组部署了一套水下声学通信设备以实时监测海洋生物。
3.The underwater acoustic communication set allowed for data transmission between autonomous underwater vehicles.
这套水下声学通信设备允许自主水下航行器之间进行数据传输。
4.During the training exercise, the navy utilized an underwater acoustic communication set to coordinate their movements.
在训练演习中,海军利用了水下声学通信设备来协调他们的行动。
5.The scientists tested a new prototype of the underwater acoustic communication set in a controlled environment.
科学家们在受控环境中测试了一种新的水下声学通信设备原型。
作文
In recent years, the field of underwater exploration has gained significant attention due to its importance in various sectors such as marine biology, environmental monitoring, and military operations. One of the critical technologies that facilitate effective communication in these challenging environments is the underwater acoustic communication set. This technology allows for the transmission of information through sound waves in water, which is essential given that traditional wireless communication methods do not work effectively underwater. The underwater acoustic communication set consists of several components, including transducers, signal processing units, and communication protocols. Transducers convert electrical signals into sound waves for transmission and vice versa for reception. The effectiveness of this system relies heavily on the frequency used; lower frequencies can travel longer distances but may carry less data, while higher frequencies support higher data rates but have limited range. The application of the underwater acoustic communication set spans various fields. In marine research, scientists use these systems to monitor aquatic life and gather data on oceanographic conditions. For instance, researchers can deploy autonomous underwater vehicles (AUVs) equipped with these communication sets to explore deep-sea environments, collect samples, and relay important data back to surface stations. This capability enhances our understanding of marine ecosystems and helps in conservation efforts. In military applications, the underwater acoustic communication set plays a crucial role in submarine communication and naval operations. Submarines often operate stealthily, submerged beneath the ocean's surface, where radio waves cannot penetrate. Therefore, they rely on acoustic communication to maintain contact with command centers or other vessels. This technology ensures that vital information can be exchanged without compromising the submarine's position. Despite its advantages, the underwater acoustic communication set also faces challenges. The underwater environment is complex, with factors such as temperature, salinity, and sea currents affecting sound propagation. Additionally, noise pollution from ships and marine activities can interfere with acoustic signals, making it difficult to maintain clear communication. Researchers are continually working on improving the performance of these systems by developing advanced algorithms and adaptive techniques that can mitigate these issues. As technology progresses, the future of the underwater acoustic communication set looks promising. Innovations such as machine learning and artificial intelligence are expected to enhance the efficiency and reliability of underwater communication. These advancements could lead to the development of more robust systems capable of operating in diverse marine environments, thereby expanding their applications even further. In conclusion, the underwater acoustic communication set is an essential technology for underwater exploration and communication. Its applications in marine research and military operations highlight its significance in our understanding and interaction with the underwater world. As we continue to face challenges in this domain, ongoing research and technological advancements will be vital in enhancing the capabilities of underwater communication systems, ensuring they meet the growing demands of various industries.
近年来,水下探索领域因其在海洋生物学、环境监测和军事行动等多个行业的重要性而受到广泛关注。促进这些复杂环境中有效通信的关键技术之一是水下声学通信系统。该技术允许通过水中的声波传输信息,这一点至关重要,因为传统的无线通信方法在水下效果不佳。水下声学通信系统由多个组件组成,包括换能器、信号处理单元和通信协议。换能器将电信号转换为声波进行传输,并将其反向转换为电信号以供接收。该系统的有效性在很大程度上依赖于使用的频率;较低的频率可以传播更远的距离,但可能携带的数据较少,而较高的频率支持更高的数据速率,但范围有限。水下声学通信系统的应用跨越多个领域。在海洋研究中,科学家使用这些系统来监测水生生物并收集海洋气候条件的数据。例如,研究人员可以部署配备这些通信系统的自主水下航行器(AUV)来探索深海环境、收集样本并将重要数据传回地面站。这种能力增强了我们对海洋生态系统的理解,并有助于保护工作。在军事应用中,水下声学通信系统在潜艇通信和海军行动中发挥着至关重要的作用。潜艇通常在海洋表面以下隐蔽操作,在这种情况下,电波无法穿透。因此,它们依赖声学通信与指挥中心或其他舰艇保持联系。这项技术确保了重要信息可以在不泄露潜艇位置的情况下进行交换。尽管具有优势,水下声学通信系统也面临挑战。水下环境复杂,温度、盐度和海流等因素影响声波传播。此外,来自船只和海洋活动的噪声污染可能干扰声学信号,使得保持清晰的通信变得困难。研究人员正在不断努力通过开发先进的算法和自适应技术来提高这些系统的性能,以减轻这些问题。随着技术的进步,水下声学通信系统的未来看起来充满希望。机器学习和人工智能等创新预计将提高水下通信的效率和可靠性。这些进步可能导致开发出更强大的系统,能够在多样的海洋环境中运行,从而进一步扩展其应用。总之,水下声学通信系统是水下探索和通信的重要技术。它在海洋研究和军事行动中的应用突显了它在我们理解和与水下世界互动中的重要性。随着我们继续面临这一领域的挑战,持续的研究和技术进步将在增强水下通信系统能力方面至关重要,以确保它们满足各行业日益增长的需求。
相关单词
