transceiver

简明释义

英[trænˈsiːvə(r)]美[trænˈsiːvər]

n. [通信] 收发器，无线电收发两用机

英英释义

单词用法

同义词

反义词

例句

1.It affects the whole performance of the transceiver.

它的性能将直接影响整个接收机的性能。

2.So the satellite communication system made stringent requirements for the RF front end of the transceiver.

所以，在卫星通信系统中，射频收发模块的性能指标有着严格的要求。

3.He did say that no one was going to find us unless we get that transceiver working.

他说没人会找到我们的，除非那无线电接收器好用了。

4.In the second part, we study the theory of optical transceiver module in the digital fiber-optical communication system.

在论文的第二部分详细介绍了数字光纤通信系统中的光收发模块的基本原理。

5.Communication industry: Generator room, Base transceiver station, Transformer distribution room, Computer room.

通讯行业：机房、基站、变配电室、计算机房等。

6.Fiber optic , transceiver , interface converter.

光纤，受罚器，接口转换器。

7.DEI1016is a serial transceiver which can support ARINC429avigation bus protocol.

DEI1016是一种可支持ARINC 429航空总线协议的串行接收、发送器件。

8.The transceiver in my walkie-talkie is very powerful.

我对讲机中的收发器非常强大。

9.We need to replace the faulty transceiver in the network.

我们需要更换网络中故障的收发器。

10.The radio transceiver allows us to communicate over long distances.

这个无线电收发器让我们能够在远距离进行交流。

11.We installed a new transceiver in the satellite dish for better reception.

我们在卫星天线中安装了一个新的收发器以获得更好的接收效果。

12.This transceiver can operate on multiple frequencies.

这个收发器可以在多个频率上工作。

作文

In today's world, communication technology plays a vital role in connecting people and devices. One of the key components that facilitate this connection is the transceiver, which is a device that can both transmit and receive signals. Transceivers are essential for various applications, including radio communications, satellite systems, and computer networking. Understanding how transceiver technology works can help us appreciate the advancements in communication systems and their impact on our daily lives.A transceiver typically combines the functions of a transmitter and a receiver into a single unit. This integration simplifies the design of communication systems by reducing the number of components needed. For instance, in radio communications, a transceiver can send and receive radio waves, allowing users to communicate over long distances without the need for separate devices. This capability is particularly important in emergency situations where reliable communication is crucial.Moreover, transceivers come in various forms, each designed for specific applications. For example, in the realm of wireless networks, Wi-Fi transceivers enable devices like laptops and smartphones to connect to the internet. These transceivers operate on different frequency bands and use modulation techniques to ensure efficient data transmission. As technology evolves, so do the capabilities of transceivers. Modern devices often support multiple standards, allowing them to communicate seamlessly with various networks.Another significant application of transceivers is in satellite communications. Satellite transceivers are responsible for sending and receiving signals between Earth and orbiting satellites. This technology is crucial for services like GPS navigation, weather forecasting, and global telecommunications. The ability of transceivers to function in harsh environments, such as outer space, showcases their robustness and reliability.In addition to their technical functions, transceivers also play a role in the development of the Internet of Things (IoT). IoT devices often rely on transceivers to communicate with each other and with central servers. For example, smart home devices, such as thermostats and security cameras, use transceivers to send data to users' smartphones or cloud services. This connectivity enables users to monitor and control their devices remotely, enhancing convenience and security.As we look to the future, the importance of transceivers will only continue to grow. With the rise of 5G technology, new transceivers are being developed to support faster data speeds and lower latency. This advancement will enable more sophisticated applications, such as autonomous vehicles and smart cities. Thus, understanding the role of transceiver technology is crucial for anyone interested in the future of communication and technology.In conclusion, a transceiver is a fundamental component of modern communication systems, allowing for the seamless transmission and reception of signals. From radio communications to IoT devices, transceivers have transformed the way we connect and interact with the world around us. As technology continues to advance, the capabilities of transceivers will evolve, paving the way for new innovations and improved communication methods. By appreciating the significance of transceiver technology, we can better understand the interconnected world we live in today.

在当今世界，通信技术在连接人和设备方面发挥着至关重要的作用。促进这种连接的关键组件之一是收发器，它是一种可以同时发送和接收信号的设备。收发器在无线电通信、卫星系统和计算机网络等各种应用中都是必不可少的。理解收发器技术的工作原理可以帮助我们欣赏通信系统的进步及其对我们日常生活的影响。收发器通常将发射器和接收器的功能合并为一个单元。这种集成简化了通信系统的设计，减少了所需组件的数量。例如，在无线电通信中，收发器可以发送和接收无线电波，使用户能够在没有单独设备的情况下进行远距离通信。这种能力在紧急情况下尤为重要，因为可靠的通信至关重要。此外，收发器有多种形式，每种形式都旨在用于特定应用。例如，在无线网络领域，Wi-Fi 收发器使笔记本电脑和智能手机等设备能够连接到互联网。这些收发器在不同的频段上工作，并使用调制技术以确保高效的数据传输。随着技术的发展，收发器的能力也在不断提高。现代设备通常支持多种标准，使它们能够与各种网络无缝通信。收发器的另一个重要应用是在卫星通信中。卫星收发器负责在地球和轨道卫星之间发送和接收信号。这项技术对于GPS导航、天气预报和全球电信等服务至关重要。收发器在恶劣环境（如外太空）中工作的能力展示了它们的稳健性和可靠性。除了技术功能外，收发器在物联网（IoT）的发展中也发挥着作用。物联网设备通常依赖于收发器相互通信以及与中央服务器的通信。例如，智能家居设备（如温控器和安全摄像头）使用收发器将数据发送到用户的智能手机或云服务。这种连接使用户能够远程监控和控制设备，从而增强便利性和安全性。展望未来，收发器的重要性只会继续增长。随着5G技术的崛起，新的收发器正在开发中，以支持更快的数据速度和更低的延迟。这一进步将使更复杂的应用成为可能，如自动驾驶汽车和智能城市。因此，理解收发器技术的角色对于任何对通信和技术未来感兴趣的人来说都是至关重要的。总之，收发器是现代通信系统的基本组成部分，允许信号的无缝传输和接收。从无线电通信到物联网设备，收发器已经改变了我们与周围世界连接和互动的方式。随着技术的不断进步，收发器的能力将不断演变，为新创新和改进的通信方法铺平道路。通过欣赏收发器技术的重要性，我们可以更好地理解我们今天所生活的互联世界。