self-synchronous transmitter

简明释义

自动同步发射机

英英释义

例句

1.Engineers are testing the self-synchronous transmitter to ensure it meets international communication standards.

工程师正在测试自同步发射器以确保其符合国际通信标准。

2.The self-synchronous transmitter allows for real-time data transfer without the need for external clocks.

自同步发射器允许实时数据传输，无需外部时钟。

3.In high-frequency applications, a self-synchronous transmitter can reduce signal distortion significantly.

在高频应用中，自同步发射器可以显著减少信号失真。

4.A self-synchronous transmitter is essential for maintaining synchronization in distributed networks.

在分布式网络中，自同步发射器对于保持同步至关重要。

5.The new design of the communication system includes a self-synchronous transmitter that improves data transmission efficiency.

新设计的通信系统包括一个自同步发射器，提高了数据传输效率。

作文

In the realm of modern telecommunications, the term self-synchronous transmitter refers to a sophisticated device that plays a crucial role in the transmission of data. Unlike traditional transmitters that rely on external clocks or synchronization signals, a self-synchronous transmitter is capable of generating its own timing signals internally. This feature significantly enhances the efficiency and reliability of data communication systems, particularly in environments where maintaining synchronization can be challenging.The primary advantage of using a self-synchronous transmitter lies in its ability to reduce complexity in system design. Traditional systems often require additional components to ensure that the transmitter and receiver are aligned in time, which can lead to increased costs and potential points of failure. In contrast, a self-synchronous transmitter eliminates the need for these extra components, allowing for a more streamlined and cost-effective solution.Moreover, the self-synchronization capability of such transmitters makes them particularly valuable in wireless communication systems. For instance, in scenarios where signals may be subject to interference or varying distances, a self-synchronous transmitter can adapt to changing conditions in real time. This adaptability ensures that data packets are transmitted accurately and efficiently, minimizing the risk of data loss or corruption.Additionally, the implementation of self-synchronous transmitters in digital communication systems has paved the way for advancements in various technologies. From satellite communications to mobile networks, the ability to maintain synchronization without relying on external references has led to improved performance and user experiences. For example, in a mobile network, a self-synchronous transmitter can maintain a stable connection even as users move between different cell towers, providing seamless service.Furthermore, the use of self-synchronous transmitters is not limited to telecommunications alone. They have found applications in other fields, such as industrial automation and control systems. In these environments, precise timing is essential for coordinating actions between machines and processes. A self-synchronous transmitter can ensure that all components operate in harmony, leading to increased efficiency and reduced downtime.In conclusion, the concept of a self-synchronous transmitter represents a significant advancement in the field of data transmission. By eliminating the need for external synchronization and enhancing the reliability of communication systems, these devices have become integral to modern technology. As we continue to push the boundaries of what is possible in telecommunications and beyond, the importance of innovations like the self-synchronous transmitter will only grow. Understanding this technology not only provides insight into current communication practices but also highlights the ongoing evolution of our interconnected world.

在现代电信领域，术语自同步发射机指的是一种在数据传输中发挥关键作用的复杂设备。与依赖外部时钟或同步信号的传统发射机不同，自同步发射机能够内部生成自己的定时信号。这一特性显著提高了数据通信系统的效率和可靠性，特别是在维持同步可能具有挑战性的环境中。使用自同步发射机的主要优势在于其能够减少系统设计的复杂性。传统系统通常需要额外的组件来确保发射机和接收机在时间上对齐，这可能导致成本增加和潜在的故障点。相比之下，自同步发射机消除了对这些额外组件的需求，从而允许更简化和经济有效的解决方案。此外，这种发射机的自同步能力使其在无线通信系统中尤为宝贵。例如，在信号可能受到干扰或距离变化的情况下，自同步发射机能够实时适应变化的条件。这种适应性确保数据包被准确高效地传输，最大限度地减少数据丢失或损坏的风险。此外，自同步发射机在数字通信系统中的应用推动了各种技术的进步。从卫星通信到移动网络，能够在不依赖外部参考的情况下保持同步的能力提高了性能和用户体验。例如，在移动网络中，自同步发射机可以在用户在不同基站之间移动时保持稳定的连接，从而提供无缝服务。此外，自同步发射机的使用不限于电信领域。它们在工业自动化和控制系统等其他领域也得到了应用。在这些环境中，精确的时序对于协调机器和过程之间的动作至关重要。自同步发射机可以确保所有组件和谐运行，从而提高效率并减少停机时间。总之，自同步发射机的概念代表了数据传输领域的一项重大进展。通过消除对外部同步的需求并增强通信系统的可靠性，这些设备已成为现代技术的重要组成部分。随着我们继续推动电信及其他领域的可能性，像自同步发射机这样的创新的重要性只会增长。理解这项技术不仅提供了对当前通信实践的洞察，还突显了我们互联世界的持续演变。