self-synchronous transmission
简明释义
自动同步传输
英英释义
例句
1.Using self-synchronous transmission 自同步传输, the system can maintain synchronization even in the presence of noise.
使用自同步传输 self-synchronous transmission,系统即使在噪声存在的情况下也能保持同步。
2.The design of the network protocol incorporates self-synchronous transmission 自同步传输 to enhance reliability during data exchange.
网络协议的设计采用了自同步传输 self-synchronous transmission 来提高数据交换的可靠性。
3.In modern digital communication systems, self-synchronous transmission 自同步传输 ensures that data is transmitted without the need for an external clock signal.
在现代数字通信系统中,自同步传输 self-synchronous transmission 确保数据在没有外部时钟信号的情况下进行传输。
4.Engineers prefer self-synchronous transmission 自同步传输 for its ability to simplify timing issues in high-speed networks.
工程师们偏爱自同步传输 self-synchronous transmission,因为它能够简化高速网络中的时序问题。
5.The benefits of self-synchronous transmission 自同步传输 include reduced complexity in circuit design.
自同步传输 self-synchronous transmission 的优点包括电路设计复杂度降低。
作文
In the realm of modern communication systems, the concept of self-synchronous transmission plays a pivotal role in ensuring efficient data transfer. This method of transmission allows for the synchronization of data signals without the need for external clock signals, thereby simplifying the design and implementation of communication protocols. The significance of self-synchronous transmission lies in its ability to maintain the integrity and timing of data as it travels through various mediums, such as fiber optics or wireless networks.To understand the importance of self-synchronous transmission, we must first explore the challenges faced in traditional synchronous transmission systems. In conventional methods, a separate clock signal is required to synchronize the sender and receiver. This can lead to complications, such as signal degradation over long distances or the need for complex circuitry to manage the timing. Additionally, any misalignment between the clock signals can result in data loss or corruption, which is detrimental to communication reliability.On the other hand, self-synchronous transmission mitigates these issues by embedding the timing information within the data stream itself. This technique relies on specific patterns or sequences within the transmitted data that can be used to derive the timing for synchronization. As a result, the receiver can accurately interpret the incoming data without needing an external clock, thus reducing the risk of errors and improving overall system performance.One of the most notable applications of self-synchronous transmission can be found in digital communication systems, such as those used in telecommunication networks and data storage devices. For instance, in the context of digital video broadcasting, this technique ensures that the video signals remain synchronized with audio tracks, providing viewers with a seamless experience. Similarly, in data storage, self-synchronous transmission techniques are employed to enhance the speed and reliability of data retrieval processes.Moreover, the advent of advanced technologies such as 5G and the Internet of Things (IoT) has further underscored the relevance of self-synchronous transmission. As more devices become interconnected and rely on real-time data exchange, the need for efficient synchronization methods becomes increasingly critical. By leveraging self-synchronous transmission, these systems can achieve higher data rates and lower latency, ultimately enhancing user experience and enabling new applications.In conclusion, the concept of self-synchronous transmission is integral to the evolution of communication technologies. Its ability to simplify synchronization processes while maintaining data integrity makes it a preferred choice in various applications. As we move toward a more interconnected world, understanding and implementing self-synchronous transmission will be essential for developing robust and efficient communication systems that can meet the demands of future technologies.
在现代通信系统的领域中,自同步传输的概念在确保高效数据传输方面发挥着关键作用。这种传输方法允许数据信号在没有外部时钟信号的情况下进行同步,从而简化了通信协议的设计和实现。自同步传输的重要性在于它能够在数据通过各种媒介(如光纤或无线网络)传输时,保持数据的完整性和时序。要理解自同步传输的重要性,我们首先必须探讨传统同步传输系统面临的挑战。在传统方法中,需要一个单独的时钟信号来同步发送方和接收方。这可能导致复杂性,例如长距离传输中的信号衰减,或需要复杂的电路来管理时序。此外,时钟信号之间的任何不对齐都可能导致数据丢失或损坏,这对通信可靠性是有害的。另一方面,自同步传输通过将时序信息嵌入到数据流中来减轻这些问题。这种技术依赖于传输数据中的特定模式或序列,这些模式或序列可以用于推导同步的时序。因此,接收方可以准确地解释传入的数据,而无需外部时钟,从而降低错误风险,提高整体系统性能。自同步传输的一个显著应用可以在数字通信系统中找到,例如在电信网络和数据存储设备中。例如,在数字视频广播的背景下,这种技术确保视频信号与音轨保持同步,为观众提供无缝的体验。同样,在数据存储中,自同步传输技术被用来提高数据检索过程的速度和可靠性。此外,随着5G和物联网(IoT)等先进技术的出现,自同步传输的相关性进一步得到了强调。随着越来越多的设备互联并依赖实时数据交换,对高效同步方法的需求变得越来越重要。通过利用自同步传输,这些系统可以实现更高的数据速率和更低的延迟,最终提升用户体验并启用新应用。总之,自同步传输的概念是通信技术演变的核心。它简化同步过程的能力,同时保持数据完整性,使其成为各种应用的首选。随着我们走向一个更加互联的世界,理解和实施自同步传输将对开发能够满足未来技术需求的强大和高效的通信系统至关重要。
