secondary multiplexing

简明释义

二次复用

英英释义

例句

1.By using secondary multiplexing, we can transmit more data over existing infrastructure.

通过使用二级复用，我们可以在现有基础设施上传输更多数据。

2.The system utilizes secondary multiplexing to enhance data transmission efficiency.

该系统利用二级复用来提高数据传输效率。

3.In telecommunications, secondary multiplexing allows multiple signals to share the same channel.

在电信中，二级复用允许多个信号共享同一信道。

4.The implementation of secondary multiplexing has significantly reduced bandwidth consumption.

实施二级复用显著减少了带宽消耗。

5.Our new router supports secondary multiplexing for better network performance.

我们的新路由器支持二级复用以提高网络性能。

作文

In the realm of telecommunications and data transmission, efficiency and optimization are paramount. One concept that plays a crucial role in enhancing these aspects is secondary multiplexing. This term refers to a method of combining multiple signals into a single transmission channel, allowing for more efficient use of bandwidth. By implementing secondary multiplexing (二次复用), service providers can maximize their infrastructure capabilities, leading to improved service quality for users.To understand secondary multiplexing, it is essential to first grasp the basics of multiplexing itself. Multiplexing is the process of combining multiple signals over a single medium. This can be done in several ways, including time-division multiplexing (TDM) and frequency-division multiplexing (FDM). TDM allocates different time slots for each signal, while FDM assigns different frequency bands. However, as technology advances and the demand for data increases, traditional multiplexing methods may not suffice. This is where secondary multiplexing comes into play.Secondary multiplexing allows for the integration of additional layers of multiplexing on top of existing channels. For instance, consider a scenario where a primary multiplexing technique is already in use. By applying secondary multiplexing, additional signals can be introduced without requiring new physical lines or channels. This is particularly beneficial in environments where infrastructure expansion is limited or costly.One of the significant advantages of secondary multiplexing is its ability to enhance data throughput. In a world where digital communication is ubiquitous, the capacity to transmit large volumes of data quickly is invaluable. By utilizing secondary multiplexing, providers can effectively increase the amount of data transmitted over existing channels, thus improving overall network performance.Moreover, secondary multiplexing contributes to better resource management. As organizations strive to reduce operational costs, optimizing existing resources becomes critical. Instead of investing in new hardware or expanding physical networks, businesses can leverage secondary multiplexing to make the most of their current systems. This not only saves money but also minimizes the environmental impact associated with producing new equipment.However, the implementation of secondary multiplexing is not without challenges. The complexity of managing multiple layers of multiplexing can lead to increased latency and potential signal degradation. Therefore, it is essential for engineers and technicians to carefully design and monitor systems employing secondary multiplexing to ensure optimal performance.In conclusion, secondary multiplexing represents a significant advancement in the field of telecommunications. By enabling the efficient combination of multiple signals within existing infrastructure, it enhances data throughput, optimizes resource management, and ultimately improves service quality. As the demand for faster and more reliable communication continues to grow, the importance of understanding and implementing secondary multiplexing will only increase. Organizations that embrace this technology will likely find themselves at a competitive advantage in the ever-evolving landscape of digital communication.

在电信和数据传输领域，效率和优化至关重要。一个在提升这些方面发挥关键作用的概念是二次复用。这个术语指的是将多个信号组合成单个传输通道的方法，从而允许更有效地利用带宽。通过实施二次复用，服务提供商可以最大化其基础设施能力，提高用户的服务质量。要理解二次复用，首先必须掌握复用的基本知识。复用是将多个信号组合在单一介质上的过程。这可以通过几种方式进行，包括时分复用（TDM）和频分复用（FDM）。TDM为每个信号分配不同的时间槽，而FDM则分配不同的频带。然而，随着技术的进步和数据需求的增加，传统的复用方法可能不足以应对。这就是二次复用发挥作用的地方。二次复用允许在现有通道上集成额外的复用层。例如，考虑一种已经在使用的主要复用技术。通过应用二次复用，可以在不需要新的物理线路或通道的情况下引入额外的信号。这在基础设施扩展受到限制或成本高昂的环境中尤为有利。二次复用的一个显著优势是能够提高数据吞吐量。在数字通信无处不在的世界中，快速传输大量数据的能力是无价的。通过利用二次复用，提供商可以有效地增加现有通道上传输的数据量，从而改善整体网络性能。此外，二次复用有助于更好的资源管理。随着组织努力降低运营成本，优化现有资源变得至关重要。企业可以利用二次复用充分利用其当前系统，而不是投资于新硬件或扩展物理网络。这不仅节省了资金，还最小化了与生产新设备相关的环境影响。然而，实施二次复用并非没有挑战。管理多个复用层的复杂性可能导致延迟增加和信号衰减。因此，工程师和技术人员必须仔细设计和监控采用二次复用的系统，以确保最佳性能。总之，二次复用代表了电信领域的重要进步。通过在现有基础设施中实现多个信号的高效组合，它提高了数据吞吐量，优化了资源管理，并最终改善了服务质量。随着对更快和更可靠通信的需求不断增长，理解和实施二次复用的重要性只会增加。那些拥抱这一技术的组织可能会在不断发展的数字通信领域中获得竞争优势。