multiplexing
简明释义
英[ˈmʌltɪˌpleksɪŋ]美[ˈmʌltɪpleksɪŋ]
n. 多路技术
v. 多重发讯(multiplex 的 ing 形式)
英英释义
单词用法
频分复用;分频多路传输 | |
时分多路复用;时分多路转换 |
同义词
反义词
例句
1.The uplink multiplexing sample transmission system is realized by use of this technology.
并应用这一技术设计实现了上行线复用传输样机系统。
2.Therefore the video multiplexing was born, it has been put into use widely.
所以产生了视频多路复用技术,此技术目前已经得到非常广泛的使用。
3.Now see what the multiplexing mode is.
现在看看多路模式的工作方式。
4.This approach can mean a great deal of multiplexing.
这种方法需要大量的多路复用。
5.The concept behind STDM is similar to TDM, or time division multiplexing.
澳门旅游娱乐有限公司背后的概念类似于TDM,时分多路复用。
6.The uplink multiplexing sample transmission system is realized by use of this technology.
并应用这一技术设计实现了上行线复用传输样机系统。
7.A day-to-day example of multiplexing occurs when we use a cell phone.
当使用手机时,日常的多路复用例子就发生了。
8.Poll approach: A traditional way for I/O multiplexing
poll方法:传统的I/O多路复用方式
9.Digital multiplexing techniques improve the efficiency of data transmission.
数字复用技术提高了数据传输的效率。
10.The video streaming service uses multiplexing to deliver different video streams to various users simultaneously.
该视频流服务使用复用同时向不同用户传递多个视频流。
11.Time division multiplexing (TDM) is used in digital communication to allocate time slots for different signals.
时分复用(TDM)用于数字通信,以为不同信号分配时间段。
12.In a multiplex cinema, multiplexing refers to showing multiple films in different theaters at the same time.
在多厅电影院中,复用指的是在不同的放映厅同时放映多部电影。
13.In telecommunications, multiplexing allows multiple signals to be sent over a single communication channel.
在电信中,复用允许多个信号通过单一通信通道发送。
作文
In the modern world, technology has advanced to a point where we can transmit vast amounts of data efficiently and effectively. One of the key techniques that enable this is multiplexing, a method that allows multiple signals to be combined over a single communication channel. This process is essential in various fields, including telecommunications, broadcasting, and data networking. Understanding multiplexing is crucial for anyone interested in how information is transmitted across different platforms.To begin with, multiplexing can be defined as the technique of combining multiple signals into one signal over a shared medium. This is achieved by allocating different time slots, frequencies, or codes to each signal, allowing them to coexist without interference. For example, in telecommunication systems, multiplexing enables multiple phone calls to be transmitted over a single telephone line, maximizing the utilization of available bandwidth.There are several types of multiplexing, including Time Division Multiplexing (TDM), Frequency Division Multiplexing (FDM), and Code Division Multiplexing (CDM). Each type has its unique advantages and applications. TDM works by dividing time into segments and assigning each signal a specific time slot. This ensures that each signal gets a turn to use the channel, thus preventing overlap. On the other hand, FDM divides the frequency spectrum into channels, allowing multiple signals to be transmitted simultaneously at different frequencies. CDM, however, uses unique codes to differentiate between signals, enabling them to share the same frequency band without interfering with each other.The importance of multiplexing cannot be overstated. In today’s digital age, where the demand for data transmission is ever-increasing, multiplexing plays a vital role in optimizing resources. It allows for more efficient use of infrastructure, reducing costs and improving service quality. For instance, in television broadcasting, multiplexing allows multiple channels to be broadcast over a single frequency, providing viewers with a wider range of options without requiring additional bandwidth.Moreover, multiplexing is not limited to telecommunications. It is also widely used in computer networking. In Local Area Networks (LANs), multiplexing techniques help manage data traffic, ensuring that multiple devices can communicate simultaneously without causing delays or data loss. This is particularly important in environments where numerous users are accessing the network at the same time.In conclusion, multiplexing is a fundamental concept in the realm of data transmission and communication. Its ability to combine multiple signals into one channel makes it an invaluable tool in various industries. As technology continues to evolve, the significance of multiplexing will only grow, paving the way for even more innovative solutions in the future. Understanding this concept is essential for anyone looking to delve deeper into the fields of telecommunications and networking, as it lays the groundwork for comprehending how we connect and communicate in our increasingly digital world.
在现代世界,技术已经发展到一个可以高效有效地传输大量数据的程度。使这一切成为可能的关键技术之一是多路复用,这是一种允许多个信号通过单一通信通道组合的方法。这一过程在电信、广播和数据网络等多个领域中至关重要。理解多路复用对于任何对信息如何在不同平台上传输感兴趣的人来说都是至关重要的。首先,多路复用可以定义为将多个信号组合成一个信号,通过共享媒介进行传输的技术。这是通过为每个信号分配不同的时间段、频率或代码来实现的,使它们能够共存而不发生干扰。例如,在电信系统中,多路复用使得多个电话通话能够通过一条电话线传输,从而最大限度地利用可用带宽。多路复用有几种类型,包括时分多路复用(TDM)、频分多路复用(FDM)和码分多路复用(CDM)。每种类型都有其独特的优点和应用。TDM通过将时间分成段并为每个信号分配特定的时间槽来工作。这确保了每个信号都有机会使用通道,从而防止重叠。而FDM则将频谱划分为通道,允许多个信号同时以不同的频率传输。然而,CDM则使用唯一的代码来区分信号,使它们能够共享同一频段而不会相互干扰。多路复用的重要性不容小觑。在当今数字时代,数据传输需求日益增加,多路复用在优化资源方面发挥着至关重要的作用。它允许更有效地利用基础设施,降低成本并提高服务质量。例如,在电视广播中,多路复用允许多个频道通过单一频率广播,为观众提供更广泛的选择,而无需额外的带宽。此外,多路复用不仅限于电信。它在计算机网络中也被广泛使用。在局域网(LAN)中,多路复用技术帮助管理数据流量,确保多个设备可以同时通信,而不会造成延迟或数据丢失。这在多个用户同时访问网络的环境中尤为重要。总之,多路复用是数据传输和通信领域的基本概念。它将多个信号组合成一个通道的能力使其成为各行各业中不可或缺的工具。随着技术的不断发展,多路复用的重要性只会增加,为未来更具创新性的解决方案铺平道路。理解这一概念对于任何希望深入研究电信和网络领域的人来说都是必不可少的,因为它为理解我们在日益数字化的世界中如何连接和交流奠定了基础。
