transmission path

简明释义

传输路径

英英释义

例句

1.The engineer analyzed the transmission path to ensure optimal signal strength.

工程师分析了传输路径以确保最佳信号强度。

2.In wireless communication, the transmission path can significantly affect performance.

在无线通信中，传输路径可能会显著影响性能。

3.The software simulates the transmission path to predict data loss during transmission.

该软件模拟传输路径以预测传输过程中的数据丢失。

4.We need to identify any obstacles in the transmission path that could cause interference.

我们需要识别在传输路径中可能导致干扰的任何障碍物。

5.Understanding the transmission path is crucial for designing efficient networks.

理解传输路径对于设计高效网络至关重要。

作文

In the realm of communication systems, understanding the concept of a transmission path is crucial for both engineers and users alike. A transmission path refers to the route through which signals travel from one point to another. This can be in various forms, such as electrical signals in wires, light signals in fiber optics, or even radio waves in wireless communication. The efficiency and quality of the communication system largely depend on the characteristics of the transmission path involved.One of the most significant aspects of a transmission path is its impact on signal integrity. As signals traverse through different mediums, they can experience attenuation, distortion, and interference. For instance, in a wired communication system, the distance between the sender and receiver can lead to signal degradation, necessitating the use of repeaters or amplifiers to maintain signal strength. In contrast, optical fibers provide a more robust transmission path, as they are less susceptible to electromagnetic interference and can transmit data over longer distances without significant loss of quality.Moreover, the choice of transmission path can greatly influence the speed of data transfer. In today's fast-paced world, high-speed internet and instantaneous communication are paramount. Fiber optic cables, for example, have become the gold standard for transmission paths in many networks due to their ability to carry vast amounts of data at incredible speeds. On the other hand, traditional copper wires may not provide the same level of performance, leading to slower internet connections and potential bottlenecks in data flow.In addition to physical characteristics, the transmission path also encompasses various protocols and technologies that govern how data is transmitted. For instance, in wireless communication, the transmission path includes the modulation techniques and frequency bands used to send and receive signals. Understanding these protocols is essential for optimizing the transmission path and ensuring reliable and efficient communication.Furthermore, the concept of a transmission path extends beyond just physical and technical considerations. It also involves strategic planning in network design. Engineers must assess the needs of the users, the expected traffic load, and the geographical layout when designing a network's transmission path. This planning ensures that the network can handle current demands while being scalable for future growth.In conclusion, the transmission path is a fundamental concept in communication systems that encompasses the physical, technical, and strategic elements of signal transmission. Whether it is through cables, fiber optics, or wireless technologies, understanding the nuances of the transmission path allows for improved communication efficiency and reliability. As technology continues to evolve, so too will the methods and materials used to create effective transmission paths, ultimately shaping the future of global communication.

在通信系统领域，理解传输路径的概念对工程师和用户都至关重要。传输路径是指信号从一个点传输到另一个点的路线。这可以以多种形式存在，例如电线中的电信号、光纤中的光信号，甚至无线通信中的无线电波。通信系统的效率和质量在很大程度上取决于所涉及的传输路径的特性。传输路径最重要的方面之一是其对信号完整性的影响。当信号通过不同的介质传播时，它们可能会经历衰减、失真和干扰。例如，在有线通信系统中，发送者和接收者之间的距离可能导致信号退化，因此需要使用中继器或放大器来维持信号强度。相比之下，光纤提供了更强大的传输路径，因为它们不太容易受到电磁干扰，并且可以在较长的距离内传输数据，而不会显著降低质量。此外，传输路径的选择可以极大地影响数据传输的速度。在当今快节奏的世界中，高速互联网和瞬时通信至关重要。例如，光纤电缆因其能够以惊人的速度传输大量数据而成为许多网络中传输路径的黄金标准。另一方面，传统的铜线可能无法提供相同水平的性能，导致较慢的互联网连接和潜在的数据流瓶颈。除了物理特性外，传输路径还包括管理数据传输的各种协议和技术。例如，在无线通信中，传输路径包括用于发送和接收信号的调制技术和频率带。理解这些协议对于优化传输路径并确保可靠高效的通信至关重要。此外，传输路径的概念不仅限于物理和技术考虑。它还涉及网络设计中的战略规划。工程师必须评估用户的需求、预期的流量负载和地理布局，以便设计网络的传输路径。这种规划确保网络能够处理当前需求，同时为未来的增长提供可扩展性。总之，传输路径是通信系统中的一个基本概念，涵盖了信号传输的物理、技术和战略元素。无论是通过电缆、光纤还是无线技术，理解传输路径的细微差别可以提高通信的效率和可靠性。随着技术的不断发展，用于创建有效传输路径的方法和材料也将不断演变，最终塑造全球通信的未来。