propagation mode

简明释义

传播波型

英英释义

例句

1.The simulation software allows users to visualize various propagation modes in urban environments.

该模拟软件允许用户可视化城市环境中的各种传播模式。

2.Different propagation modes can lead to varying levels of interference in communication systems.

不同的传播模式可能导致通信系统中干扰水平的变化。

3.Understanding the propagation mode is crucial for designing effective antennas.

理解传播模式对于设计有效的天线至关重要。

4.The researchers studied different propagation modes to optimize the network performance.

研究人员研究了不同的传播模式以优化网络性能。

5.In wireless communication, the choice of propagation mode affects signal strength and quality.

在无线通信中，传播模式的选择会影响信号强度和质量。

作文

In the field of telecommunications and signal processing, understanding the concept of propagation mode is crucial for optimizing communication systems. The term propagation mode refers to the manner in which waves, such as electromagnetic or acoustic waves, travel through a medium. This can include various forms of transmission, such as through air, water, or solid materials, each of which has its own unique characteristics that influence how signals are propagated. For instance, in fiber optics, the propagation mode can dictate how light signals are transmitted through the optical fibers, affecting both speed and clarity of the data being transferred.The significance of propagation mode becomes even more apparent when considering the design and implementation of wireless networks. Different propagation modes can lead to variations in signal strength and quality, which ultimately affect user experience. In urban environments, where buildings and other obstacles are prevalent, understanding how different propagation modes interact with these barriers is essential for effective network planning. Engineers often conduct extensive simulations to determine the optimal placement of antennas and repeaters based on the expected propagation mode in a given area.Moreover, the choice of propagation mode can also impact the overall efficiency of a system. For example, in underwater communication, sound waves are typically used due to their ability to travel long distances without significant attenuation. Here, the propagation mode is primarily influenced by the water temperature, salinity, and depth, all of which can alter the speed and direction of sound waves. By selecting the appropriate propagation mode, engineers can enhance the reliability of communication links in challenging environments.In addition to practical applications, the study of propagation modes also has theoretical implications in physics. Researchers investigate how different modes can be manipulated to achieve desired outcomes, such as minimizing interference or maximizing data throughput. For instance, in a multi-mode fiber optic system, different propagation modes can be utilized to carry multiple signals simultaneously, effectively increasing the bandwidth of the communication channel.Understanding propagation mode is not only limited to telecommunications but extends to various fields including meteorology, acoustics, and even medical imaging. In meteorology, for example, the propagation mode of radio waves can affect weather radar systems, influencing how accurately precipitation is detected. Similarly, in medical imaging, ultrasound waves utilize specific propagation modes to create detailed images of internal body structures, showcasing the versatility of this concept across different domains.In conclusion, the concept of propagation mode is integral to many scientific and engineering disciplines. Its implications range from enhancing communication technologies to improving our understanding of natural phenomena. As technology continues to evolve, the exploration of propagation modes will undoubtedly play a pivotal role in developing more efficient and effective systems that cater to our ever-growing need for connectivity and information exchange.

在电信和信号处理领域，理解传播模式的概念对于优化通信系统至关重要。术语传播模式指的是波（例如电磁波或声波）通过介质传播的方式。这可以包括各种传输形式，例如通过空气、水或固体材料，每种材料都有其独特的特性，影响信号的传播。例如，在光纤通信中，传播模式可以决定光信号如何通过光纤传输，从而影响数据传输的速度和清晰度。当考虑无线网络的设计和实施时，传播模式的重要性变得更加明显。不同的传播模式可能导致信号强度和质量的变化，最终影响用户体验。在城市环境中，建筑物和其他障碍物的存在使得理解不同传播模式如何与这些障碍物相互作用成为有效网络规划的关键。工程师通常会进行广泛的模拟，以根据预期的传播模式确定天线和中继器的最佳放置。此外，传播模式的选择也会影响系统的整体效率。例如，在水下通信中，由于声波能够长距离传播而不显著衰减，因此通常使用声波。在这里，传播模式主要受到水温、盐度和深度的影响，这些因素都可以改变声波的速度和方向。通过选择适当的传播模式，工程师可以提高在复杂环境中通信链路的可靠性。除了实际应用，传播模式的研究在物理学中也具有理论意义。研究人员调查如何操控不同的模式以实现所需的结果，例如最小化干扰或最大化数据吞吐量。例如，在多模光纤系统中，可以利用不同的传播模式同时承载多个信号，有效地增加通信通道的带宽。理解传播模式不仅限于电信，还扩展到气象学、声学甚至医学成像等多个领域。例如，在气象学中，传播模式对天气雷达系统有影响，影响降水的检测准确性。类似地，在医学成像中，超声波利用特定的传播模式创建内部结构的详细图像，展示了这一概念在不同领域的多样性。总之，传播模式的概念是许多科学和工程学科的核心。它的影响范围从增强通信技术到改善我们对自然现象的理解。随着技术的不断发展，对传播模式的探索无疑将在开发更高效、更有效的系统中发挥关键作用，以满足我们日益增长的连接和信息交流需求。