time of propagation

简明释义

传播时间

英英释义

例句

1.The time of propagation 传播时间 in a vacuum is approximately 299,792 kilometers per second.

真空中的传播时间 传播时间 大约是每秒299,792公里。

2.Engineers must calculate the time of propagation 传播时间 to ensure accurate positioning in GPS technology.

工程师必须计算传播时间 传播时间 以确保GPS技术中的定位准确性。

3.Understanding the time of propagation 传播时间 helps in designing more efficient communication systems.

理解传播时间 传播时间 有助于设计更高效的通信系统。

4.The time of propagation 传播时间 for signals in fiber optics is crucial for achieving high-speed communication.

光纤中信号的传播时间 传播时间 对实现高速通信至关重要。

5.In wireless networks, the time of propagation 传播时间 can affect the overall latency experienced by users.

在无线网络中，传播时间 传播时间 会影响用户体验的整体延迟。

作文

In the field of physics and engineering, the concept of time of propagation refers to the duration it takes for a signal, wave, or any form of energy to travel from one point to another. This concept is crucial in various applications, including telecommunications, acoustics, and even in understanding natural phenomena like earthquakes. The time of propagation can significantly affect the performance and efficiency of systems that rely on the transmission of signals.For instance, in telecommunications, the time of propagation determines how quickly data can be transmitted over a network. When a message is sent from one device to another, it does not arrive instantaneously; instead, there is a delay caused by the distance the signal must travel and the medium through which it travels. Understanding and minimizing this time of propagation is essential for improving communication speeds and ensuring that information is conveyed in real-time, especially in critical applications such as emergency services.Moreover, in the realm of acoustics, the time of propagation plays a vital role in how we perceive sound. Sound waves travel at different speeds depending on the medium—air, water, or solid materials. For example, sound travels faster in water than in air. Musicians and sound engineers must consider the time of propagation when designing concert halls or recording studios to ensure optimal sound quality and clarity. If the time of propagation is not accounted for, it can lead to echoes and delays that disrupt the listening experience.In addition to these practical applications, the time of propagation is also a fundamental concept in scientific research. For instance, seismologists study the time of propagation of seismic waves to determine the location and magnitude of earthquakes. By analyzing how long it takes for these waves to reach different seismic stations, scientists can create detailed maps of earthquake activity and improve early warning systems, ultimately saving lives and property.Furthermore, the time of propagation can be influenced by various factors, including temperature, pressure, and the characteristics of the medium through which the wave travels. For example, in optical fibers used for high-speed internet, the time of propagation can be affected by the refractive index of the glass and any impurities present. Engineers must carefully design these fibers to minimize delays and maximize transmission speeds.In conclusion, the time of propagation is a critical parameter that affects many aspects of our daily lives and technological advancements. Whether in communications, acoustics, or geological studies, understanding this concept allows us to innovate and improve the systems we rely on. As technology continues to evolve, the importance of minimizing the time of propagation will only increase, paving the way for faster and more efficient methods of communication and data transfer. By grasping the significance of the time of propagation, we can better appreciate the intricacies of the world around us and the technologies we use every day.

在物理学和工程学领域，传播时间这一概念指的是信号、波或任何形式的能量从一个点传递到另一个点所需的持续时间。这个概念在各种应用中至关重要，包括电信、声学，甚至在理解自然现象如地震时也非常重要。传播时间可以显著影响依赖信号传输的系统的性能和效率。例如，在电信领域，传播时间决定了数据在网络上传输的速度。当一条消息从一个设备发送到另一个设备时，它并不会瞬间到达；相反，由于信号必须传播的距离以及传播介质，会产生延迟。理解和最小化这个传播时间对于提高通信速度和确保信息实时传递至关重要，尤其是在紧急服务等关键应用中。此外，在声学领域，传播时间在我们感知声音的过程中发挥着重要作用。声波在不同的介质中传播速度不同——空气、水或固体材料。例如，声音在水中传播得比在空气中快。音乐家和音响工程师在设计音乐厅或录音室时必须考虑传播时间，以确保最佳的音质和清晰度。如果不考虑传播时间，可能会导致回声和延迟，从而破坏听觉体验。除了这些实际应用，传播时间也是科学研究中的一个基本概念。例如，地震学家研究地震波的传播时间以确定地震的位置和强度。通过分析这些波到达不同地震站所需的时间，科学家可以创建详细的地震活动地图，并改进预警系统，从而最终拯救生命和财产。此外，传播时间还会受到多种因素的影响，包括温度、压力以及波传播介质的特性。例如，在用于高速互联网的光纤中，传播时间可能会受到玻璃的折射率和任何存在的不纯物质的影响。工程师必须精心设计这些光纤，以最小化延迟并最大化传输速度。总之，传播时间是影响我们日常生活和技术进步的一个关键参数。无论是在通信、声学还是地质研究中，理解这一概念使我们能够创新和改善我们所依赖的系统。随着技术的不断发展，最小化传播时间的重要性只会增加，为更快、更高效的通信和数据传输方法铺平道路。通过掌握传播时间的重要性，我们可以更好地欣赏周围世界的复杂性以及我们每天使用的技术。