turbulent propagation

简明释义

湍流传播

英英释义

例句

1.In telecommunications, turbulent propagation can affect signal strength and clarity.

在电信中，湍流传播可能影响信号强度和清晰度。

2.Researchers are investigating the effects of turbulent propagation on ocean currents.

研究人员正在调查湍流传播对海洋洋流的影响。

3.The phenomenon of turbulent propagation can lead to unexpected outcomes in chemical reactions.

在化学反应中，湍流传播现象可能导致意想不到的结果。

4.Understanding turbulent propagation is crucial for predicting weather patterns accurately.

理解湍流传播对准确预测天气模式至关重要。

5.The study of turbulent propagation in fluid dynamics helps engineers design more efficient aircraft.

流体动力学中对湍流传播的研究帮助工程师设计更高效的飞机。

作文

In the study of physics and engineering, the concept of turbulent propagation refers to the chaotic and irregular movement of waves or particles as they travel through a medium. This phenomenon can be observed in various contexts, such as fluid dynamics, sound waves, and even electromagnetic waves. Understanding turbulent propagation is crucial for predicting how these waves behave under different conditions and for developing technologies that rely on wave transmission.To illustrate this concept, let us consider the example of water flowing in a river. When the water flows smoothly, it is said to be in a laminar state, where the flow is orderly and predictable. However, as the flow increases in speed or encounters obstacles, it can transition into a turbulent state. In this turbulent regime, the water exhibits swirling eddies and unpredictable currents, which complicate the understanding of its motion. The turbulent propagation of water waves can lead to increased energy dissipation and mixing, which are important factors in environmental studies and engineering applications.Similarly, in the realm of acoustics, the turbulent propagation of sound waves can affect how we perceive sound in various environments. For instance, in a crowded room, the sound waves produced by multiple sources can interfere with one another, creating a complex auditory landscape. This interference is a result of the turbulent nature of sound wave propagation, making it challenging to isolate individual sounds. Researchers in acoustics strive to understand these interactions to improve sound quality in public spaces, concert halls, and other environments.In the field of telecommunications, turbulent propagation plays a significant role in signal transmission. As radio waves travel through the atmosphere, they encounter various obstacles, such as buildings, trees, and atmospheric conditions. These factors can cause the waves to scatter, reflect, or refract, resulting in a turbulent propagation pattern. Engineers must account for these variables when designing communication systems to ensure reliable and efficient transmission of data.Moreover, turbulent propagation is not limited to physical waves; it also has implications in the realm of information theory. In networks, data packets can experience turbulence in their transmission paths due to congestion, errors, or interference. Understanding how information propagates through these turbulent conditions is essential for optimizing network performance and ensuring data integrity.In conclusion, the concept of turbulent propagation encompasses a range of phenomena observed in various fields, including fluid dynamics, acoustics, telecommunications, and information theory. By studying the chaotic and irregular behaviors of waves and particles, scientists and engineers can develop better models, improve technologies, and enhance our understanding of complex systems. As we continue to explore the intricacies of turbulent propagation, we open the door to innovations that can transform industries and improve our daily lives.

在物理和工程学的研究中，短语turbulent propagation指的是波或粒子在介质中传播时的混乱和不规则运动。这种现象可以在流体动力学、声波甚至电磁波等各种背景下观察到。理解turbulent propagation对于预测这些波在不同条件下的行为以及开发依赖于波传输的技术至关重要。为了说明这一概念，让我们考虑河流中水流动的例子。当水流平稳时，它被称为层流状态，此时流动是有序和可预测的。然而，随着流速的增加或遇到障碍物，水流可能会过渡到湍流状态。在这种湍流状态下，水表现出旋涡和不可预测的水流，这使得理解其运动变得复杂。水波的turbulent propagation可能导致能量的增加耗散和混合，这些都是环境研究和工程应用中的重要因素。同样，在声学领域，声波的turbulent propagation会影响我们在各种环境中对声音的感知。例如，在拥挤的房间里，由多个声源产生的声波可能会相互干扰，形成复杂的听觉景观。这种干扰是声波传播湍流特性的结果，使得隔离单独的声音变得具有挑战性。声学研究人员努力理解这些相互作用，以改善公共空间、音乐厅和其他环境中的音质。在电信领域，turbulent propagation在信号传输中也起着重要作用。当无线电波穿过大气层时，它们会遇到各种障碍物，如建筑物、树木和大气条件。这些因素可能导致波的散射、反射或折射，从而形成湍流传播模式。工程师们必须考虑这些变量，以确保通信系统的可靠性和数据的高效传输。此外，turbulent propagation不仅限于物理波；它在信息理论领域也具有重要意义。在网络中，数据包可能由于拥堵、错误或干扰而经历湍流的传输路径。理解信息在这些湍流条件下是如何传播的，对于优化网络性能和确保数据完整性至关重要。总之，turbulent propagation的概念涵盖了在流体动力学、声学、电信和信息理论等多个领域观察到的一系列现象。通过研究波和粒子的混乱和不规则行为，科学家和工程师可以开发更好的模型，改进技术，并增强我们对复杂系统的理解。随着我们继续探索turbulent propagation的复杂性，我们为能够改变行业和改善日常生活的创新打开了大门。