beam propagation path

简明释义

光束传播轨迹

英英释义

例句

1.The clarity of images in optical devices depends on the accuracy of the beam propagation path 光束传播路径 calculations.

光学设备中图像的清晰度取决于光束传播路径 beam propagation path 计算的准确性。

2.In optical fibers, understanding the beam propagation path 光束传播路径 is crucial for maximizing signal strength.

在光纤中，理解光束传播路径 beam propagation path 对于最大化信号强度至关重要。

3.During the experiment, we tracked the beam propagation path 光束传播路径 using advanced sensors.

在实验过程中，我们使用先进传感器跟踪了光束传播路径 beam propagation path。

4.The beam propagation path 光束传播路径 can be affected by environmental factors such as temperature and humidity.

环境因素如温度和湿度可能会影响光束传播路径 beam propagation path。

5.Engineers must simulate the beam propagation path 光束传播路径 to design more efficient laser systems.

工程师必须模拟光束传播路径 beam propagation path 以设计更高效的激光系统。

作文

In the realm of optics and telecommunications, understanding the concept of beam propagation path is crucial for the successful transmission of signals. The term refers to the specific trajectory that a light beam or electromagnetic wave follows as it moves through different media. This path is not always linear; it can be influenced by various factors such as the refractive index of the materials involved, obstacles in the way, and the initial angle of incidence. By comprehending the beam propagation path, engineers and scientists can optimize systems for better performance and efficiency.When designing optical systems, such as fiber optic networks, one must consider how the beam propagation path will be affected by bends, splices, and connectors. Each of these elements can introduce loss or distortion to the signal, which may degrade the quality of communication. For instance, when light travels through a fiber optic cable, it encounters changes in the refractive index at the core-cladding interface. These changes dictate how the light behaves and ultimately determine the effectiveness of data transmission.Moreover, the beam propagation path is also essential in laser applications. Lasers are designed to emit light in a very specific direction, and understanding the path that this light takes allows for precise targeting in applications ranging from medical surgeries to industrial cutting processes. Any deviation in the beam propagation path can lead to significant errors, making it paramount for operators to have a thorough understanding of this concept.In addition to practical applications, the theoretical aspects of the beam propagation path are equally important. Researchers often use mathematical models to predict how light will propagate through different environments. These models take into account factors such as scattering, diffraction, and absorption, which can all alter the intended path of the beam. By simulating these scenarios, scientists can develop better technologies that minimize losses and enhance signal clarity.Furthermore, advancements in computational methods have allowed for more accurate predictions of the beam propagation path. Techniques such as ray tracing and finite-difference time-domain (FDTD) simulations enable researchers to visualize and analyze how beams interact with various surfaces. This capability is invaluable in fields like astronomy, where understanding the beam propagation path of light from distant stars can reveal critical information about the universe.In conclusion, the beam propagation path is a fundamental concept in optics and telecommunications that encompasses the route taken by light or electromagnetic waves. Its significance spans across various fields, including engineering, medicine, and research. By mastering this concept, professionals can enhance the efficiency and accuracy of their systems, leading to improved outcomes in both practical applications and theoretical explorations. Understanding the beam propagation path not only contributes to technological advancements but also enriches our comprehension of the physical world around us.

在光学和电信领域，理解“光束传播路径”的概念对于信号的成功传输至关重要。这个术语指的是光束或电磁波在不同介质中移动时所遵循的特定轨迹。这条路径并不总是线性的；它可能受到多种因素的影响，例如所涉及材料的折射率、途中的障碍物以及入射角的初始角度。通过理解“光束传播路径”，工程师和科学家可以优化系统，以提高性能和效率。在设计光学系统（如光纤网络）时，必须考虑“光束传播路径”如何受到弯曲、拼接和连接器的影响。这些元素中的每一个都可能引入信号损失或失真，从而降低通信质量。例如，当光通过光纤电缆时，它会在核心-包层界面处遇到折射率的变化。这些变化决定了光的行为，并最终决定数据传输的有效性。此外，“光束传播路径”在激光应用中也至关重要。激光被设计为以非常特定的方向发出光，理解这束光所经过的路径使得在医学手术到工业切割过程中的精确定位成为可能。“光束传播路径”的任何偏差都可能导致重大错误，因此操作人员必须对这一概念有深入的了解。除了实际应用外，“光束传播路径”的理论方面同样重要。研究人员常常使用数学模型来预测光在不同环境中的传播方式。这些模型考虑了散射、衍射和吸收等因素，这些因素都可能改变光束的预期路径。通过模拟这些场景，科学家可以开发出更好的技术，以最小化损失并增强信号清晰度。此外，计算方法的进步使得对“光束传播路径”的预测更加准确。光线追踪和有限差分时域（FDTD）模拟等技术使研究人员能够可视化和分析光束如何与各种表面相互作用。这种能力在天文学等领域是无价的，在那里理解来自遥远恒星的“光束传播路径”可以揭示关于宇宙的重要信息。总之，“光束传播路径”是光学和电信中的一个基本概念，涵盖了光或电磁波所采取的路径。其重要性横跨多个领域，包括工程、医学和研究。通过掌握这一概念，专业人士可以提高其系统的效率和准确性，从而在实际应用和理论探索中获得更好的结果。理解“光束传播路径”不仅有助于技术进步，还丰富了我们对周围物理世界的理解。