beam jitter

简明释义

束摆动

英英释义

例句

1.The satellite communication system experienced significant beam jitter 波束抖动 during the storm, causing interruptions in service.

在暴风雨期间，卫星通信系统经历了显著的波束抖动，导致服务中断。

2.The video feed was affected by beam jitter 波束抖动, resulting in a poor viewing experience for the audience.

视频信号受到波束抖动的影响，导致观众观看体验不佳。

3.To enhance performance, we need to address the issue of beam jitter 波束抖动 in our optical network.

为了提高性能，我们需要解决光网络中的波束抖动问题。

4.Engineers are working to minimize beam jitter 波束抖动 in the new laser system to improve accuracy.

工程师们正在努力减少新激光系统中的波束抖动以提高准确性。

5.The drone's navigation system struggled with beam jitter 波束抖动, making it difficult to maintain a stable flight path.

无人机的导航系统因波束抖动而难以维持稳定的飞行路径。

作文

In the field of telecommunications and optics, the term beam jitter refers to the small, rapid fluctuations in the position or angle of a light beam or signal. These fluctuations can significantly impact the performance of communication systems, particularly in fiber optics and laser applications. Understanding beam jitter is crucial for engineers and scientists working to improve the reliability and efficiency of data transmission. When light travels through optical fibers, it is essential that the beam remains stable and focused. However, various factors such as temperature changes, mechanical vibrations, and even the inherent properties of the materials used can cause the beam to deviate from its intended path. This deviation is what we refer to as beam jitter. In practical terms, beam jitter can lead to increased error rates in data transmission, resulting in slower speeds and reduced overall performance. To mitigate the effects of beam jitter, engineers employ several strategies. One common approach is to use advanced stabilization techniques, which may involve feedback systems that continuously monitor the beam's position and make real-time adjustments to keep it on track. Additionally, the design of optical components can be optimized to minimize susceptibility to external disturbances that contribute to beam jitter. Another important aspect of understanding beam jitter is its measurement. Various tools and methods have been developed to quantify the degree of jitter present in a system. For instance, high-speed cameras and specialized sensors can capture the rapid movements of a beam, allowing researchers to analyze its stability. This data is invaluable for improving existing technologies and developing new solutions to combat the challenges posed by beam jitter. As technology advances, the demand for high-speed data transmission continues to grow. Consequently, addressing issues related to beam jitter becomes increasingly critical. Innovations in materials science, signal processing, and optical engineering hold the potential to significantly reduce the impact of jitter on communication systems. Researchers are exploring novel approaches, such as adaptive optics and machine learning algorithms, to enhance the performance of optical systems in the presence of beam jitter. In conclusion, beam jitter is a significant concern in the realm of optics and telecommunications. Its ability to disrupt data transmission makes it a focal point for ongoing research and development. By understanding the causes and effects of beam jitter, engineers and scientists can devise more effective strategies to ensure stable and reliable communication systems. As we continue to push the boundaries of technology, addressing beam jitter will play a pivotal role in achieving faster, more efficient data transfer capabilities in the future.

在电信和光学领域，术语beam jitter指的是光束或信号位置或角度的小幅、快速波动。这些波动会显著影响通信系统的性能，尤其是在光纤和激光应用中。理解beam jitter对工程师和科学家而言至关重要，他们致力于提高数据传输的可靠性和效率。当光通过光纤传播时，保持光束的稳定和聚焦至关重要。然而，温度变化、机械振动甚至所用材料的固有特性等各种因素都可能导致光束偏离其预定路径。这种偏差就是我们所说的beam jitter。从实际角度来看，beam jitter可能导致数据传输中的错误率增加，从而导致速度变慢和整体性能降低。为了减轻beam jitter的影响，工程师采用了几种策略。一种常见的方法是使用先进的稳定技术，这可能涉及反馈系统，持续监测光束的位置并实时调整以保持其轨迹。此外，光学组件的设计可以优化，以最小化对外部干扰的敏感性，这些干扰会导致beam jitter。理解beam jitter的另一个重要方面是其测量。已经开发出多种工具和方法来量化系统中存在的抖动程度。例如，高速摄像机和专用传感器可以捕捉光束的快速运动，使研究人员能够分析其稳定性。这些数据对于改进现有技术和开发新解决方案以应对beam jitter带来的挑战至关重要。随着技术的进步，对高速数据传输的需求不断增长。因此，解决与beam jitter相关的问题变得越来越关键。材料科学、信号处理和光学工程的创新有可能显著减少抖动对通信系统的影响。研究人员正在探索新颖的方法，例如自适应光学和机器学习算法，以增强光学系统在存在beam jitter时的性能。总之，beam jitter是光学和电信领域的一个重要关注点。它干扰数据传输的能力使其成为持续研究和发展的重点。通过理解beam jitter的原因和影响，工程师和科学家可以制定更有效的策略，以确保稳定和可靠的通信系统。随着我们继续突破技术的界限，解决beam jitter将对未来实现更快、更高效的数据传输能力发挥关键作用。