guided wave

简明释义

被导波

英英释义

A guided wave is a type of wave that is constrained to propagate along a specific path or within a particular medium, often guided by physical structures such as fibers or channels.

导波是一种波动,它被限制在特定路径或特定介质中传播,通常由物理结构(如光纤或通道)引导。

例句

1.Engineers use guided wave 导波 technology for non-destructive testing of materials.

工程师使用guided wave 导波技术进行材料的无损检测。

2.The guided wave 导波 radar system can detect objects at long distances.

guided wave 导波雷达系统可以在很远的距离内探测物体。

3.In fiber optics, guided wave 导波 structures are essential for efficient signal transmission.

在光纤中,guided wave 导波结构对于高效信号传输至关重要。

4.The concept of guided wave 导波 is crucial in understanding how waves behave in different media.

理解不同介质中波动行为时,guided wave 导波的概念至关重要。

5.The researchers developed a new technology to transmit data using guided wave 导波 propagation.

研究人员开发了一种新技术,通过使用guided wave 导波传播数据。

作文

In the field of physics and engineering, the term guided wave refers to waves that are confined to a certain path or structure, allowing them to propagate with minimal loss of energy. This concept is crucial in various applications, including telecommunications, sensors, and medical imaging. The ability to control and manipulate these waves has opened up new avenues for innovation and efficiency in technology. The phenomenon of guided wave propagation can be observed in many different contexts. For instance, optical fibers utilize guided wave principles to transmit light signals over long distances. The core of the fiber optic cable acts as a waveguide, ensuring that the light remains confined within it, thus reducing signal loss and improving transmission quality. This technology has revolutionized the telecommunications industry, enabling high-speed internet and clear voice communication.Another significant application of guided wave technology is in the field of ultrasound imaging. Medical professionals use ultrasonic waves to create images of internal organs and structures within the body. By employing guided wave techniques, they can enhance the clarity and resolution of these images, leading to more accurate diagnoses and better patient outcomes. The ability to guide these waves through specific pathways allows for targeted imaging of areas of interest, making ultrasound a valuable tool in modern medicine.In addition to telecommunications and medical imaging, guided wave technology is also utilized in structural health monitoring. Engineers deploy sensors that use guided wave propagation to detect flaws or damages in materials such as bridges, pipelines, and aircraft. By analyzing the way these waves travel through a structure, engineers can identify potential issues before they become serious problems, ensuring safety and reliability.The study of guided wave phenomena involves complex mathematical models and simulations. Researchers continuously explore new materials and designs to improve the efficiency and effectiveness of guided wave systems. Innovations in this field could lead to faster data transmission rates, more precise medical imaging techniques, and enhanced safety measures in infrastructure.Moreover, the integration of artificial intelligence and machine learning with guided wave technologies is an exciting frontier. These advancements may enable real-time monitoring and analysis, providing insights that were previously unattainable. For example, AI algorithms could predict the behavior of guided wave signals in various conditions, allowing for adaptive systems that respond dynamically to changing environments.In conclusion, the concept of guided wave is pivotal in multiple domains, showcasing its versatility and importance. From enhancing communication networks to improving healthcare and ensuring structural integrity, guided wave technology is at the forefront of scientific and engineering advancements. As research continues to evolve, we can expect even more groundbreaking applications that leverage the power of guided wave propagation to transform our world.

在物理和工程领域,术语导波指的是被限制在某条路径或结构中的波,使其能够以最小的能量损失传播。这个概念在电信、传感器和医学成像等多个应用中至关重要。控制和操纵这些波的能力为技术创新和效率提升开辟了新的途径。导波传播现象可以在许多不同的环境中观察到。例如,光纤利用导波原理在长距离上传输光信号。光纤电缆的核心部分充当波导,确保光保持在其中,从而减少信号损失并提高传输质量。这项技术革新了电信行业,使高速互联网和清晰的语音通信成为可能。导波技术的另一个重要应用是在超声成像领域。医务人员使用超声波创建内部器官和结构的图像。通过采用导波技术,他们可以增强这些图像的清晰度和分辨率,从而导致更准确的诊断和更好的患者结果。通过特定路径引导这些波的能力使得对感兴趣区域的目标成像成为可能,使超声成为现代医学中的宝贵工具。除了电信和医学成像,导波技术还用于结构健康监测。工程师部署使用导波传播的传感器来检测桥梁、管道和飞机等材料中的缺陷或损伤。通过分析这些波在结构中的传播方式,工程师可以在问题变得严重之前识别潜在问题,从而确保安全和可靠性。对导波现象的研究涉及复杂的数学模型和模拟。研究人员不断探索新材料和设计,以提高导波系统的效率和有效性。该领域的创新可能导致更快的数据传输速率、更精确的医学成像技术以及基础设施的安全措施的增强。此外,将人工智能和机器学习与导波技术相结合是一个令人兴奋的前沿。这些进步可能使实时监测和分析成为可能,提供以前无法获得的洞见。例如,人工智能算法可以预测在各种条件下导波信号的行为,从而允许自适应系统动态响应变化的环境。总之,导波的概念在多个领域中至关重要,展示了其多功能性和重要性。从增强通信网络到改善医疗保健和确保结构完整性,导波技术处于科学和工程进步的前沿。随着研究的不断发展,我们可以期待更多利用导波传播力量的突破性应用,改变我们的世界。