operating wavelength

简明释义

工专长

英英释义

例句

1.Different materials have specific operating wavelengths where they exhibit optimal absorption.

不同材料具有特定的操作波长，在此波长下它们表现出最佳吸收。

2.To optimize the performance of the sensor, we need to adjust its operating wavelength.

为了优化传感器的性能，我们需要调整其操作波长。

3.For this application, we recommend a light source with an operating wavelength of around 500 nm.

对于这个应用，我们建议使用约500纳米的光源，其操作波长。

4.The operating wavelength of the fiber optic system is critical for minimizing signal loss.

光纤系统的操作波长对于最小化信号损失至关重要。

5.The laser operates at an operating wavelength of 850 nm, making it suitable for short-range communication.

该激光器在850纳米的操作波长下工作，适合短距离通信。

作文

In the field of optics and telecommunications, the term operating wavelength is crucial for understanding how various devices function. The operating wavelength refers to the specific wavelength of light that a system is designed to use for optimal performance. Different materials and technologies respond differently to various wavelengths, making it essential to select the correct operating wavelength for a given application.For instance, in fiber optic communication, the choice of operating wavelength significantly affects signal loss and data transmission rates. Commonly used wavelengths for optical fibers are around 850 nm, 1310 nm, and 1550 nm. Each of these wavelengths has unique properties that make them suitable for different types of communication systems. The 1550 nm wavelength, for example, is preferred for long-distance communication due to its lower attenuation compared to shorter wavelengths.Moreover, the operating wavelength is not only important in telecommunications but also in other applications such as lasers, sensors, and imaging systems. In laser technology, the operating wavelength determines the color of the laser light and its interaction with various materials. For example, a laser operating at a wavelength of 532 nm will produce green light, while one at 1064 nm will emit infrared light. The choice of operating wavelength can influence the efficiency of the laser and its suitability for specific tasks, such as cutting or engraving materials.In addition to practical applications, understanding the concept of operating wavelength requires knowledge of the electromagnetic spectrum. The spectrum encompasses all possible wavelengths of electromagnetic radiation, from radio waves to gamma rays. Within this spectrum, visible light occupies a small range, and the operating wavelength of a device often falls within this range or in the infrared region. This knowledge helps engineers and scientists design more effective systems by selecting wavelengths that maximize performance and minimize interference.Furthermore, advancements in technology have led to the development of tunable devices that can operate at multiple operating wavelengths. These devices are particularly useful in applications requiring flexibility and adaptability, such as in telecommunications where bandwidth demands are constantly changing. By being able to adjust the operating wavelength, these devices can optimize performance based on current network conditions.In conclusion, the term operating wavelength plays a vital role in various technological fields, particularly in optics and telecommunications. Understanding its significance allows engineers and researchers to make informed decisions about the design and implementation of systems that rely on light. As technology continues to evolve, the importance of optimizing the operating wavelength will only grow, paving the way for more efficient and effective communication and sensing technologies.

在光学和电信领域，术语工作波长对于理解各种设备的功能至关重要。工作波长指的是系统为最佳性能而设计使用的特定光波长。不同的材料和技术对不同波长的响应各异，因此选择正确的工作波长对于特定应用至关重要。例如，在光纤通信中，工作波长的选择显著影响信号损失和数据传输速率。常用的光纤波长约为850纳米、1310纳米和1550纳米。这些波长每个都有独特的特性，使它们适合不同类型的通信系统。例如，1550纳米波长因其较低的衰减而被优先用于远距离通信，相较于短波长具有更好的性能。此外，工作波长不仅在电信中重要，在激光器、传感器和成像系统等其他应用中也同样关键。在激光技术中，工作波长决定了激光光的颜色及其与各种材料的相互作用。例如，工作在532纳米波长的激光将产生绿色光，而1064纳米的激光将发出红外光。工作波长的选择会影响激光的效率及其在切割或雕刻材料等特定任务中的适用性。了解工作波长的概念还需要掌握电磁谱的知识。电磁谱包含所有可能的电磁辐射波长，从无线电波到伽马射线。在这个谱中，可见光占据一个小范围，而设备的工作波长通常落在这个范围内或红外区域。这样的知识帮助工程师和科学家通过选择最大化性能和最小化干扰的波长来设计更有效的系统。此外，技术的进步导致了可调设备的发展，这些设备可以在多个工作波长下运行。这些设备在需要灵活性和适应性的应用中尤为有用，例如在电信中，带宽需求不断变化。通过能够调整工作波长，这些设备可以根据当前网络条件优化性能。总之，术语工作波长在光学和电信等多个技术领域中发挥着至关重要的作用。理解其重要性使工程师和研究人员能够就依赖光的系统的设计和实施做出明智的决策。随着技术的不断发展，优化工作波长的重要性只会增加，为更高效、更有效的通信和传感技术铺平道路。