effective wave length

简明释义

有效波长

英英释义

例句

1.The effective wave length of this fiber optic cable allows for high-speed data transmission.

这根光纤电缆的有效波长允许高速数据传输。

2.The laser operates at an effective wave length of 532 nm, which is ideal for green light applications.

该激光器的有效波长为532纳米，适用于绿色光应用。

3.The effective wave length in this context refers to the wavelength that produces the desired effect.

在此上下文中，有效波长指的是产生所需效果的波长。

4.Researchers measured the effective wave length to determine the best frequency for the experiment.

研究人员测量了有效波长以确定实验的最佳频率。

5.In telecommunications, the effective wave length can significantly affect signal quality over long distances.

在电信中，有效波长可以显著影响长距离信号质量。

作文

The concept of effective wave length is crucial in various fields, including physics, engineering, and telecommunications. Understanding this term can significantly enhance our comprehension of how waves interact with different media and how they can be manipulated for various applications. In simple terms, the effective wave length refers to the wavelength of a wave that has been adjusted or modified to account for certain factors that affect its propagation. This can include the medium through which the wave travels, the frequency of the wave, and even the presence of obstacles in its path.In physics, the effective wave length is often used when discussing electromagnetic waves, such as light. Light waves can behave differently depending on the medium they are passing through. For instance, when light travels from air into water, its speed decreases, and consequently, its wavelength changes. The effective wave length helps in understanding these changes and predicting how light will behave in different environments.Moreover, in telecommunications, the effective wave length plays a vital role in the design of antennas and transmission lines. Engineers must take into account the effective wave length to ensure that signals are transmitted efficiently and without significant loss. By understanding the effective wave length, engineers can optimize the performance of communication systems, leading to clearer signals and better connectivity.Another important application of the effective wave length is in the field of acoustics. Sound waves also have wavelengths that can be affected by the medium through which they travel, such as air, water, or solid materials. The effective wave length in acoustics helps in designing spaces for optimal sound quality, such as concert halls and recording studios. By manipulating the effective wave length, acousticians can enhance sound clarity and richness, providing a better experience for listeners.In summary, grasping the concept of effective wave length is essential for anyone studying waves and their applications. It allows us to understand how waves behave in different contexts and provides a foundation for advancements in technology and science. Whether in physics, telecommunications, or acoustics, the effective wave length serves as a fundamental principle that aids in the exploration and manipulation of waves. As we continue to delve into the complexities of wave behavior, the effective wave length remains a key factor in unlocking new possibilities and innovations in various fields.In conclusion, the effective wave length is not just a technical term; it represents a bridge between theory and practical application. By mastering this concept, we can contribute to advancements in science and technology, ultimately enhancing our understanding of the world around us and improving our daily lives.

“有效波长”这一概念在物理学、工程学和电信等多个领域中至关重要。理解这个术语可以显著增强我们对波与不同介质相互作用的理解，以及如何操控波以实现各种应用。简单来说，“有效波长”是指经过调整或修改的波长，以考虑影响其传播的某些因素。这可能包括波传播的介质、波的频率，甚至其路径中的障碍物。在物理学中，“有效波长”常用于讨论电磁波，例如光。光波在通过不同介质时会表现出不同的行为。例如，当光从空气进入水中时，其速度会减慢，因此其波长也会发生变化。“有效波长”有助于理解这些变化，并预测光在不同环境中的行为。此外，在电信领域，“有效波长”在天线和传输线设计中扮演着重要角色。工程师必须考虑“有效波长”，以确保信号高效传输且损失最小。通过理解“有效波长”，工程师可以优化通信系统的性能，从而实现更清晰的信号和更好的连接。“有效波长”的另一个重要应用是在声学领域。声波的波长也会受到传播介质的影响，例如空气、水或固体材料。声学中的“有效波长”有助于设计最佳音质的空间，例如音乐厅和录音室。通过操控“有效波长”，声学家可以增强声音的清晰度和丰富性，为听众提供更好的体验。总之，掌握“有效波长”的概念对于任何研究波及其应用的人来说都是必不可少的。它使我们能够理解波在不同背景下的行为，并为科技和科学的进步奠定基础。无论是在物理学、电信还是声学中，“有效波长”作为一个基本原理，有助于探索和操控波。随着我们继续深入研究波动行为的复杂性，“有效波长”仍然是开启各个领域新可能性和创新的关键因素。最后，“有效波长”不仅仅是一个技术术语；它代表了理论与实际应用之间的桥梁。通过掌握这一概念，我们可以为科学和技术的进步做出贡献，最终增强我们对周围世界的理解，改善我们的日常生活。