phase locking

简明释义

锁相

英英释义

例句

1.The phenomenon of phase locking can be observed in various biological rhythms, such as circadian cycles.

在各种生物节律中，如昼夜节律，可以观察到相位锁定现象。

2.Engineers use phase locking techniques to improve the stability of communication signals.

工程师使用相位锁定技术来提高通信信号的稳定性。

3.The study of phase locking in auditory processing helps researchers understand how we perceive sounds.

对听觉处理中的相位锁定的研究帮助研究人员理解我们如何感知声音。

4.In neuroscience, phase locking is crucial for understanding how brain regions synchronize during cognitive tasks.

在神经科学中，相位锁定 对于理解大脑区域在认知任务中如何同步至关重要。

5.In music production, phase locking ensures that different tracks align perfectly in time.

在音乐制作中，相位锁定确保不同轨道在时间上完美对齐。

作文

Phase locking is a phenomenon that occurs in various fields of science and engineering, particularly in the study of oscillatory systems. This concept can be observed in many natural and artificial systems, where two or more oscillators synchronize their phases to achieve a stable relationship. Understanding phase locking (相位锁定) is crucial for comprehending how complex systems function and interact with one another.One of the most common examples of phase locking (相位锁定) can be seen in the synchronization of fireflies during mating season. When fireflies gather in a particular area, they often light up in unison, creating a mesmerizing display. This synchronization is a result of phase locking (相位锁定), where the individual fireflies adjust their flashing patterns to align with those of their neighbors. This phenomenon not only enhances their chances of attracting mates but also serves as a fascinating example of how natural systems can exhibit synchronized behavior.In the realm of physics, phase locking (相位锁定) is particularly relevant in the study of coupled oscillators. When two or more oscillators are coupled, they can influence each other's frequencies and phases. As a result, they may lock onto a common frequency, exhibiting a stable phase relationship. This is commonly observed in mechanical systems, such as pendulums or metronomes. When two metronomes are placed on a common base, they eventually synchronize their ticks through phase locking (相位锁定), despite starting at different times.In engineering, phase locking (相位锁定) plays a vital role in communication systems, particularly in phase-locked loops (PLLs). A PLL is an electronic circuit that synchronizes an output signal with a reference signal in terms of frequency and phase. This technology is widely used in radio transmitters and receivers, ensuring that signals are transmitted and received accurately. The ability to maintain synchronization through phase locking (相位锁定) is essential for minimizing errors and improving the quality of communication.Moreover, phase locking (相位锁定) is also significant in neuroscience, particularly in understanding brain rhythms. Research has shown that different regions of the brain can synchronize their activities through phase locking (相位锁定), which is thought to play a crucial role in cognitive processes such as attention and perception. For instance, when individuals focus on a specific task, the brain regions involved may exhibit synchronized oscillations, facilitating efficient information processing.In conclusion, phase locking (相位锁定) is a fundamental concept that spans multiple disciplines, from biology to physics to engineering. Its ability to explain synchronization in various systems provides valuable insights into the underlying mechanisms that govern both natural and artificial phenomena. By studying phase locking (相位锁定), researchers can better understand the dynamics of complex systems, paving the way for advancements in technology and science. As we continue to explore the intricacies of synchronization, the implications of phase locking (相位锁定) will undoubtedly remain a critical area of investigation.

相位锁定是一种现象，发生在科学和工程的多个领域，特别是在振荡系统的研究中。这个概念可以在许多自然和人工系统中观察到，在这些系统中，两个或多个振荡器同步它们的相位，以实现稳定的关系。理解相位锁定（phase locking）对理解复杂系统如何运作及其相互作用至关重要。相位锁定的一个常见例子可以在萤火虫的交配季节中看到。当萤火虫聚集在特定区域时，它们往往会同时发光，创造出迷人的景象。这种同步是相位锁定（phase locking）的结果，其中个别萤火虫调整它们的闪烁模式以与邻居的模式对齐。这一现象不仅增强了它们吸引配偶的机会，也作为自然系统如何表现出同步行为的迷人例子。在物理学领域，相位锁定（phase locking）在耦合振荡器的研究中尤其相关。当两个或多个振荡器被耦合时，它们可以相互影响频率和相位。因此，它们可能锁定到一个共同的频率，表现出稳定的相位关系。这在机械系统中很常见，例如摆锤或节拍器。当两个节拍器放置在一个共同的基础上时，尽管起初时间不同，但它们最终会通过相位锁定（phase locking）来同步它们的滴答声。在工程中，相位锁定（phase locking）在通信系统中发挥着重要作用，特别是在锁相环（PLLs）中。锁相环是一种电子电路，它将输出信号的频率和相位与参考信号同步。这项技术广泛应用于无线电发射机和接收机，确保信号的准确传输和接收。通过相位锁定（phase locking）保持同步的能力对于最小化错误和提高通信质量至关重要。此外，相位锁定（phase locking）在神经科学中也具有重要意义，特别是在理解大脑节律方面。研究表明，大脑的不同区域可以通过相位锁定（phase locking）来同步它们的活动，这被认为在注意力和感知等认知过程中发挥着关键作用。例如，当个体专注于特定任务时，参与的脑区可能表现出同步的振荡，从而促进高效的信息处理。总之，相位锁定（phase locking）是一个跨越多个学科的基本概念，从生物学到物理学再到工程学。它解释了各种系统中的同步能力，为理解支配自然和人工现象的基本机制提供了宝贵的见解。通过研究相位锁定（phase locking），研究人员可以更好地理解复杂系统的动态，为科技和科学的进步铺平道路。随着我们继续探索同步的复杂性，相位锁定（phase locking）的影响无疑将保持在一个关键的研究领域。