lock-in synchronism

简明释义

进入同步

英英释义

例句

1.Achieving lock-in synchronism is crucial for the success of this communication protocol.

实现锁定同步对这个通信协议的成功至关重要。

2.The team was excited to see lock-in synchronism during their tests, as it indicated a stable system.

团队在测试中看到锁定同步时感到兴奋，因为这表明系统稳定。

3.The engineers implemented a system that achieved lock-in synchronism to ensure all components operated in unison.

工程师们实施了一种系统，实现了锁定同步，以确保所有组件齐心协作。

4.In the experiment, we observed lock-in synchronism between the oscillators at specific frequencies.

在实验中，我们观察到特定频率下振荡器之间的锁定同步。

5.The researchers noted that lock-in synchronism can enhance the performance of quantum systems.

研究人员指出，锁定同步可以提高量子系统的性能。

作文

In the realm of physics and engineering, the concept of lock-in synchronism plays a crucial role in understanding how systems can achieve stability and coherence. This phenomenon occurs when oscillating systems synchronize their frequencies due to feedback mechanisms, resulting in enhanced performance and efficiency. For instance, consider a group of pendulum clocks hanging on a wall. Initially, they may swing independently, each at its own pace. However, as time progresses, they begin to influence one another through subtle vibrations in the air or mechanical coupling. Eventually, they reach a state of lock-in synchronism, where all clocks swing in unison, demonstrating the power of synchronization in complex systems.The importance of lock-in synchronism extends beyond simple pendulums. In electrical engineering, this principle is vital for maintaining the stability of power grids. When various generators operate in a synchronized manner, the overall system becomes more resilient to disturbances. If one generator experiences a fluctuation, the others can quickly adjust to compensate, ensuring a steady supply of electricity. This illustrates how lock-in synchronism can lead to enhanced reliability in critical infrastructures.Moreover, lock-in synchronism is not limited to mechanical or electrical systems; it is also observable in biological contexts. For example, fireflies are known to synchronize their flashing patterns during mating rituals. This synchronization increases the chances of attracting mates, illustrating the evolutionary advantages that can arise from lock-in synchronism. Such natural phenomena highlight the interconnectedness of life and the intricate ways in which organisms can communicate and coordinate with one another.In the field of neuroscience, researchers have discovered that lock-in synchronism can occur among neurons within the brain. When neurons fire in synchrony, they can create more robust signals that enhance cognitive functions such as memory and learning. This finding underscores the significance of synchronization in the brain's operation, suggesting that achieving lock-in synchronism among neural networks could be key to optimizing mental processes.Despite its many benefits, lock-in synchronism can also pose challenges. In certain systems, excessive synchronization can lead to instability or catastrophic failure. For instance, in financial markets, if too many traders act on similar information simultaneously, it can trigger a market crash. This phenomenon, often referred to as herd behavior, exemplifies the darker side of synchronization, where lock-in synchronism leads to negative outcomes.In conclusion, the concept of lock-in synchronism is a fascinating area of study that spans multiple disciplines, from physics to biology and even finance. Understanding how systems can achieve synchronization allows us to harness its benefits while being mindful of its potential pitfalls. As we continue to explore the intricacies of synchronization in various fields, we may uncover new applications that leverage lock-in synchronism for the betterment of society. Whether in technology, nature, or human interactions, the principles of synchronization remind us of the importance of coherence and collaboration in achieving optimal outcomes.

在物理和工程领域，锁定同步的概念在理解系统如何实现稳定性和一致性方面起着至关重要的作用。这种现象发生在振荡系统由于反馈机制而同步其频率，从而导致性能和效率的提高。例如，考虑一组挂在墙上的摆钟。最初，它们可能独立摆动，各自以自己的节奏。然而，随着时间的推移，它们开始通过空气中的微小振动或机械耦合相互影响。最终，它们达到一种锁定同步的状态，所有钟表都齐心协力摆动，展示了复杂系统中同步的力量。锁定同步的重要性不仅限于简单的摆钟。在电气工程中，这一原理对于维持电网的稳定性至关重要。当各种发电机以同步的方式运作时，整个系统变得更加抗干扰。如果一个发电机经历波动，其他发电机可以迅速调整以补偿，确保电力的稳定供应。这说明了锁定同步如何导致关键基础设施的可靠性增强。此外，锁定同步不仅限于机械或电气系统；它在生物学背景中也可观察到。例如，萤火虫在交配仪式中以同步的闪光模式而闻名。这种同步增加了吸引伴侣的机会，说明了锁定同步带来的进化优势。这样的自然现象突显了生命的相互联系，以及生物体之间沟通和协调的复杂方式。在神经科学领域，研究人员发现大脑中的神经元也可以发生锁定同步。当神经元同步放电时，它们可以产生更强的信号，从而增强记忆和学习等认知功能。这一发现强调了同步在大脑运作中的重要性，表明实现神经网络之间的锁定同步可能是优化心理过程的关键。尽管有许多好处，锁定同步也可能带来挑战。在某些系统中，过度同步可能导致不稳定或灾难性故障。例如，在金融市场中，如果太多交易者同时对类似信息采取行动，可能会引发市场崩溃。这种现象通常被称为羊群行为，体现了同步的阴暗面，其中锁定同步导致负面结果。总之，锁定同步的概念是一个跨多个学科的迷人研究领域，从物理到生物学甚至金融。理解系统如何实现同步使我们能够利用其好处，同时注意其潜在的陷阱。随着我们继续探索各个领域中同步的复杂性，我们可能会发现新的应用，利用锁定同步造福社会。无论是在技术、自然还是人际互动中，同步的原则提醒我们在实现最佳结果时一致性和合作的重要性。