injection locking

简明释义

注入锁定

英英释义

例句

1.The concept of injection locking is crucial for enhancing the coherence of light sources, translated as 注入锁定.

概念上的注入锁定对增强光源的相干性至关重要，英文为injection locking。

2.The laser system achieved stability through injection locking, which is known as 注入锁定 in Chinese.

激光系统通过注入锁定实现了稳定性，英文称为injection locking。

3.In telecommunications, injection locking helps synchronize multiple signals, which is 注入锁定 in Chinese.

在电信领域，注入锁定有助于同步多个信号，中文称为injection locking。

4.Researchers are studying injection locking techniques to improve laser performance, known as 注入锁定.

研究人员正在研究注入锁定技术以提高激光性能，英文为injection locking。

5.By applying injection locking, the oscillator's frequency was precisely controlled, referred to as 注入锁定 in Mandarin.

通过应用注入锁定，振荡器的频率得到了精确控制，中文称为injection locking。

作文

Injection locking is a fascinating phenomenon observed in the field of laser physics and electronics. It refers to the process where an external signal, often referred to as the 'injection signal,' influences the frequency and phase of a laser or oscillator. This effect can be particularly useful in various applications, including telecommunications, precision measurement, and even in the development of advanced technologies such as quantum computing. Understanding injection locking can provide insights into how we can control and manipulate light and sound waves for practical uses.The concept of injection locking can be explained through a simple analogy. Imagine a child on a swing; if another child pushes the swing at just the right moment, the swing will move higher and faster than it would on its own. Similarly, when an external signal is introduced at the right frequency and phase, it can 'push' the laser or oscillator, locking its output to the frequency of the external signal. This synchronization leads to increased stability and coherence of the emitted light or signal.In practice, injection locking is utilized in various technologies. For instance, in fiber-optic communication systems, lasers are often locked to a stable reference frequency to ensure that the data transmitted remains consistent and clear. This is crucial in maintaining the integrity of communications over long distances, where even minor fluctuations can lead to significant errors.Another application of injection locking is in the field of metrology, where precise measurements are required. By locking a laser to a known frequency, scientists can achieve highly accurate measurements of distance, time, and other physical properties. This technique has been instrumental in advancing fields such as gravitational wave detection, where precision is paramount.Moreover, injection locking plays a vital role in the development of new technologies. For example, in quantum computing, researchers are exploring ways to use locked lasers to create entangled photons, which are essential for quantum information processing. The ability to control the phase and frequency of light through injection locking opens up new avenues for innovation in this rapidly evolving field.Despite its advantages, injection locking also poses challenges. The process requires careful tuning of the external signal's frequency and phase to achieve the desired locking effect. If not done correctly, it can lead to instability or undesired oscillations. Researchers continue to study these dynamics to improve the reliability and efficiency of injection locking systems.In conclusion, injection locking is a powerful tool in the realm of laser physics and electronics. Its ability to stabilize frequencies and enhance coherence makes it invaluable in various applications, from telecommunications to advanced scientific research. As technology continues to advance, the understanding and application of injection locking will undoubtedly play a crucial role in shaping the future of numerous fields. By mastering this concept, we can harness the power of light and sound in innovative ways, paving the way for breakthroughs that were once thought impossible.

注入锁定是激光物理和电子学领域观察到的一种迷人现象。它指的是一个外部信号（通常称为“注入信号”）影响激光器或振荡器的频率和相位的过程。这种效应在各种应用中尤其有用，包括电信、精密测量，甚至在量子计算等先进技术的发展中。理解注入锁定可以提供对我们如何控制和操纵光和声波以供实际使用的洞察。注入锁定的概念可以通过一个简单的类比来解释。想象一下，一个孩子在秋千上；如果另一个孩子在恰当的时刻推秋千，秋千将比自己单独摆动得更高、更快。类似地，当以正确的频率和相位引入外部信号时，它可以“推动”激光器或振荡器，将其输出锁定到外部信号的频率。这种同步导致发射的光或信号的稳定性和相干性增强。在实践中，注入锁定被广泛应用于各种技术中。例如，在光纤通信系统中，激光器通常被锁定到稳定的参考频率，以确保传输的数据保持一致和清晰。这在维持长距离通信的完整性方面至关重要，因为即使是微小的波动也可能导致显著的错误。注入锁定的另一个应用是在计量学领域，在那里需要精确的测量。通过将激光器锁定到已知频率，科学家可以实现对距离、时间和其他物理属性的高度准确测量。这项技术在推进引力波探测等领域中发挥了重要作用，在这些领域中，精度是至关重要的。此外，注入锁定在新技术的发展中也扮演着重要角色。例如，在量子计算中，研究人员正在探索利用锁定激光器生成纠缠光子的方式，这对于量子信息处理至关重要。通过注入锁定控制光的相位和频率的能力为这一快速发展的领域开辟了新的创新途径。尽管有其优势，注入锁定也面临挑战。该过程需要仔细调谐外部信号的频率和相位，以实现期望的锁定效果。如果没有正确完成，可能会导致不稳定或不必要的振荡。研究人员继续研究这些动态，以提高注入锁定系统的可靠性和效率。总之，注入锁定是激光物理和电子学领域的一种强大工具。它稳定频率和增强相干性的能力使其在电信到先进科学研究的各种应用中都具有不可或缺的价值。随着技术的不断进步，对注入锁定的理解和应用无疑将在塑造众多领域的未来中发挥关键作用。通过掌握这一概念，我们可以以创新的方式利用光和声的力量，为曾经被认为不可能的突破铺平道路。