cophase excitation

简明释义

同相激励

英英释义

例句

1.The engineers utilized cophase excitation 同相激发 to improve the efficiency of the antenna system.

工程师们利用cophase excitation同相激发来提高天线系统的效率。

2.In optical systems, cophase excitation 同相激发 can lead to constructive interference patterns.

在光学系统中，cophase excitation同相激发可以导致建设性干涉图样。

3.The concept of cophase excitation 同相激发 is often applied in quantum mechanics to describe particle interactions.

在量子力学中，cophase excitation同相激发的概念常用于描述粒子间的相互作用。

4.In the study of wave interference, researchers observed that cophase excitation 同相激发 can enhance signal strength significantly.

在波干涉的研究中，研究人员观察到cophase excitation同相激发可以显著增强信号强度。

5.During the experiment, cophase excitation 同相激发 was critical for achieving the desired resonance frequency.

在实验过程中，cophase excitation同相激发对实现所需的共振频率至关重要。

作文

In the realm of physics and engineering, the concept of cophase excitation plays a crucial role in understanding how systems interact with each other. This term refers to the simultaneous excitation of multiple components or systems in phase, which can lead to enhanced performance or efficiency. For instance, in electrical engineering, cophase excitation is often employed in synchronous generators where multiple units operate in harmony to produce a stable output. When these generators are excited in phase, their outputs combine effectively, minimizing losses and maximizing the overall power generation.Moreover, the principle of cophase excitation is not limited to electrical systems but extends to various fields such as acoustics and optics. In acoustics, when sound waves from different sources reach a listener's ear at the same time, they create a richer auditory experience. This phenomenon is akin to cophase excitation, where the coherent addition of sound waves enhances the overall sound quality. Similarly, in optics, lasers utilize cophase excitation to produce coherent light, which is essential for applications ranging from telecommunications to medical devices.Understanding cophase excitation also has practical implications in technology development. Engineers and scientists must consider how to achieve this synchronization in various applications, such as in the design of advanced communication systems. For example, in wireless networks, ensuring that signals from multiple antennas are transmitted in phase can significantly improve data rates and reliability. The study of cophase excitation thus becomes vital in the pursuit of higher efficiency and performance in modern technology.Furthermore, the concept is essential in the field of control systems. In automated systems, maintaining cophase excitation among various actuators can lead to smoother operations and better response times. For instance, in robotics, synchronizing the movements of multiple joints in a robotic arm ensures precise and coordinated actions, which is critical for tasks requiring high accuracy.In conclusion, cophase excitation is a fundamental concept that transcends various disciplines, including electrical engineering, acoustics, optics, and control systems. Its importance lies in the ability to enhance system performance through synchronized excitation. As technology continues to evolve, the principles underlying cophase excitation will remain integral to innovations that strive for efficiency and effectiveness. By mastering this concept, professionals across different fields can contribute to advancements that harness the power of synchronized systems, ultimately leading to improved outcomes in both industrial and everyday applications.

在物理和工程领域，cophase excitation（同相激励）这一概念在理解系统之间的相互作用中发挥着至关重要的作用。这个术语指的是多个组件或系统同时以相位激励，这可以导致性能或效率的提升。例如，在电气工程中，cophase excitation通常用于同步发电机，其中多个单元协调工作以产生稳定的输出。当这些发电机同相激励时，它们的输出有效地结合在一起，最小化损耗并最大化整体发电量。此外，cophase excitation的原理不仅限于电气系统，还扩展到声学和光学等多个领域。在声学中，当来自不同来源的声音波同时到达听者的耳朵时，会创造出更丰富的听觉体验。这种现象类似于cophase excitation，其中声音波的相干叠加增强了整体音质。同样，在光学中，激光利用cophase excitation产生相干光，这对于从电信到医疗设备的应用至关重要。理解cophase excitation在技术开发中也具有实际意义。工程师和科学家必须考虑如何在各种应用中实现这种同步，例如在先进通信系统的设计中。例如，在无线网络中，确保来自多个天线的信号同相传输可以显著提高数据速率和可靠性。因此，研究cophase excitation在追求现代技术的高效性和性能方面变得至关重要。此外，这一概念在控制系统领域中也至关重要。在自动化系统中，保持各个执行器之间的cophase excitation可以导致更平滑的操作和更好的响应时间。例如，在机器人技术中，同步机器手臂中多个关节的运动确保精确和协调的动作，这对于需要高精度的任务至关重要。总之，cophase excitation是一个基本概念，超越了电气工程、声学、光学和控制系统等多个学科。它的重要性在于通过同步激励来增强系统性能。随着技术的不断发展，支撑cophase excitation的原理将继续成为追求高效和有效创新的核心。通过掌握这一概念，各个领域的专业人员可以为利用同步系统的力量做出贡献，从而最终在工业和日常应用中实现更好的结果。