auxiliary excitation

简明释义

辅励磁

英英释义

例句

1.The system's performance improved significantly with the introduction of auxiliary excitation techniques.

引入辅助激励技术后，系统的性能显著提高。

2.Engineers often rely on auxiliary excitation for testing the durability of materials.

工程师们常常依赖辅助激励来测试材料的耐久性。

3.The researchers applied auxiliary excitation to enhance the signal in their experiments.

研究人员应用了辅助激励来增强实验中的信号。

4.In this study, auxiliary excitation was used to improve the accuracy of the measurements.

在这项研究中，使用了辅助激励来提高测量的准确性。

5.The auxiliary excitation method allowed for real-time monitoring of the device's response.

该辅助激励方法允许对设备响应进行实时监控。

作文

In the field of physics and engineering, the term auxiliary excitation refers to a supplementary energy input that enhances the performance or functionality of a system. This concept is particularly important in various applications, such as electrical engineering, signal processing, and control systems. By understanding how auxiliary excitation works, we can improve the efficiency and effectiveness of numerous technologies.To illustrate the significance of auxiliary excitation, let us consider its role in electrical machines. In synchronous motors, for instance, auxiliary excitation is crucial for maintaining the rotor's magnetic field. When the motor operates at varying loads, the excitation system adjusts the current supplied to the rotor, ensuring optimal performance under different conditions. Without this auxiliary excitation, the motor could experience instability, leading to reduced efficiency and potential damage.Similarly, in the realm of signal processing, auxiliary excitation is often employed to enhance the quality of signals being transmitted or received. For example, in communication systems, additional signals can be introduced to improve the clarity and strength of the primary signal. This technique helps mitigate issues such as noise and interference, ultimately leading to better data transmission rates and clearer audio or video outputs.Moreover, auxiliary excitation plays a vital role in control systems, where it can be used to stabilize dynamic systems. In these scenarios, supplementary inputs can help regulate the behavior of the system, ensuring that it responds appropriately to changes in external conditions. This application of auxiliary excitation is especially critical in complex systems, such as those found in aerospace engineering, where precise control is necessary for safety and performance.Understanding auxiliary excitation also has implications in research and development. Engineers and scientists are continually exploring new ways to implement this concept to innovate existing technologies or create entirely new systems. For instance, advancements in materials science may lead to more effective methods of generating auxiliary excitation, resulting in lighter, more efficient devices.In conclusion, auxiliary excitation is a fundamental concept that enhances the performance of various systems across multiple disciplines. Whether in electrical machines, signal processing, or control systems, the ability to provide supplementary energy inputs significantly impacts the efficiency and reliability of technologies. As we continue to advance in our understanding and application of auxiliary excitation, we can expect to see ongoing improvements in the performance of countless devices and systems, paving the way for a more efficient technological future.

在物理学和工程学领域，术语辅助激励指的是一种补充的能量输入，它增强了系统的性能或功能。这个概念在电气工程、信号处理和控制系统等各种应用中尤为重要。通过理解辅助激励的工作原理，我们可以提高众多技术的效率和有效性。为了说明辅助激励的重要性，让我们考虑它在电机中的作用。例如，在同步电动机中，辅助激励对于维持转子的磁场至关重要。当电动机在不同负载下运行时，激励系统会调整供给转子的电流，以确保在不同条件下的最佳性能。如果没有这种辅助激励，电动机可能会出现不稳定，从而导致效率降低和潜在损坏。同样，在信号处理领域，辅助激励常常用于增强传输或接收信号的质量。例如，在通信系统中，可以引入额外的信号来改善主信号的清晰度和强度。这种技术有助于减轻噪声和干扰等问题，最终导致更好的数据传输速度以及更清晰的音频或视频输出。此外，辅助激励在控制系统中也起着至关重要的作用，它可以用于稳定动态系统。在这些情况下，补充输入可以帮助调节系统的行为，确保其对外部条件的变化做出适当反应。这种辅助激励的应用在复杂系统中尤其关键，例如在航空航天工程中，精确的控制对于安全和性能至关重要。理解辅助激励也对研究和开发具有重要意义。工程师和科学家们不断探索实现这一概念的新方法，以创新现有技术或创造全新的系统。例如，材料科学的进步可能导致更有效的生成辅助激励的方法，从而产生更轻、更高效的设备。总之，辅助激励是一个基本概念，增强了多个学科中各种系统的性能。无论是在电气机器、信号处理还是控制系统中，提供补充能量输入的能力显著影响着技术的效率和可靠性。随着我们对辅助激励的理解和应用不断深入，我们可以期待在无数设备和系统的性能上持续改善，为更加高效的技术未来铺平道路。