compound excitation

简明释义

复励

英英释义

例句

1.The phenomenon of compound excitation 复合激发 is crucial for understanding superconductivity.

理解超导现象时，复合激发 compound excitation 现象至关重要。

2.Engineers utilize compound excitation 复合激发 to enhance the performance of electronic devices.

工程师利用 复合激发 compound excitation 来提高电子设备的性能。

3.The study focused on how compound excitation 复合激发 affects the stability of the material.

研究集中在 复合激发 compound excitation 如何影响材料的稳定性。

4.The researchers observed that the compound excitation 复合激发 increased the overall energy levels in the system.

研究人员观察到，复合激发 compound excitation 增加了系统的整体能量水平。

5.In quantum mechanics, compound excitation 复合激发 can lead to new states of matter.

在量子力学中，复合激发 compound excitation 可以导致新的物质状态。

作文

In the realm of physics and engineering, the concept of compound excitation plays a crucial role in understanding how systems respond to various stimuli. Essentially, compound excitation refers to the simultaneous application of multiple forms of excitation or stimulus to a system, which can lead to complex responses that are not easily predictable. This phenomenon is particularly evident in fields such as structural engineering, where buildings and bridges must withstand various forces such as wind, earthquakes, and human activity all at once.For instance, consider a skyscraper located in an area prone to both high winds and seismic activity. When designing this structure, engineers must account for the compound excitation that occurs during an earthquake while also considering the lateral forces exerted by strong winds. The interplay between these two forms of excitation can significantly affect the overall stability and safety of the building. If only one form of excitation were considered in isolation, the design might fail under real-world conditions, leading to catastrophic consequences.Moreover, the study of compound excitation extends beyond structural applications. In the field of acoustics, for example, sound waves can interact in complex ways when multiple sources are present. This interaction can create phenomena such as constructive and destructive interference, which can alter the perceived loudness and quality of sound. Understanding how compound excitation affects sound propagation is essential for designing concert halls, recording studios, and other spaces where acoustics are paramount.In addition, compound excitation can also be observed in biological systems. For instance, when studying the human body, researchers often examine how multiple stimuli, such as temperature changes, pressure, and chemical signals, interact to produce a physiological response. This is particularly relevant in pharmacology, where the efficacy of a drug can be influenced by the presence of other substances in the body. The concept of compound excitation helps scientists understand the complexities of drug interactions and the potential side effects that may arise from them.To sum up, the idea of compound excitation is integral to a variety of disciplines, highlighting the importance of considering multiple stimuli when analyzing system behaviors. Whether in engineering, acoustics, or biology, recognizing that systems often experience simultaneous excitations allows for more accurate predictions and designs. As we continue to explore the intricacies of the natural world, the understanding of compound excitation will undoubtedly remain a key component in advancing our knowledge and capabilities across numerous fields.

在物理和工程领域，复合激励的概念在理解系统如何对各种刺激做出反应方面起着至关重要的作用。本质上，复合激励是指同时对一个系统施加多种形式的激励或刺激，这可能导致复杂的响应，这些响应并不容易预测。这种现象在结构工程等领域尤为明显，在这些领域中，建筑物和桥梁必须同时承受风、地震和人类活动等各种力量。例如，考虑一座位于高风和地震活动频繁地区的摩天大楼。在设计这座结构时，工程师必须考虑在地震期间发生的复合激励，同时还要考虑强风施加的侧向力。这两种激励之间的相互作用可以显著影响建筑物的整体稳定性和安全性。如果只单独考虑一种激励，设计可能会在现实条件下失败，导致灾难性后果。此外，复合激励的研究超越了结构应用。在声学领域，例如，当多个声源同时存在时，声波可以以复杂的方式相互作用。这种相互作用可以产生如建设性和破坏性干涉等现象，这可以改变声音的响度和质量。理解复合激励如何影响声音传播对于设计音乐厅、录音室以及其他声学至关重要的空间是必不可少的。此外，复合激励也可以在生物系统中观察到。例如，在研究人体时，研究人员经常检查温度变化、压力和化学信号等多种刺激如何相互作用以产生生理反应。这在药理学中特别相关，因为药物的有效性可能会受到体内其他物质存在的影响。复合激励的概念帮助科学家理解药物相互作用的复杂性以及可能由此产生的副作用。总之，复合激励的理念对各种学科至关重要，突显了在分析系统行为时考虑多重刺激的重要性。无论是在工程、声学还是生物学中，认识到系统通常经历同时激励的事实，可以使预测和设计更为准确。随着我们继续探索自然世界的复杂性，复合激励的理解无疑将继续成为推动我们在多个领域知识和能力进步的关键组成部分。