compound excitation

简明释义

复激励

英英释义

例句

1.In our experiment, we observed compound excitation 复合激励 leading to unexpected results.

在我们的实验中，我们观察到复合激励 compound excitation 导致了意想不到的结果。

2.Researchers are exploring the implications of compound excitation 复合激励 in quantum mechanics.

研究人员正在探索复合激励 compound excitation 在量子力学中的影响。

3.The study demonstrated that the effects of compound excitation 复合激励 on the system were significant.

研究表明，复合激励 compound excitation 对系统的影响是显著的。

4.The phenomenon of compound excitation 复合激励 can be observed in various physical systems.

在各种物理系统中都可以观察到复合激励 compound excitation 现象。

5.The model incorporates compound excitation 复合激励 to simulate real-world conditions.

该模型结合了复合激励 compound excitation 来模拟现实条件。

作文

In the realm of physics and engineering, the concept of compound excitation plays a crucial role in understanding complex systems. This term refers to the simultaneous application of multiple forms of energy or stimuli to a system, which can lead to various responses that are not observed when each form of excitation is applied individually. For instance, in mechanical systems, compound excitation might involve the combined effects of thermal, acoustic, and vibrational forces acting on a structure. Understanding how these different types of excitations interact can help engineers design more resilient structures that can withstand diverse environmental conditions.One of the most significant applications of compound excitation is in the field of materials science. When developing new materials, scientists often need to consider how these materials will respond under various conditions. For example, a new composite material might be subjected to thermal stress while simultaneously being exposed to mechanical loads. The interaction between these two forms of excitation can significantly alter the material's properties, leading to unexpected failures or enhanced performance. Therefore, a thorough understanding of compound excitation becomes essential for predicting how materials will behave in real-world applications.Moreover, compound excitation is also relevant in the study of biological systems. Living organisms are constantly exposed to multiple stimuli, such as temperature changes, chemical signals, and physical forces. These stimuli can interact in complex ways, influencing cellular responses and overall organism behavior. For instance, in neurobiology, researchers examine how sensory neurons respond to multiple stimuli, which can lead to a better understanding of how the brain processes information. By studying compound excitation, scientists can gain insights into how organisms adapt to their environments and how they might respond to changes in those environments.The implications of compound excitation extend beyond scientific inquiry; they also have practical applications in technology and engineering. For example, in the design of electronic devices, engineers must consider how various electromagnetic fields can interact with one another. If multiple signals are transmitted simultaneously, understanding compound excitation allows engineers to mitigate interference and enhance the performance of communication systems. This is particularly important in the development of wireless technologies, where multiple signals often overlap, leading to potential disruptions.In conclusion, the concept of compound excitation is integral to various fields, from physics and engineering to biology and technology. By studying how different forms of excitation interact, researchers and engineers can better understand complex systems and improve the design and functionality of materials and devices. As our world becomes increasingly interconnected and technologically advanced, the importance of comprehending compound excitation will only grow, paving the way for innovations that can address the challenges of tomorrow. Ultimately, mastering this concept will enable us to harness the power of multiple stimuli to create more effective solutions across a wide range of disciplines.

在物理和工程领域，复合激励的概念在理解复杂系统中起着至关重要的作用。这个术语指的是同时对一个系统施加多种形式的能量或刺激，这可能导致与单独施加每种激励时观察到的不同反应。例如，在机械系统中，复合激励可能涉及热、声和振动力共同作用于结构的影响。了解这些不同类型的激励如何相互作用，可以帮助工程师设计出更具韧性的结构，以承受多样的环境条件。复合激励最重要的应用之一是在材料科学领域。在开发新材料时，科学家们常常需要考虑这些材料在各种条件下的反应。例如，一种新型复合材料可能在受到热应力的同时暴露于机械载荷下。这两种激励之间的相互作用可能显著改变材料的性质，导致意想不到的故障或增强的性能。因此，深入理解复合激励对于预测材料在现实世界应用中的表现变得至关重要。此外，复合激励在生物系统的研究中也具有相关性。生物体不断受到多种刺激，例如温度变化、化学信号和物理力量。这些刺激可以以复杂的方式相互作用，影响细胞反应和整体生物体行为。例如，在神经生物学中，研究人员检查感官神经元如何对多种刺激作出反应，这可以帮助我们更好地理解大脑如何处理信息。通过研究复合激励，科学家们可以深入了解生物体如何适应其环境，以及它们如何可能对这些环境的变化作出反应。复合激励的影响不仅限于科学研究；它们在技术和工程中的实际应用也同样重要。例如，在电子设备的设计中，工程师必须考虑各种电磁场如何相互作用。如果多个信号同时传输，理解复合激励使工程师能够减轻干扰并增强通信系统的性能。这在无线技术的发展中尤为重要，因为多个信号常常重叠，可能导致潜在的干扰。总之，复合激励的概念在物理、工程、生物学和技术等多个领域中都是不可或缺的。通过研究不同激励形式的相互作用，研究人员和工程师可以更好地理解复杂系统，并改善材料和设备的设计与功能。随着我们的世界变得越来越互联和技术先进，理解复合激励的重要性只会增加，为解决未来的挑战铺平道路。最终，掌握这一概念将使我们能够利用多种刺激的力量，在广泛的学科中创造更有效的解决方案。