mixed excitation
简明释义
混合励磁
英英释义
Mixed excitation refers to a condition in which multiple types of stimuli or energy sources are combined to produce a response or effect. | 混合激励指的是多种类型的刺激或能量源结合在一起以产生反应或效果的状态。 |
例句
1.In audio processing, mixed excitation techniques can enhance the quality of synthesized speech.
在音频处理中,混合激励技术可以提高合成语音的质量。
2.By applying mixed excitation, the team was able to improve the performance of their algorithm significantly.
通过应用混合激励,团队能够显著提高其算法的性能。
3.The researchers conducted an experiment using a method of mixed excitation to analyze the behavior of the system.
研究人员使用混合激励的方法进行实验,以分析系统的行为。
4.The mixed excitation model is often used in simulations to better represent real-world conditions.
在模拟中,混合激励模型通常用于更好地表示现实世界条件。
5.The concept of mixed excitation is crucial in understanding complex dynamic systems.
理解复杂动态系统时,混合激励的概念至关重要。
作文
In the realm of modern physics and engineering, the concept of mixed excitation plays a crucial role in understanding various dynamic systems. 混合激励 refers to a situation where multiple sources of excitation or forces act on a system simultaneously, leading to complex interactions and responses. This phenomenon is particularly relevant in fields such as structural engineering, vibration analysis, and control systems, where systems are often subjected to different types of excitations from environmental factors or operational conditions.For instance, consider a building subjected to both wind forces and seismic activities. The combined effect of these two sources of excitation can significantly influence the building's response, necessitating a thorough analysis to ensure its stability and safety. Engineers must account for mixed excitation in their designs to mitigate potential risks associated with such dynamic loads. By using advanced modeling techniques and simulations, they can predict how the structure will behave under various combinations of excitations, allowing for more robust and resilient designs.Another area where mixed excitation is pertinent is in the field of robotics. Robots often operate in environments where they encounter multiple stimuli, such as varying terrains, obstacles, and dynamic objects. Understanding how these different excitations interact is essential for developing effective control algorithms that enable robots to navigate safely and efficiently. For example, a robot designed to traverse uneven ground must be able to adapt its movements based on both the terrain's characteristics and any external forces acting upon it, such as wind or nearby moving objects.Moreover, mixed excitation can also be observed in the context of signal processing. In communication systems, multiple signals can interfere with one another, creating a scenario of mixed excitation that can complicate the extraction of useful information. Techniques such as filtering and modulation are employed to manage these mixed signals, ensuring that the desired information can be accurately transmitted and received. By analyzing the effects of mixed excitation, engineers can improve the reliability and efficiency of communication systems, which is critical in our increasingly interconnected world.In summary, the concept of mixed excitation encompasses a wide range of applications across various disciplines. From structural engineering to robotics and signal processing, understanding how different excitations interact is vital for designing systems that can withstand and adapt to complex environments. As technology continues to advance, the importance of effectively managing mixed excitation will only grow, highlighting the need for ongoing research and innovation in this area. By embracing the challenges presented by mixed excitation, we can pave the way for more resilient structures, smarter robots, and more reliable communication systems, ultimately enhancing our quality of life and safety in an ever-evolving world.
在现代物理学和工程学的领域中,混合激励的概念在理解各种动态系统方面发挥着至关重要的作用。混合激励指的是多个激励源或力量同时作用于一个系统的情况,导致复杂的相互作用和反应。这种现象在结构工程、振动分析和控制系统等领域尤其相关,因为系统通常会受到来自环境因素或操作条件的不同类型的激励。例如,考虑一座建筑物受到风力和地震活动的共同作用。这两种激励源的综合效应可能会显著影响建筑物的反应,因此需要进行全面分析以确保其稳定性和安全性。工程师必须在设计中考虑混合激励,以减轻与这些动态负载相关的潜在风险。通过使用先进的建模技术和仿真,他们可以预测结构在各种激励组合下的行为,从而实现更强大和更有韧性的设计。另一个与混合激励相关的领域是机器人技术。机器人通常在遇到多种刺激的环境中工作,例如变化的地形、障碍物和动态物体。理解这些不同激励如何相互作用对于开发有效的控制算法,使机器人能够安全高效地导航至关重要。例如,设计用于穿越不平坦地面的机器人必须能够根据地形特征和任何外部作用力(如风或附近移动物体)调整其运动。此外,混合激励在信号处理的背景下也可以观察到。在通信系统中,多种信号可能相互干扰,形成混合激励的场景,这可能会使提取有用信息变得复杂。采用过滤和调制等技术来管理这些混合信号,确保所需的信息能够准确传输和接收。通过分析混合激励的影响,工程师可以提高通信系统的可靠性和效率,这在我们日益互联的世界中至关重要。总之,混合激励的概念涵盖了各个学科中的广泛应用。从结构工程到机器人技术和信号处理,理解不同激励如何相互作用对于设计能够承受和适应复杂环境的系统至关重要。随着技术的不断进步,有效管理混合激励的重要性只会增加,突显出在这一领域持续研究和创新的必要性。通过迎接混合激励所带来的挑战,我们可以为更具韧性的结构、更智能的机器人以及更可靠的通信系统铺平道路,最终提高我们的生活质量和安全性,在这个不断发展的世界中。
相关单词
