resonant mode

简明释义

谐振模

英英释义

例句

1.The engineer analyzed the structure to identify its resonant mode (共振模式) to ensure stability under various conditions.

工程师分析了结构，以识别其共振模式 (resonant mode)，以确保在各种条件下的稳定性。

2.The resonant mode (共振模式) of the musical instrument determines its unique sound characteristics.

乐器的共振模式 (resonant mode) 决定了其独特的声音特征。

3.In acoustic design, understanding the resonant mode (共振模式) of a room can help optimize sound quality.

在声学设计中，了解房间的共振模式 (resonant mode) 可以帮助优化音质。

4.Researchers used simulations to visualize the resonant mode (共振模式) of the vibrating membrane.

研究人员使用模拟来可视化振动膜的共振模式 (resonant mode)。

5.The resonant mode (共振模式) of the bridge was tested to predict its behavior during an earthquake.

桥梁的共振模式 (resonant mode) 被测试以预测其在地震中的行为。

作文

In the field of physics and engineering, the concept of resonant mode plays a crucial role in understanding how systems respond to external forces. A resonant mode refers to a specific pattern of oscillation that occurs when a system is subjected to a periodic force at a particular frequency. This phenomenon is evident in various applications, from musical instruments to architectural design, and even in the mechanics of bridges and buildings. When a system vibrates in its resonant mode, it can achieve significantly greater amplitudes than at other frequencies. For instance, consider a guitar string. When plucked, the string vibrates at its fundamental frequency, producing a sound that resonates with the air around it. The specific ways in which the string vibrates—its resonant modes—determine the pitch and tone of the note produced. Similarly, in architectural engineering, buildings are designed to withstand vibrations caused by wind or earthquakes. Engineers must calculate the resonant modes of structures to ensure they do not resonate with these external forces, which could lead to catastrophic failures.The importance of understanding resonant modes extends beyond the physical sciences. In music, composers and musicians utilize the principles of resonance to create harmonies and melodies that evoke emotional responses in listeners. The resonance of a room can enhance or dampen the sound produced by an instrument, highlighting the significance of resonant modes in performance settings. Moreover, the study of resonant modes has implications in technology, particularly in the design of electronic circuits and components. For example, in radio transmission, antennas are designed to operate at specific resonant modes to maximize signal strength and clarity. Understanding the resonant modes of circuits can lead to more efficient designs and improved performance in communication technologies.In conclusion, the concept of resonant mode is integral to various disciplines, providing insights into the behavior of systems under oscillatory conditions. Whether in the arts, architecture, or technology, recognizing and harnessing the power of resonant modes can lead to innovations and advancements that enhance our understanding and interaction with the world around us. As we continue to explore the dynamics of resonance, we uncover new possibilities for creativity and functionality in our designs and applications.

在物理和工程领域，共振模式的概念在理解系统如何响应外部力方面起着至关重要的作用。共振模式是指当一个系统受到特定频率的周期性力量时，发生的特定振荡模式。这种现象在各种应用中都很明显，从乐器到建筑设计，甚至在桥梁和建筑的力学中。当一个系统以其共振模式振动时，它可以达到比其他频率显著更大的振幅。例如，考虑吉他弦。当被拨动时，弦以其基频振动，产生与周围空气共鸣的声音。弦的具体振动方式——其共振模式——决定了所产生音符的音高和音调。类似地，在建筑工程中，建筑物的设计旨在承受风或地震引起的振动。工程师必须计算结构的共振模式，以确保它们不会与这些外部力量共振，这可能导致灾难性的失败。理解共振模式的重要性超越了物理科学。在音乐中，作曲家和音乐家利用共振原理创造出引发听众情感反应的和声和旋律。房间的共鸣可以增强或抑制乐器发出的声音，突显了在表演场合中共振模式的重要性。此外，共振模式的研究在技术上也有影响，特别是在电子电路和组件的设计中。例如，在无线电传输中，天线被设计为在特定的共振模式下工作，以最大化信号强度和清晰度。理解电路的共振模式可以导致更高效的设计和通信技术的性能提升。总之，共振模式的概念对于各个学科都是至关重要的，为我们提供了关于系统在振荡条件下行为的见解。无论是在艺术、建筑还是技术中，认识并利用共振模式的力量可以带来创新和进步，增强我们对周围世界的理解和互动。随着我们继续探索共振的动态，我们揭示了在我们的设计和应用中创造力和功能的新可能性。