resonance capture
简明释义
共振俘获
英英释义
例句
1.During the experiment, the team utilized resonance capture to identify specific frequencies that caused structural vibrations.
在实验过程中,团队利用共振捕获来识别导致结构振动的特定频率。
2.Artists are exploring resonance capture techniques to create immersive sound installations in galleries.
艺术家们正在探索共振捕获技术,以在画廊中创建沉浸式声音装置。
3.The application of resonance capture in medical imaging has significantly improved the clarity of scans.
在医学成像中应用共振捕获显著提高了扫描的清晰度。
4.In the latest research on sound waves, scientists have developed a technique called resonance capture to enhance audio quality.
在最新的声波研究中,科学家们开发了一种名为共振捕获的技术,以增强音质。
5.The engineer explained how resonance capture can be used in architectural design to improve acoustics in concert halls.
工程师解释了如何在建筑设计中使用共振捕获来改善音乐厅的声学效果。
作文
In the realm of physics and engineering, the term resonance capture refers to the phenomenon where a system absorbs energy at specific frequencies, leading to an amplification of oscillations. This concept is not only crucial in understanding various natural phenomena but also plays a significant role in technological applications. For instance, in the design of musical instruments, the resonance capture effect is harnessed to enhance sound quality. When a musician plays a note, the instrument vibrates at certain frequencies, capturing and amplifying those vibrations, resulting in a rich and full sound. Similarly, in the field of architecture, engineers must consider resonance capture when designing structures to ensure they can withstand environmental forces such as wind or earthquakes. Buildings that resonate with these forces can experience catastrophic failures if the resonance frequency matches the natural frequency of the structure. Therefore, understanding how to mitigate the effects of resonance capture is essential for creating safe and durable buildings.Moreover, resonance capture is also prevalent in the field of electronics, particularly in the design of circuits and filters. Engineers utilize this phenomenon to create devices that can selectively amplify signals at desired frequencies while minimizing noise and interference. For example, radio receivers rely on resonance capture to tune into specific stations by adjusting the circuit to resonate at the frequency of the desired signal, allowing for clear audio reception.In the biological sciences, resonance capture can be observed in how certain molecules interact with light. The absorption of light at particular wavelengths can lead to vibrational modes in molecules, which is a fundamental principle in techniques like spectroscopy. By analyzing these interactions, scientists can gain insights into the molecular composition and structure of various substances.The implications of resonance capture extend beyond the physical sciences. In social dynamics, the concept can be metaphorically applied to understand how ideas and movements gain traction within communities. Just as systems resonate with specific frequencies, certain ideas resonate with individuals, leading to collective action and societal change. Understanding this metaphorical resonance capture can provide valuable insights into marketing strategies, political campaigns, and social movements.In conclusion, the concept of resonance capture is a multifaceted phenomenon that spans various disciplines, from physics to sociology. Its importance cannot be overstated, as it offers a framework for understanding how energy and information are transmitted and amplified across different systems. Whether in the design of a musical instrument, the engineering of resilient structures, or the analysis of social phenomena, recognizing the principles of resonance capture can lead to more effective solutions and innovations. As we continue to explore the complexities of our world, the study of resonance capture will undoubtedly remain a vital area of inquiry.
在物理和工程领域,术语共鸣捕获指的是一个系统在特定频率下吸收能量的现象,从而导致振动的放大。这个概念不仅对理解各种自然现象至关重要,而且在技术应用中也发挥着重要作用。例如,在乐器设计中,共鸣捕获效应被利用来增强音质。当音乐家演奏一个音符时,乐器在某些频率下振动,捕获并放大这些振动,从而产生丰富而饱满的声音。同样,在建筑领域,工程师在设计结构时必须考虑共鸣捕获,以确保它们能够承受风或地震等环境力量。与这些力量共鸣的建筑物,如果共鸣频率与结构的自然频率匹配,可能会经历灾难性的故障。因此,理解如何减轻共鸣捕获的影响对于创造安全耐用的建筑物至关重要。此外,共鸣捕获在电子学领域也很常见,特别是在电路和滤波器的设计中。工程师利用这一现象创建可以选择性放大所需频率信号的设备,同时最小化噪声和干扰。例如,无线电接收器依赖于共鸣捕获来调谐特定站点,通过调整电路以在所需信号的频率上共鸣,从而实现清晰的音频接收。在生物科学中,共鸣捕获可以在某些分子与光的相互作用中观察到。在特定波长下光的吸收可以导致分子的振动模式,这是如光谱学等技术的基本原理。通过分析这些相互作用,科学家可以获得有关各种物质的分子组成和结构的见解。共鸣捕获的影响超越了物理科学。在社会动态中,这个概念可以比喻性地应用于理解某些思想和运动如何在社区内获得牵引力。正如系统与特定频率共鸣一样,某些思想与个人产生共鸣,导致集体行动和社会变革。理解这种比喻性的共鸣捕获可以为营销策略、政治运动和社会运动提供有价值的见解。总之,共鸣捕获的概念是一个多面的现象,跨越多个学科,从物理到社会学。它的重要性不容低估,因为它提供了一个框架,用于理解能量和信息如何在不同系统之间传输和放大。无论是在乐器的设计中、韧性结构的工程中,还是在社会现象的分析中,认识到共鸣捕获的原理可以导致更有效的解决方案和创新。随着我们继续探索世界的复杂性,共鸣捕获的研究无疑将仍然是一个重要的研究领域。
