acoustic resonance

简明释义

声共振

英英释义

例句

1.The violin's body is crafted to create a perfect balance of acoustic resonance for rich sound quality.

小提琴的琴体经过精心制作，以创造完美的声学共鸣平衡，从而提供丰富的音质。

2.During the experiment, we observed how the acoustic resonance of the tube affected the sound produced.

在实验中，我们观察到了管子的声学共鸣如何影响产生的声音。

3.The researchers focused on the acoustic resonance properties of different materials for soundproofing.

研究人员专注于不同材料的声学共鸣特性，以实现隔音效果。

4.The design of the concert hall was optimized to enhance acoustic resonance, ensuring that every note could be heard clearly.

音乐厅的设计经过优化，以增强声学共鸣，确保每个音符都能清晰地听到。

5.Engineers used software to simulate acoustic resonance in the new auditorium design.

工程师们使用软件模拟新礼堂设计中的声学共鸣。

作文

Acoustic resonance is a fascinating phenomenon that occurs when an object vibrates at its natural frequency in response to sound waves. This concept can be observed in various contexts, ranging from musical instruments to architectural designs. Understanding acoustic resonance (声学共鸣) not only enhances our appreciation of music but also informs engineers and architects in their work. In musical instruments, acoustic resonance (声学共鸣) plays a crucial role in producing sound. For example, in a violin, the body of the instrument acts as a resonating chamber. When a musician draws a bow across the strings, the vibrations produced are amplified by the body of the violin, creating a rich and full sound. The specific shape and material of the violin influence its acoustic properties, allowing for different tonal qualities. This illustrates how acoustic resonance (声学共鸣) is essential for achieving the desired sound in musical performances.Beyond music, acoustic resonance (声学共鸣) can also be observed in architecture. Many concert halls and theaters are designed with the principles of acoustic resonance (声学共鸣) in mind to enhance sound quality. The curvature of walls, the height of ceilings, and the materials used all contribute to how sound waves interact within the space. For instance, the Sydney Opera House is renowned not just for its stunning design but also for its exceptional acoustics. Engineers and architects must consider acoustic resonance (声学共鸣) to ensure that audiences can experience clear and balanced sound during performances.Moreover, acoustic resonance (声学共鸣) is not limited to large structures or musical instruments. It can also be found in everyday objects. For example, a glass can resonate when exposed to a specific frequency of sound, leading to the famous experiment where a singer shatters a glass by matching its natural frequency. This demonstrates the power of acoustic resonance (声学共鸣) and how it can have both beautiful and destructive effects.In conclusion, acoustic resonance (声学共鸣) is a vital concept that intersects art, science, and engineering. Its applications range from enhancing the sound of musical instruments to optimizing the acoustics of performance spaces. By understanding acoustic resonance (声学共鸣), we can appreciate the intricacies of sound and its impact on our experiences. As technology advances, further exploration of acoustic resonance (声学共鸣) will likely lead to new innovations in sound design and architecture, enriching our auditory environment even more.

声学共鸣是一个迷人的现象，当物体在声音波的作用下以其自然频率振动时，就会发生这种现象。这个概念可以在各种背景中观察到，从乐器到建筑设计。理解声学共鸣（acoustic resonance）不仅增强了我们对音乐的欣赏，还为工程师和建筑师提供了重要的参考。在乐器中，声学共鸣（acoustic resonance）在产生声音方面起着至关重要的作用。例如，在小提琴中，乐器的主体充当共鸣腔。当音乐家用弓拉动弦时，产生的振动通过小提琴的主体被放大，创造出丰富而饱满的声音。小提琴的具体形状和材料影响其声学特性，从而允许不同的音色。这说明了如何实现音乐表演中所需的声音，声学共鸣（acoustic resonance）是必不可少的。除了音乐之外，声学共鸣（acoustic resonance）还可以在建筑中观察到。许多音乐厅和剧院的设计都考虑到了声学共鸣（acoustic resonance）的原则，以增强音质。墙壁的曲率、天花板的高度以及使用的材料都影响声音波在空间中的相互作用。例如，悉尼歌剧院不仅因其惊艳的设计而闻名，还因其卓越的声学效果而受到赞誉。工程师和建筑师必须考虑声学共鸣（acoustic resonance），以确保观众在表演期间能够体验到清晰和平衡的声音。此外，声学共鸣（acoustic resonance）并不限于大型结构或乐器。它也可以在日常物品中找到。例如，当暴露于特定频率的声音时，玻璃可以产生共鸣，这导致著名的实验，即歌手通过匹配其自然频率来打破玻璃。这展示了声学共鸣（acoustic resonance）的力量，以及它可能产生美丽和破坏性效果的方式。总之，声学共鸣（acoustic resonance）是一个重要的概念，交织着艺术、科学和工程。它的应用范围从增强乐器的声音到优化表演空间的声学。通过理解声学共鸣（acoustic resonance），我们可以欣赏声音的复杂性及其对我们体验的影响。随着技术的进步，对声学共鸣（acoustic resonance）的进一步探索可能会导致声音设计和建筑领域的新创新，进一步丰富我们的听觉环境。