acoustic resonance

简明释义

声共鸣

英英释义

例句

1.Certain musical notes can cause a dramatic increase in acoustic resonance within a space.

某些音乐音符可以在空间内导致声学共鸣的剧烈增加。

2.The design of the concert hall was optimized to enhance acoustic resonance.

音乐厅的设计经过优化，以增强声学共鸣。

3.The engineer studied the acoustic resonance of different materials for soundproofing.

工程师研究了不同材料的声学共鸣以进行隔音。

4.Musicians often adjust their instruments to achieve the best acoustic resonance.

音乐家们经常调整他们的乐器，以获得最佳的声学共鸣。

5.In architectural acoustics, acoustic resonance can significantly affect sound quality.

在建筑声学中，声学共鸣可以显著影响音质。

作文

Acoustic resonance is a fascinating phenomenon that occurs when an object vibrates in response to sound waves. This concept can be observed in various everyday situations, from musical instruments to architectural designs. The principle behind acoustic resonance (声学共振) lies in the natural frequencies at which objects tend to vibrate. When sound waves of a specific frequency encounter an object that resonates at that same frequency, the energy from the sound waves is absorbed, causing the object to vibrate more intensely. This effect can amplify sound, creating richer tones and enhancing auditory experiences.One of the most common examples of acoustic resonance (声学共振) can be found in musical instruments. For instance, when a violin string is plucked, it vibrates at certain frequencies, producing sound. The body of the violin, which is hollow, acts as a resonating chamber. The air inside the chamber vibrates in harmony with the string’s vibrations, amplifying the sound produced. This is why violins have a distinct and rich tone; the acoustic resonance (声学共振) of the instrument enhances the sound quality, making it more pleasing to the ear.Another interesting application of acoustic resonance (声学共振) can be seen in architecture. Architects often design concert halls and theaters with specific shapes and materials to optimize sound quality. The goal is to create spaces where sound waves can bounce off surfaces and resonate effectively, providing the audience with a clear and immersive listening experience. For example, the Sydney Opera House is known for its unique design, which not only serves aesthetic purposes but also enhances acoustic resonance (声学共振) within the performance spaces.Moreover, acoustic resonance (声学共振) is not limited to music or architecture; it plays a crucial role in various scientific fields. In physics, understanding the principles of acoustic resonance (声学共振) helps scientists study sound waves and their interactions with different materials. This knowledge can lead to advancements in technology, such as improving the design of speakers and sound systems, ensuring they produce high-quality audio by maximizing resonance.Additionally, acoustic resonance (声学共振) is also relevant in medical applications. For instance, ultrasound technology relies on the principles of resonance to create images of the inside of the body. By sending sound waves at specific frequencies into the body, doctors can observe how these waves resonate with different tissues, allowing for accurate imaging and diagnosis.In conclusion, acoustic resonance (声学共振) is a multifaceted concept that impacts various aspects of our lives. From enhancing the beauty of music to optimizing architectural designs and advancing scientific research, the principles of resonance are essential for creating harmonious experiences. Understanding acoustic resonance (声学共振) opens up a world of possibilities, allowing us to appreciate the intricate relationship between sound and the physical world around us.

声学共振是一个迷人的现象，当物体对声波振动时就会发生这种现象。这个概念可以在各种日常情况下观察到，从乐器到建筑设计。声学共振的原理在于物体倾向于振动的自然频率。当特定频率的声波遇到一个在同一频率下共振的物体时，声波的能量被吸收，导致物体更强烈地振动。这种效应可以放大声音，创造出更丰富的音调，并增强听觉体验。声学共振的一个常见例子可以在乐器中找到。例如，当小提琴弦被拨动时，它会以某些频率振动，产生声音。小提琴的琴身是空心的，充当共振腔。腔内的空气与弦的振动和谐共振，放大产生的声音。这就是为什么小提琴有独特而丰富的音色；乐器的声学共振增强了音质，使其更加悦耳。声学共振的另一个有趣应用可以在建筑中看到。建筑师通常设计音乐厅和剧院，采用特定的形状和材料，以优化声音质量。目标是创建声波能够有效反弹并共振的空间，为观众提供清晰而沉浸的听觉体验。例如，悉尼歌剧院以其独特的设计而闻名，这不仅服务于美学目的，还增强了演出空间内的声学共振。此外，声学共振不仅限于音乐或建筑；它在多个科学领域也发挥着关键作用。在物理学中，理解声学共振的原理帮助科学家研究声波及其与不同材料的相互作用。这种知识可以推动技术的进步，例如改善扬声器和音响系统的设计，确保它们通过最大化共振来产生高质量的音频。此外，声学共振在医学应用中也很相关。例如，超声技术依赖于共振原理来创建身体内部的图像。通过以特定频率发送声波进入体内，医生可以观察这些波如何与不同组织共振，从而实现准确的成像和诊断。总之，声学共振是一个多方面的概念，影响着我们生活的各个方面。从增强音乐的美感到优化建筑设计，再到推动科学研究的进步，共振原理对于创造和谐的体验至关重要。理解声学共振为我们打开了一扇可能性的大门，让我们欣赏声音与周围物理世界之间的复杂关系。