acoustic coupling

简明释义

声耦合

英英释义

例句

1.They used gel to improve acoustic coupling 声学耦合 during the ultrasound imaging process.

他们使用凝胶来改善超声成像过程中的声学耦合 声学耦合。

2.Proper acoustic coupling 声学耦合 is crucial for achieving clear sound transmission in audio devices.

适当的声学耦合 声学耦合对于实现音频设备中的清晰声音传输至关重要。

3.The researchers investigated the acoustic coupling 声学耦合 effects in underwater communication systems.

研究人员调查了水下通信系统中的声学耦合 声学耦合效应。

4.In this experiment, we measured the acoustic coupling 声学耦合 efficiency in different materials.

在这个实验中，我们测量了不同材料中的声学耦合 声学耦合效率。

5.The effectiveness of the ultrasound treatment depends on the degree of acoustic coupling 声学耦合 between the transducer and the skin.

超声治疗的有效性取决于换能器与皮肤之间的声学耦合 声学耦合程度。

作文

Acoustic coupling is a term that describes the interaction between sound waves and the medium through which they travel. In simple terms, it refers to how effectively sound can be transmitted from one object to another, often through air or other materials. Understanding acoustic coupling (声学耦合) is essential in various fields, including music, engineering, and environmental science. This concept plays a significant role in the design of audio equipment, the construction of buildings, and even in the study of animal communication.In music, acoustic coupling (声学耦合) can be observed in how instruments interact with their surroundings. For example, when a violin is played, its body vibrates, producing sound waves that travel through the air. The way these sound waves interact with the surrounding environment, including walls and furniture, can significantly affect the overall sound quality. Musicians and sound engineers must consider acoustic coupling (声学耦合) when setting up a performance space to ensure optimal sound transmission and clarity.In the field of engineering, acoustic coupling (声学耦合) is crucial for designing structures that minimize sound transmission. For instance, when constructing a building, architects must consider how sound will travel between rooms and through walls. Proper insulation and material selection can help reduce unwanted noise, creating a more comfortable environment for occupants. Engineers often use models to simulate acoustic coupling (声学耦合) effects during the design phase, allowing them to make informed decisions about materials and layouts.Moreover, acoustic coupling (声学耦合) is also relevant in environmental science, particularly in studying how animals communicate. Many species rely on sound to convey messages, attract mates, or establish territory. Researchers investigate how sound travels through different environments, such as forests or oceans, and how factors like temperature and humidity affect acoustic coupling (声学耦合). Understanding these dynamics is vital for conservation efforts and for maintaining healthy ecosystems.In conclusion, acoustic coupling (声学耦合) is a fundamental concept that influences various aspects of our lives, from music and engineering to environmental science. By understanding how sound interacts with different mediums, we can enhance our experiences and improve our surroundings. Whether it's ensuring that a concert hall has excellent acoustics or designing a quiet office space, grasping the principles of acoustic coupling (声学耦合) allows us to create environments that are both functional and enjoyable. As technology continues to evolve, the importance of acoustic coupling (声学耦合) will only become more pronounced, highlighting the need for ongoing research and innovation in this fascinating field.

声学耦合是一个描述声波与其传播介质之间相互作用的术语。简单来说，它指的是声音从一个物体有效传输到另一个物体的能力，通常通过空气或其他材料进行。理解声学耦合在音乐、工程和环境科学等多个领域至关重要。这个概念在音频设备的设计、建筑的构造，甚至动物交流的研究中都起着重要作用。在音乐中，声学耦合可以观察到乐器与其周围环境之间的互动。例如，当小提琴被演奏时，其琴体会振动，产生通过空气传播的声波。这些声波与周围环境（包括墙壁和家具）的相互作用，可以显著影响整体音质。音乐家和音响工程师在设置表演空间时必须考虑声学耦合，以确保最佳的声音传输和清晰度。在工程领域，声学耦合对设计能减少声音传播的结构至关重要。例如，在建造一座建筑时，建筑师必须考虑声音如何在房间之间和通过墙壁传播。适当的绝缘和材料选择可以帮助减少不必要的噪音，为居住者创造一个更舒适的环境。工程师通常使用模型在设计阶段模拟声学耦合的效果，使他们能够对材料和布局做出明智的决策。此外，声学耦合在环境科学中也相关，特别是在研究动物如何交流时。许多物种依赖声音来传达信息、吸引配偶或建立领土。研究人员调查声音如何在不同环境中传播，如森林或海洋，以及温度和湿度等因素如何影响声学耦合。理解这些动态对保护工作和维护健康生态系统至关重要。总之，声学耦合是一个基本概念，影响着我们生活的各个方面，从音乐和工程到环境科学。通过理解声音如何与不同介质相互作用，我们可以增强我们的体验并改善我们的环境。无论是确保音乐厅具有优良的音响效果，还是设计一个安静的办公室空间，掌握声学耦合的原理使我们能够创造既实用又愉悦的环境。随着技术的不断发展，声学耦合的重要性只会愈加突出，强调了在这一迷人领域持续研究和创新的必要性。