acoustic dipole

简明释义

声偶极子

英英释义

例句

1.Researchers discovered that an acoustic dipole (声学偶极子) can be used to create directional sound fields.

研究人员发现，声学偶极子 (声学偶极子) 可以用来创建定向声场。

2.In architectural acoustics, the placement of speakers can be optimized using the principles of an acoustic dipole (声学偶极子).

在建筑声学中，可以利用 声学偶极子 (声学偶极子) 的原理来优化扬声器的放置。

3.Engineers often use an acoustic dipole (声学偶极子) model to design efficient sonar systems.

工程师们常常使用 声学偶极子 (声学偶极子) 模型来设计高效的声纳系统。

4.In the study of underwater acoustics, the concept of an acoustic dipole (声学偶极子) is crucial for understanding sound propagation.

在水下声学研究中，声学偶极子 (声学偶极子) 的概念对于理解声波传播至关重要。

5.The acoustic dipole (声学偶极子) configuration can significantly affect the radiation pattern of sound waves.

声学偶极子 (声学偶极子) 配置可以显著影响声波的辐射模式。

作文

The concept of an acoustic dipole refers to a source of sound that emits waves in a specific manner, typically characterized by the arrangement of two opposing sound sources. This phenomenon can be observed in various applications, ranging from musical instruments to advanced sonar systems. Understanding the mechanics of an acoustic dipole is crucial for engineers and scientists who work with sound propagation, as it provides insights into how sound waves interact with their environment.In essence, an acoustic dipole consists of two point sources of sound that are placed at a small distance apart. When these sources emit sound waves, they create a pattern of interference that can be analyzed mathematically. The resulting sound field exhibits unique properties, including directional characteristics that can be exploited in numerous technologies. For instance, in the realm of audio engineering, the principles of an acoustic dipole can be applied to design speakers that deliver sound more efficiently and with greater clarity.Moreover, the study of acoustic dipole configurations is essential in the field of underwater acoustics. Sonar systems often utilize this principle to detect objects submerged in water. By emitting sound waves from two closely spaced sources, the sonar system can create a detailed map of the underwater environment. This technique not only enhances object detection but also aids in navigation and exploration of marine ecosystems.The significance of an acoustic dipole extends beyond practical applications; it also plays a vital role in fundamental research. Scientists explore acoustic dipole behavior to understand the physical properties of sound waves and their interactions with different materials. This research can lead to breakthroughs in fields such as material science and environmental monitoring, where sound is used to gather data about the surrounding world.In summary, the acoustic dipole is a fascinating concept that bridges theory and application. Its implications reach far and wide, influencing technology, research, and our understanding of sound itself. As we continue to explore the intricacies of sound waves and their behavior, the acoustic dipole will undoubtedly remain a critical area of focus. Whether it is in designing better audio systems or enhancing sonar capabilities, the principles behind the acoustic dipole will continue to shape our auditory experiences and technological advancements. Embracing this knowledge allows us to harness the power of sound in innovative ways, paving the path for future discoveries in acoustics.

“声学偶极子”这一概念指的是以特定方式发出声波的声源，通常以两个相对的声源的排列为特征。这种现象可以在各种应用中观察到，从乐器到先进的声纳系统。理解“声学偶极子”的机制对于从事声波传播的工程师和科学家至关重要，因为它提供了关于声波如何与环境相互作用的见解。本质上，“声学偶极子”由两个相距较小的声源组成。当这些声源发出声波时，它们会产生一个可以用数学分析的干涉模式。由此产生的声场展现出独特的特性，包括可以在众多技术中利用的方向特性。例如，在音频工程领域，“声学偶极子”的原理可以应用于设计更高效、清晰度更高的扬声器。此外，“声学偶极子”配置的研究在水下声学领域也至关重要。声纳系统通常利用这一原理来探测沉没在水中的物体。通过从两个相距较近的声源发出声波，声纳系统可以创建水下环境的详细地图。这项技术不仅增强了物体检测能力，还帮助导航和探索海洋生态系统。“声学偶极子”的重要性不仅限于实际应用；它在基础研究中也发挥着重要作用。科学家们探索“声学偶极子”的行为，以了解声波的物理特性及其与不同材料的相互作用。这项研究可能导致材料科学和环境监测等领域的突破，在这些领域中，声音被用来收集有关周围世界的数据。总之，“声学偶极子”是一个迷人的概念，连接了理论与应用。它的影响深远，影响着技术、研究以及我们对声音的理解。随着我们继续探索声波及其行为的复杂性，“声学偶极子”无疑将仍然是一个关键的关注领域。无论是在设计更好的音频系统还是增强声纳能力方面，“声学偶极子”背后的原理将继续塑造我们的听觉体验和技术进步。掌握这些知识使我们能够以创新的方式利用声音的力量，为声学领域的未来发现铺平道路。