acoustic susceptance

简明释义

声纳

英英释义

例句

1.The study of acoustic susceptance 声学易导性 is crucial for designing better sound systems.

对声学易导性的研究对于设计更好的音响系统至关重要。

2.Researchers are measuring the acoustic susceptance 声学易导性 of different fabrics for soundproofing applications.

研究人员正在测量不同织物的声学易导性以用于隔音应用。

3.Engineers must consider the acoustic susceptance 声学易导性 of materials when constructing concert halls.

工程师在建造音乐厅时必须考虑材料的声学易导性。

4.The acoustic susceptance 声学易导性 of the room affected how the music was perceived.

房间的声学易导性影响了音乐的感知方式。

5.A high acoustic susceptance 声学易导性 indicates that a material can absorb sound effectively.

高声学易导性表明一种材料能够有效吸收声音。

作文

In the study of acoustics, particularly in the field of engineering and physics, understanding various properties of sound waves is crucial. One such property is acoustic susceptance, which refers to the measure of how easily a system can transmit or absorb sound energy. This concept is vital when designing spaces for optimal sound quality, such as concert halls, recording studios, and even residential areas. By grasping the principles behind acoustic susceptance, engineers can create environments that either enhance or dampen sound in a controlled manner.To comprehend acoustic susceptance, it is essential to consider its relationship with other acoustic parameters. For instance, it is closely related to acoustic impedance, which quantifies how much sound pressure is produced by a given volume velocity of air. While acoustic impedance is a complex value that combines resistance and reactance, acoustic susceptance is specifically focused on the reactive component of this relationship. It provides insights into how much sound energy is absorbed or reflected by a material or structure.The significance of acoustic susceptance becomes apparent when evaluating different materials used in construction. For example, soft materials like carpets and curtains exhibit high acoustic susceptance, meaning they are effective at absorbing sound. On the other hand, hard surfaces like concrete or glass have low acoustic susceptance, leading to increased sound reflection. Understanding these properties allows architects and designers to strategically select materials that will achieve the desired acoustic environment.Moreover, acoustic susceptance plays a critical role in architectural acoustics, where the goal is to optimize sound distribution within a space. By analyzing the acoustic susceptance of various elements within a room, such as walls, ceilings, and furnishings, professionals can predict how sound will behave in that environment. This predictive capability is essential for ensuring that sound travels evenly throughout a venue, minimizing dead spots or areas of excessive reverberation.In addition to architectural applications, acoustic susceptance is also important in the design of musical instruments. For instance, the body of a guitar or the shape of a violin significantly influences its acoustic susceptance. Luthiers carefully consider the materials and shapes they use to craft instruments that produce the most pleasing sounds. By manipulating acoustic susceptance, they can enhance certain frequencies while dampening others, resulting in a richer tonal quality.Furthermore, advancements in technology have led to new methods of measuring and analyzing acoustic susceptance. With the use of computer simulations and sophisticated modeling techniques, acousticians can visualize how sound interacts with various surfaces and materials. This data-driven approach allows for more precise adjustments in design, ultimately leading to better acoustic outcomes.In conclusion, acoustic susceptance is a fundamental concept in the field of acoustics that impacts various applications from architecture to musical instrument design. By understanding and leveraging this property, professionals can create spaces that enhance sound quality and improve auditory experiences. As we continue to explore the intricate relationships between sound and materials, the importance of acoustic susceptance will only grow, paving the way for innovative solutions in sound management and design.

在声学研究中，特别是在工程和物理领域，理解声波的各种特性至关重要。其中一个特性是声学易感性，它指的是一个系统传递或吸收声能的能力的度量。这个概念在设计最佳音质的空间时非常重要，如音乐厅、录音室甚至住宅区。通过掌握声学易感性背后的原理，工程师可以以可控的方式创建增强或减弱声音的环境。要理解声学易感性，需要考虑其与其他声学参数的关系。例如，它与声学阻抗密切相关，声学阻抗量化了给定体积速度的空气产生多少声压。虽然声学阻抗是一个结合了电阻和反应性的复杂值，但声学易感性专注于这种关系的反应性成分。它提供了关于材料或结构吸收或反射多少声能的见解。声学易感性的重要性在评估建筑中使用的不同材料时变得显而易见。例如，像地毯和窗帘这样的软材料表现出高声学易感性，意味着它们在吸收声音方面有效。另一方面，像混凝土或玻璃这样的硬表面具有低声学易感性，导致声音反射增加。理解这些特性使建筑师和设计师能够战略性地选择材料，以实现所需的声学环境。此外，声学易感性在建筑声学中发挥着关键作用，其目标是优化空间内的声音分布。通过分析房间内各种元素的声学易感性，如墙壁、天花板和家具，专业人士可以预测声音在该环境中的行为。这种预测能力对于确保声音均匀传播至关重要，最小化死角或过度混响区域。除了建筑应用外，声学易感性在乐器设计中也很重要。例如，吉他的琴体或小提琴的形状显著影响其声学易感性。乐器制造师仔细考虑他们用来制作乐器的材料和形状，以生产出最悦耳的声音。通过操控声学易感性，他们可以增强某些频率，同时减弱其他频率，从而产生更丰富的音色质量。此外，技术的进步导致了测量和分析声学易感性的新方法。借助计算机模拟和复杂的建模技术，声学家可以可视化声音如何与各种表面和材料相互作用。这种数据驱动的方法允许在设计中进行更精确的调整，最终导致更好的声学结果。总之，声学易感性是声学领域的一个基本概念，影响从建筑到乐器设计的各种应用。通过理解和利用这一特性，专业人士可以创建增强音质和改善听觉体验的空间。随着我们继续探索声音与材料之间复杂的关系，声学易感性的重要性只会增加，为声音管理和设计的创新解决方案铺平道路。