New research on low-frequency membrane absorbers

John Calder
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引用次数: 1

Abstract

Low-frequency (LF) room modes are one of the greatest issues for accurate sound recording and reproduction. Effective LF absorbers can mitigate modes in professional and consumer audio rooms. However, fiber- and foam-based absorbers act on sound velocity; membrane absorbers act on sound pressure (greatest at hard surfaces and corners). Velocity at hard surfaces is zero; thus, fiber and foam absorbers work far less effectively than membrane absorbers under 200Hz. Additionally, most independent testing laboratories are only large enough to accurately measure absorption results above 160Hz (per Schroeder frequency) but not below. Only one lab is large enough to be accurate down to 40Hz. A new LF membrane-based absorber product was designed to compliment the frequency range of an existing product. Both were separately tested for LF absorption down to 40Hz at the above-referenced lab. Ten LF absorber tests revealed that the type of absorber, and its location and orientation in a room, are critical to LF absorber effectiveness. Some unexpected results, however, showed clearly that without standardized laboratory absorption testing in a lab capable of accurately testing down to 40Hz, it is not possible to state conclusively that low-frequency absorber products perform as claimed.Low-frequency (LF) room modes are one of the greatest issues for accurate sound recording and reproduction. Effective LF absorbers can mitigate modes in professional and consumer audio rooms. However, fiber- and foam-based absorbers act on sound velocity; membrane absorbers act on sound pressure (greatest at hard surfaces and corners). Velocity at hard surfaces is zero; thus, fiber and foam absorbers work far less effectively than membrane absorbers under 200Hz. Additionally, most independent testing laboratories are only large enough to accurately measure absorption results above 160Hz (per Schroeder frequency) but not below. Only one lab is large enough to be accurate down to 40Hz. A new LF membrane-based absorber product was designed to compliment the frequency range of an existing product. Both were separately tested for LF absorption down to 40Hz at the above-referenced lab. Ten LF absorber tests revealed that the type of absorber, and its location and orientation in a room, are critical to LF absorb...
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低频膜吸收器的新研究
低频(LF)房间模式是准确录音和再现的最大问题之一。有效的低频吸收器可以减轻专业和消费者音频室的模式。然而,基于纤维和泡沫的吸收器对声速起作用;膜吸收器作用于声压(在坚硬表面和角落最大)。在坚硬表面上的速度为零;因此,在200Hz下,纤维和泡沫吸收器的工作效率远远低于膜吸收器。此外,大多数独立的测试实验室只能精确测量160Hz以上(每施罗德频率)的吸收结果,而不能低于160Hz。只有一个实验室足够大,可以精确到40Hz。设计了一种新的低频膜吸收器产品,以补充现有产品的频率范围。在上述实验室分别测试了低至40Hz的低频吸收。10次低频吸波器试验表明,吸波器的类型及其在室内的位置和朝向对低频吸波器的效果至关重要。然而,一些意想不到的结果清楚地表明,在实验室中没有标准化的实验室吸收测试,能够准确地测试到40Hz,就不可能得出结论,低频吸收器产品的性能与所声称的一样。低频(LF)房间模式是准确录音和再现的最大问题之一。有效的低频吸收器可以减轻专业和消费者音频室的模式。然而,基于纤维和泡沫的吸收器对声速起作用;膜吸收器作用于声压(在坚硬表面和角落最大)。在坚硬表面上的速度为零;因此,在200Hz下,纤维和泡沫吸收器的工作效率远远低于膜吸收器。此外,大多数独立的测试实验室只能精确测量160Hz以上(每施罗德频率)的吸收结果,而不能低于160Hz。只有一个实验室足够大,可以精确到40Hz。设计了一种新的低频膜吸收器产品,以补充现有产品的频率范围。在上述实验室分别测试了低至40Hz的低频吸收。10次低低频吸波器试验表明,吸波器的类型及其在室内的位置和朝向对低低频吸波效果至关重要。
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