Comparative study for Active Noise Cancellation using Adaptive filtering and Standing wave pattern

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引用次数: 1

Abstract

Noise pollution is one of the most fundamental challenges facing our environment, causes health problem, communication inefficiency and degrade the performance of works due to lack of concentration, thus, mitigating this impact becomes an unavoidable requirement of time to protect people's health and the environment. This noise may originate from several sources including industrial machinery, system parts wear out, and adjacent environmental acoustics. To mitigate this noise effect, an Active Noise Cancellation (ANC) headphone is achieved by two effective techniques; Adaptive filtering and Standing wave phenomenon. In this work, an ANC system is designed using both adaptive filtering and standing wave techniques, the former one basically utilizes single-channel feedforward whereas the latter one utilizes both single-channel feedforward and feedback control. LMS adaptive filter algorithm is the basic component of the designed ANC headphone. For simulation, a noise-free signal will be used as the desired audio signal and a gaussian distributed noise as the unwanted noise signal, these are combined to form noise corrupted speech signal. Propose algorithms performance were evaluated based on the ability to mitigate effects of different frequency broad-band noise signals and of different Noise to Signal ratio. Evaluation measures used are; convergence rate and noise reduction in dB. Result reveals ANC headphone using standing wave technique has better performance at mitigating noise frequency below 800Hz, with low SNR than Adaptive filtering. However, at higher frequencies above 1000Hz, ANC headphone using Adaptive filtering has good performance of masking high frequencies up to 22dB.
自适应滤波与驻波模式主动降噪的比较研究
噪音污染是我们环境面临的最根本的挑战之一,它会导致健康问题、沟通效率低下,并因注意力不集中而降低工程性能,因此,减轻这种影响成为保护人们健康和环境的不可避免的时间要求。这种噪音可能来自几个来源,包括工业机械、系统部件磨损和邻近的环境声学。为了减轻这种噪音影响,主动降噪(ANC)耳机是通过两种有效的技术实现的;自适应滤波和驻波现象。本文采用自适应滤波和驻波技术设计了一种自适应滤波系统,前者主要采用单通道前馈控制,后者则采用单通道前馈和反馈控制。LMS自适应滤波算法是所设计的ANC耳机的基本组成部分。在仿真中,一个无噪声的信号将被用作所需的音频信号,一个高斯分布的噪声将被用作不需要的噪声信号,它们被组合起来形成噪声破坏的语音信号。基于抑制不同频率宽带噪声信号和不同信噪比影响的能力,对所提算法的性能进行了评价。采用的评价措施有:收敛速度和降噪(以dB为单位)。结果表明,与自适应滤波相比,驻波技术在降噪800Hz以下的降噪效果更好,信噪比更低。然而,在1000Hz以上的更高频率下,采用自适应滤波的ANC耳机具有良好的屏蔽高达22dB的高频的性能。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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