Deep Space Separable Distillation for Lightweight Acoustic Scene Classification

ShuQi Ye, Yuan Tian
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Abstract

Acoustic scene classification (ASC) is highly important in the real world. Recently, deep learning-based methods have been widely employed for acoustic scene classification. However, these methods are currently not lightweight enough as well as their performance is not satisfactory. To solve these problems, we propose a deep space separable distillation network. Firstly, the network performs high-low frequency decomposition on the log-mel spectrogram, significantly reducing computational complexity while maintaining model performance. Secondly, we specially design three lightweight operators for ASC, including Separable Convolution (SC), Orthonormal Separable Convolution (OSC), and Separable Partial Convolution (SPC). These operators exhibit highly efficient feature extraction capabilities in acoustic scene classification tasks. The experimental results demonstrate that the proposed method achieves a performance gain of 9.8% compared to the currently popular deep learning methods, while also having smaller parameter count and computational complexity.
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用于轻量级声学场景分类的深空可分离蒸馏技术
声学场景分类(ASC)在现实世界中非常重要。最近,基于深度学习的方法被广泛用于声学场景分类。然而,这些方法目前还不够轻便,性能也不尽如人意。为了解决这些问题,我们提出了一种深度空间可分离蒸馏网络。首先,该网络对log-mel频谱图进行高低频分解,在保持模型性能的同时大大降低了计算复杂度。其次,我们专门为 ASC 设计了三个轻量级算子,包括可分离卷积(SC)、正交可分离卷积(OSC)和可分离部分卷积(SPC)。这些算子在声学场景分类任务中表现出高效的特征提取能力。实验结果表明,与目前流行的深度学习方法相比,所提出的方法实现了 9.8% 的性能增益,同时还具有更少的参数数量和计算复杂性。
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