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Multi-scale Convolutional Recurrent Neural Network and Data Augmentation for Polyphonic Sound Event Detection
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Multi-scale Convolutional Recurrent Neural Network and Data Augmentation for Polyphonic Sound Event Detection
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Multi-scale Convolutional Recurrent Neural Network and Data Augmentation for Polyphonic Sound Event Detection
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Journal Article
Multi-scale Convolutional Recurrent Neural Network and Data Augmentation for Polyphonic Sound Event Detection
2021
Overview
We propose Multi-scale convolutional recurrent neural networks (MCRNN) and data augmentation methods to detect polyphonic sound event with few training data. MCRNN consists of Multi-scale convolutional neural networks (MCNN) and recurrent neural networks (RNN). MCNN concatenates the higher level features extracted using multiple convolution kernels with different scales from the time domain and frequency domain at the same time. RNN is able to capture the longer term temporal context characteristics. A novel background spectrum random replacement (BSRR) data augmentation method is applied to expand training data, which uses standard normal distribution data with randomly selected position and length instead of the original time-domain, frequency-domain or time-frequency domain background spectrum features. Our method is tested on the datasets of DCASE 2019 Task3 (T3). The experimental results showed that the MCRNN and BSRR data augmentation method are efficient. We achieved better results than the first place and the single advanced on the T3 by applying BSRR and SpecAugment data augmentation method simultaneously. On the evaluation dataset (T3-eval), our best result shows 0.05 and 0.975 of error rate (ER) and F1 respectively. Our method got the best performance and relatively improved 17% and 1% than the corresponding values of the single advanced.
Publisher
IOP Publishing
