368 research outputs found
Representation Learning: A Review and New Perspectives
The success of machine learning algorithms generally depends on data
representation, and we hypothesize that this is because different
representations can entangle and hide more or less the different explanatory
factors of variation behind the data. Although specific domain knowledge can be
used to help design representations, learning with generic priors can also be
used, and the quest for AI is motivating the design of more powerful
representation-learning algorithms implementing such priors. This paper reviews
recent work in the area of unsupervised feature learning and deep learning,
covering advances in probabilistic models, auto-encoders, manifold learning,
and deep networks. This motivates longer-term unanswered questions about the
appropriate objectives for learning good representations, for computing
representations (i.e., inference), and the geometrical connections between
representation learning, density estimation and manifold learning
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Single Channel auditory source separation with neural network
Although distinguishing diļ¬erent sounds in noisy environment is a relative easy task for human, source separation has long been extremely diļ¬cult in audio signal processing. The problem is challenging for three reasons: the large variety of sound type, the abundant mixing conditions and the unclear mechanism to distinguish sources, especially for similar sounds.
In recent years, the neural network based methods achieved impressive successes in various problems, including the speech enhancement, where the task is to separate the clean speech out of the noise mixture. However, the current deep learning based source separator does not perform well on real recorded noisy speech, and more importantly, is not applicable in a more general source separation scenario such as overlapped speech.
In this thesis, we ļ¬rstly propose extensions for the current mask learning network, for the problem of speech enhancement, to ļ¬x the scale mismatch problem which is usually occurred in real recording audio. We solve this problem by combining two additional restoration layers in the existing mask learning network. We also proposed a residual learning architecture for the speech enhancement, further improving the network generalization under diļ¬erent recording conditions. We evaluate the proposed speech enhancement models on CHiME 3 data. Without retraining the acoustic model, the best bi-direction LSTM with residue connections yields 25.13% relative WER reduction on real data and 34.03% WER on simulated data.
Then we propose a novel neural network based model called ādeep clusteringā for more general source separation tasks. We train a deep network to assign contrastive embedding vectors to each time-frequency region of the spectrogram in order to implicitly predict the segmentation labels of the target spectrogram from the input mixtures. This yields a deep network-based analogue to spectral clustering, in that the embeddings form a low-rank pairwise aļ¬nity matrix that approximates the ideal aļ¬nity matrix, while enabling much faster performance. At test time, the clustering step ādecodesā the segmentation implicit in the embeddings by optimizing K-means with respect to the unknown assignments. Experiments on single channel mixtures from multiple speakers show that a speaker-independent model trained on two-speaker and three speakers mixtures can improve signal quality for mixtures of held-out speakers by an average over 10dB.
We then propose an extension for deep clustering named ādeep attractorā network that allows the system to perform eļ¬cient end-to-end training. In the proposed model, attractor points for each source are ļ¬rstly created the acoustic signals which pull together the time-frequency bins corresponding to each source by ļ¬nding the centroids of the sources in the embedding space, which are subsequently used to determine the similarity of each bin in the mixture to each source. The network is then trained to minimize the reconstruction error of each source by optimizing the embeddings. We showed that this frame work can achieve even better results.
Lastly, we introduce two applications of the proposed models, in singing voice separation and the smart hearing aid device. For the former, a multi-task architecture is proposed, which combines the deep clustering and the classiļ¬cation based network. And a new state of the art separation result was achieved, where the signal to noise ratio was improved by 11.1dB on music and 7.9dB on singing voice. In the application of smart hearing aid device, we combine the neural decoding with the separation network. The system ļ¬rstly decodes the userās attention, which is further used to guide the separator for the targeting source. Both objective study and subjective study show the proposed system can accurately decode the attention and significantly improve the user experience
Deep Contextualized Acoustic Representations For Semi-Supervised Speech Recognition
We propose a novel approach to semi-supervised automatic speech recognition
(ASR). We first exploit a large amount of unlabeled audio data via
representation learning, where we reconstruct a temporal slice of filterbank
features from past and future context frames. The resulting deep contextualized
acoustic representations (DeCoAR) are then used to train a CTC-based end-to-end
ASR system using a smaller amount of labeled audio data. In our experiments, we
show that systems trained on DeCoAR consistently outperform ones trained on
conventional filterbank features, giving 42% and 19% relative improvement over
the baseline on WSJ eval92 and LibriSpeech test-clean, respectively. Our
approach can drastically reduce the amount of labeled data required;
unsupervised training on LibriSpeech then supervision with 100 hours of labeled
data achieves performance on par with training on all 960 hours directly.
Pre-trained models and code will be released online.Comment: Accepted to ICASSP 2020 (oral
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