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Deep Xi: A Deep Learning Approach to A Priori SNR Estimation for speech enhancement.

News

New journal paper:

  • On Training Targets for Deep Learning Approaches to Clean Speech Magnitude Spectrum Estimation [link] [.pdf]

New trained model:

  • A trained MHANet is available in the model directory.

New journal paper:

  • Masked Multi-Head Self-Attention for Causal Speech Enhancement [link] [.pdf]

New journal paper:

  • Spectral distortion level resulting in a just-noticeable difference between an a priori signal-to-noise ratio estimate and its instantaneous case [link] [.pdf]

New conference paper:

  • Temporal Convolutional Network with Frequency Dimension Adaptive Attention for Speech Enhancement (INTERSPEECH 2021)[link]

Contents

Introduction

Deep Xi is implemented in TensorFlow 2/Keras and can be used for speech enhancement, noise estimation, mask estimation, and as a front-end for robust ASR. Deep Xi (where the Greek letter 'xi' or ξ is pronounced /zaɪ/ and is the symbol used in the literature for the a priori SNR) is a deep learning approach to a priori SNR estimation that was proposed in [1]. Some of its use cases include:

  • Minimum mean-square error (MMSE) approaches to speech enhancement.
  • MMSE-based noise PSD estimators, as in DeepMMSE [2].
  • Ideal binary mask (IBM) estimation for missing feature approaches.
  • Ideal ratio mask (IRM) estimation for source separation.
  • Front-end for robust ASR

How does Deep Xi work?

A training example is shown in Figure 2. A deep neural network (DNN) within the Deep Xi framework is fed the noisy-speech short-time magnitude spectrum as input. The training target of the DNN is a mapped version of the instantaneous a priori SNR (i.e. mapped a priori SNR). The instantaneous a priori SNR is mapped to the interval [0,1] to improve the rate of convergence of the used stochastic gradient descent algorithm. The map is the cumulative distribution function (CDF) of the instantaneous a priori SNR, as given by Equation (13) in [1]. The statistics for the CDF are computed over a sample of the training set. An example of the mean and standard deviation of the sample for each frequency bin is shown in Figure 3. The training examples in each mini-batch are padded to the longest sequence length in the mini-batch. The sequence mask is used by TensorFlow to ensure that the DNN is not trained on the padding. During inference, the a priori SNR estimate is computed from the mapped a priori SNR using the sample statistics and Equation (12) from [2].

Figure 2: A training example for Deep Xi. Generated using eval_example.m.

Figure 3: The normal distribution for each frequency bin is computed from the mean and standard deviation of the instantaneous a priori SNR (dB) over a sample of the training set. Generated using eval_stats.m

Current networks

Configurations for the following networks can be found in run.sh.

  • MHANet: Multi-head attention network [6].
  • RDLNet: Residual-dense lattice network [3].
  • ResNet: Residual network [2].
  • ResLSTM & ResBiLSTM: Residual long short-term memory (LSTM) network and residual bidirectional LSTM (ResBiLSTM) network [1].

Deep Xi utilising the MHANet (Deep Xi-MHANet) was proposed in [6]. It utilises multi-head attention to efficiently model the long-range dependencies of noisy speech. Deep Xi-MHANet is shown in Figure 4. Deep Xi utilising a ResNet TCN (Deep Xi-ResNet) was proposed in [2]. It uses bottleneck residual blocks and a cyclic dilation rate. The network comprises of approximately 2 million parameters and has a contextual field of approximately 8 seconds. Deep Xi utilising a ResLSTM network (Deep Xi-ResLSTM) was proposed in [1]. Each of its residual blocks contain a single LSTM cell. The network comprises of approximately 10 million parameters.

Figure 4: (left) Deep Xi-MHANet from [6].

Available models

mhanet-1.1c (available in the model directory)

resnet-1.1n (available in the model directory)

resnet-1.1c (available in the model directory)

Each available model is trained using the Deep Xi dataset. Please see run.sh for more details about these networks.

There are multiple Deep Xi versions, comprising of different networks and restrictions. An example of the ver naming convention is resnet-1.0c. The network type is given at the start of ver. Versions with c are causal. Versions with n are non-causal. The version iteration is also given, i.e. 1.0.

Results

Note: Results for the Deep Xi framework in this repository are reported for Tensorflow 2/Keras. Results in the papers were found using Tensorflow 1. All future work will be completed in Tensorflow 2/Keras.

DEMAND Voice Bank test set

Objective scores obtained on the DEMAND Voicebank test set described here. Each Deep Xi model is trained on the DEMAND Voicebank training set. As in previous works, the objective scores are averaged over all tested conditions. CSIG, CBAK, and COVL are mean opinion score (MOS) predictors of the signal distortion, background-noise intrusiveness, and overall signal quality, respectively. PESQ is the perceptual evaluation of speech quality measure. STOI is the short-time objective intelligibility measure (in %). The highest scores attained for each measure are indicated in boldface.

Method Gain Causal CSIG CBAK COVL PESQ STOI SegSNR
Noisy speech -- -- 3.35 2.44 2.63 1.97 92 (91.5) --
Wiener Yes 3.23 2.68 2.67 2.22 -- --
SEGAN -- No 3.48 2.94 2.80 2.16 93 --
WaveNet -- No 3.62 3.23 2.98 -- -- --
MMSE-GAN -- No 3.80 3.12 3.14 2.53 93 --
Deep Feature Loss -- Yes 3.86 3.33 3.22 -- -- --
Metric-GAN -- No 3.99 3.18 3.42 2.86 -- --
Koizumi2020 -- No 4.15 3.42 3.57 2.99 -- --
T-GSA -- No 4.18 3.59 3.62 3.06 -- --
Deep Xi-ResLSTM (1.0c) MMSE-LSA Yes 4.01 3.25 3.34 2.65 91 (91.0) 8.2
Deep Xi-ResNet (1.0c) MMSE-LSA Yes 4.14 3.32 3.46 2.77 93 (93.2) --
Deep Xi-ResNet (1.0n) MMSE-LSA No 4.28 3.46 3.64 2.95 94 (93.6) --
Deep Xi-ResNet (1.1c) MMSE-LSA Yes 4.24 3.40 3.59 2.91 94 (93.5) 8.4
Deep Xi-ResNet (1.1n) MMSE-LSA No 4.35 3.52 3.71 3.03 94 (94.1) 9.3
Deep Xi-MHANet (1.0c) MMSE-LSA Yes 4.15 3.37 3.48 2.77 93 (93.2) 8.9
Deep Xi-MHANet (1.1c) MMSE-LSA Yes 4.34 3.49 3.69 2.99 94 (94.0) 9.1

Deep Xi Test Set

Average objective scores obtained over the conditions in the test set of the Deep Xi dataset. Each Deep Xi model is trained on the test set of the Deep Xi dataet. SNR levels between -10 dB and 20 dB are considered only. Results for each condition can be found in log/results

Method Gain Causal CSIG CBAK COVL PESQ STOI
Deep Xi-ResNet (1.1c) MMSE-STSA Yes 3.14 2.52 2.43 1.82 84.85
Deep Xi-ResNet (1.1c) MMSE-LSA Yes 3.15 2.55 2.46 1.85 84.72
Deep Xi-ResNet (1.1c) SRWF/IRM Yes 3.12 2.50 2.41 1.79 84.95
Deep Xi-ResNet (1.1c) cWF Yes 3.15 2.51 2.44 1.83 84.94
Deep Xi-ResNet (1.1c) WF Yes 2.66 2.46 2.12 1.69 83.02
Deep Xi-ResNet (1.1c) IBM Yes 1.36 2.16 1.26 1.30 77.57
Deep Xi-ResNet (1.1n) MMSE-LSA No 3.30 2.62 2.59 1.97 86.70
Deep Xi-MHANet (1.1c) MMSE-LSA Yes 3.45 2.75 2.73 2.08 87.11

DeepMMSE

DeepMMSE: A Deep Learning Approach to MMSE-Based Noise Power Spectral Density Estimation.

To save noise PSD estimate .mat files from DeepMMSE, please use the following:

./run.sh VER="mhanet-1.1c" INFER=1 GAIN="deepmmse"

Installation

Prerequisites for GPU usage:

To install:

  1. git clone https://github.com/anicolson/DeepXi.git
  2. python3 -m venv --system-site-packages ~/venv/DeepXi
  3. source ~/venv/DeepXi/bin/activate
  4. cd DeepXi
  5. pip install -r requirements.txt

Otherwise, a docker image can be found on Docker Hub: https://hub.docker.com/r/fhoerst/deepxi

How to use Deep Xi

Use run.sh to configure and run Deep Xi. Look at config.sh to set the paths to the dataset, models, and outputs.

Inference: To perform inference and save the outputs, use the following:

./run.sh VER="mhanet-1.1c" INFER=1 GAIN="mmse-lsa"

Please look in thoth/args.py for available gain functions and run.sh for further options.

Testing: To perform testing and get objective scores, use the following:

./run.sh VER="mhanet-1.1c" TEST=1 GAIN="mmse-lsa"

Please look in log/results for the results.

Training:

./run.sh VER="mhanet-1.1c" TRAIN=1

Ensure to delete the data directory before training. This will allow training lists and statistics for your training set to be saved and used. To retrain from a certain epoch, set --resume_epoch in run.sh to the desired epoch.

Current issues and potential areas of improvement

If you would like to contribute to Deep Xi, please investigate the following and compare it to current models:

  • Currently, the ResLSTM network is not performing as well as expected (when compared to TensorFlow 1.x performance).

Where can I get a dataset for Deep Xi?

Open-source training and testing sets are available for Deep Xi on IEEE DataPort:

[4] Deep Xi dataset (training, validation, and test set): http://dx.doi.org/10.21227/3adt-pb04.

[5] Test set from the original Deep Xi paper: http://dx.doi.org/10.21227/0ppr-yy46.

The MATLAB scripts used to generate these sets can be found in set.

Which audio do I use with Deep Xi?

Deep Xi operates on mono/single-channel audio (not stereo/dual-channel audio). Single-channel audio is used due to most cell phones using a single microphone. The available trained models operate on a sampling frequency of f_s=16000Hz, which is currently the standard sampling frequency used in the speech enhancement community. The sampling frequency can be changed in run.sh. Deep Xi can be trained using a higher sampling frequency (e.g. f_s=44100Hz), but this is unnecessary as human speech rarely exceeds 8 kHz (the Nyquist frequency of f_s=16000Hz is 8 kHz). The available trained models operate on a window duration and shift of T_d=32ms and T_s=16ms, respectively. To train a model on a different window duration and shift, T_d and T_s can be changed in run.sh. Currently, Deep Xi supports .wav, .mp3, and .flac audio codecs. The audio codec and bit rate does not affect the performance of Deep Xi.

Naming convention in the set/ directory

The following is already configured in the Deep Xi dataset.

Training set

The filenames of the waveforms in the train_clean_speech and train_noise directories are not restricted. There can be a different number of waveforms in each. The Deep Xi framework utilises each of the waveforms in train_clean_speech once during an epoch. For each train_clean_speech waveform of a mini-batch, the Deep Xi framework selects a random section of a randomely selected waveform from train_noise (that is at a length greater than or equal to the train_clean_speech waveform) and adds it to the train_clean_speech waveform at a randomly selected SNR level (the SNR level range can be set in run.sh).

Validation set

As the validation set must not change from epoch to epoch, a set of restrictions apply to the waveforms in val_clean_speech and val_noise. There must be the same amount of waveforms in val_clean_speech and val_noise. One waveform in val_clean_speech corresponds to only one waveform in val_noise, i.e. a clean speech and noise validation waveform pair. Each clean speech and noise validation waveform pair must have identical filenames and and an identical number of samples. Each clean speech and noise validation waveform pair must have the SNR level (dB) that they are to be mixed at placed at the end of their filenames. The convention used is _XdB, where X is replaced with the desired SNR level. E.g. val_clean_speech/NAME_-5dB.wav and val_noise/NAME_-5dB.wav. An example of the filenames for a clean speech and noise validation waveform pair is as follows: val_clean_speech/198_19-198-0003_Machinery17_15dB.wav and val_noise/198_19-198-0003_Machinery17_15dB.wav.

Test set

The filenames of the waveforms in the test_noisy_speech directory are not restricted. This is all that is required if you want inference outputs from Deep Xi, i.e. ./run.sh VER="ANY_NAME" INFER=1. If you are obtaining objective scores by using ./run.sh VER="ANY_NAME" TEST=1, then reference waveforms for the objective measures need to be placed in test_clean_speech. The waveforms in test_clean_speech and test_noisy_speech that correspond to each other must have the same number of samples (i.e. the same sequence length). The filename of the waveform in test_clean_speech that corresponds to a waveform in test_noisy_speech must be contained in the corresponding test noisy speech waveforn filename. E.g. if the filename of a test noisy speech waveform is test_noisy_speech/61-70968-0000_SIGNAL021_-5dB.wav, then the filename of the corresponding test clean speech waveform must be contained in the filename of the test noisy speech waveform: test_clean_speech/61-70968-0000.wav. This is because a test clean speech waveform may be used as a reference for multiple waveforms in test_noisy_speech (e.g. test_noisy_speech/61-70968-0000_SIGNAL021_0dB.wav, test_noisy_speech/61-70968-0000_SIGNAL021_5dB.wav, and test_noisy_speech/61-70968-0000_SIGNAL021_10dB.wav are additional test noisy speech waveforms that the test clean speech waveform from the previous example is a reference for).

Citation guide

Please cite the following depending on what you are using:

  • The Deep Xi framework is proposed in [1].
  • If using Deep Xi-MHANet, please cite [1] and [6].
  • If using Deep Xi-ResLSTM, please cite [1].
  • If using Deep Xi-ResNet, please cite [1] and [2].
  • If using DeepMMSE, please cite [2].
  • If using Deep Xi-RDLNet, please cite [1] and [3].
  • If using Deep Xi dataset, please cite [4].
  • If using the Test Set From 10.1016/j.specom.2019.06.002, please cite [5].

[1] A. Nicolson, K. K. Paliwal, Deep learning for minimum mean-square error approaches to speech enhancement, Speech Communication 111 (2019) 44 - 55, https://doi.org/10.1016/j.specom.2019.06.002.

[2] Q. Zhang, A. M. Nicolson, M. Wang, K. Paliwal and C. Wang, "DeepMMSE: A Deep Learning Approach to MMSE-based Noise Power Spectral Density Estimation," in IEEE/ACM Transactions on Audio, Speech, and Language Processing, vol. 28, pp. 1404-1415, 2020, doi: 10.1109/TASLP.2020.2987441.

[3] Mohammad Nikzad, Aaron Nicolson, Yongsheng Gao, Jun Zhou, Kuldip K. Paliwal, and Fanhua Shang. "Deep residual-dense lattice network for speech enhancement". In AAAI Conference on Artificial Intelligence, pages 8552–8559, 2020

[4] Aaron Nicolson, "Deep Xi dataset", IEEE Dataport, 2020. [Online]. Available: http://dx.doi.org/10.21227/3adt-pb04.

[5] Aaron Nicolson, "Test Set From 10.1016/j.specom.2019.06.002", IEEE Dataport, 2020. [Online]. Available: http://dx.doi.org/10.21227/0ppr-yy46.

[6] A. Nicolson, K. K. Paliwal, Masked multi-head self-attention for causal speech enhancement, Speech Communication 125 (2020) 80 - 96, https://doi.org/10.1016/j.specom.2019.06.002.