BiGRU encoder + Attention decoder, based on "Listen, Attend and Spell"1.
The acoustic features are 80-dimensional filter banks. They are stacked every 3 consecutive frames, so the time resolution is reduced.
Following the standard recipe, we use 462-speaker training set with all SA records removed. Outputs are mapped to 39 phonemes when evalauting.
With this code you can achieve ~22% PER on the core test set.
$ pip install -r requirements.txtThis will create lists (*.csv) of audio file paths along with their transcripts:
$ python prepare_data.py --root ${DIRECTORY_OF_TIMIT}Check available options:
$ python train.py -hUse the default configuration for training:
$ python train.py exp/default.yamlYou can also write your own configuration file based on exp/default.yaml.
$ python train.py ${PATH_TO_YOUR_CONFIG}With the default configuration, the training logs are stored in exp/default/history.csv.
Specify your training logs accordingly.
$ python show_history.py exp/default/history.csv
During training, the program will keep monitoring the error rate on development set.
The checkpoint with the lowest error rate will be saved in the logging directory (by default exp/default/best.pth).
To evalutate the checkpoint on test set, run:
$ python eval.py exp/default/best.pthOr you can test random audio from the test set and see the attentions:
$ python inference.py exp/default/best.pth
Predict:
h# hh ih l pcl p gcl g r ey tcl d ix pcl p ih kcl k ix pcl p eh kcl k ix v dcl d ix tcl t ey dx ah v z h#
Ground-truth:
h# hh eh l pcl p gcl g r ey gcl t ix pcl p ih kcl k ix pcl p eh kcl k ix v pcl p ix tcl t ey dx ow z h#
[1] W. Chan et al., "Listen, Attend and Spell", https://arxiv.org/pdf/1508.01211.pdf
[2] J. Chorowski et al., "Attention-Based Models for Speech Recognition", https://arxiv.org/pdf/1506.07503.pdf
[3] M. Luong et al., "Effective Approaches to Attention-based Neural Machine Translation", https://arxiv.org/pdf/1508.04025.pdf