Official Tensorflow implementation of ICASSP 2023 paper, "Temporal Modeling Matters: A Novel Temporal Emotional Modeling Approach for Speech Emotion Recognition". [paper] [code]
In this paper, we propose a Temporal-aware bI-direction Multi-scale Network, termed TIM-Net, which is a novel temporal emotional modeling approach to learn multi-scale contextual affective representations from various time scales.
Our MFCC features files (*.npy):
Baidu links
: https://pan.baidu.com/s/1Y-GDJXpF0FqjcGGN6y84JA?pwd=MFCCcode
: MFCC
Google links
: https://drive.google.com/drive/folders/1nl7hej--Nds2m3MrMDHT63fNL-yRRe3dOur testing model weight files (*.hdf5):
Baidu links
: https://pan.baidu.com/s/1EtjhuljeHwvIjYG8hYtMXQ?pwd=HDF5code
: HDF5
Google links
: https://drive.google.com/drive/folders/1ZjgcT6R0A0C2twXatgpimFh1a3IL81pw
$ git clone https://github.com/Jiaxin-Ye/TIM-Net_SER.git
$ cd TIM-Net_SER/Code
Our code is based on Python 3 (>= 3.8). There are a few dependencies to run the code. The major libraries are listed as follows:
- Tensorflow-gpu (>= 2.5.0)
- Keras (>= 2.5.0, the same as TF)
- Scikit-learn (== 1.0.2)
- NumPy (>= 1.19.5)
- SciPy (== 1.8.0)
- librosa (>= 0.8.1)
- Pandas (== 1.4.1)
- ......
$ pip install -r requirement.txt
The six public emotion datasets are used in the experiments: the CASIA, EMODB, EMOVO, IEMOCAP, RAVDESS, and SAVEE. The languages of IEMOCAP, RAVDESS and SAVEE are English, while the CASIA, EMODB and EMOVO datasets contain Chinese, German and Italian speech signals.
In the experiments, the 39-D static MFCCs are extracted using the Librosa toolbox with the default settings. Specifically, the frame length is 50 ms, the frame shift is 12.5 ms, the sample rate is 22050 Hz and the window function added for the speech is Hamming window. In the single-corpus SER task, the "mean_signal_length" is set to 88000, 96000, 96000, 310000, 110000, 130000 for CASIA, EMODB, EMOVO, IEMOCAP, RAVDESS and SAVEE, which is almost the same as the maximum length of the input sequences. If you are not convenient to preprocess these features, you can download them from our shared link to MFCC
folder.
$ python extract_feature.py --data_name CASIA --mean_signal_length 88000
$ python extract_feature.py --data_name EMODB --mean_signal_length 96000
$ python extract_feature.py --data_name EMOVO --mean_signal_length 96000
$ python extract_feature.py --data_name IEMOCAP --mean_signal_length 310000
$ python extract_feature.py --data_name RAVDE --mean_signal_length 110000
$ python extract_feature.py --data_name SAVEE --mean_signal_length 130000
$ python main.py --mode train --data RAVDE --split_fold 10 --random_seed 46 --epoch 500 --gpu 0
If you want to test your model on 10-fold cross-validation manner with `X' random seed, you can run the following commands:
$ python main.py --mode test --data CASIA --test_path ./Test_Models/CASIA_32 --split_fold 10 --random_seed 32
$ python main.py --mode test --data EMODB --test_path ./Test_Models/EMODB_46 --split_fold 10 --random_seed 46
$ python main.py --mode test --data EMOVO --test_path ./Test_Models/EMOVO_1 --split_fold 10 --random_seed 1
$ python main.py --mode test --data IEMOCAP --test_path ./Test_Models/IEMOCAP_16 --split_fold 10 --random_seed 16
$ python main.py --mode test --data RAVDE --test_path ./Test_Models/RAVDE_46 --split_fold 10 --random_seed 46
$ python main.py --mode test --data SAVEE --test_path ./Test_Models/SAVEE_44 --split_fold 10 --random_seed 44
You can download our model files from our shared link to Test_Models
folder.
The cross-entropy criterion is used as the objective function and overall epoch is set to 500. Adam algorithm is adopted to optimize the model with an initial learning rate
Since not all SOTA methods we compared provide their source codes or model sizes in the paper, we can only select some typical ones for size comparison. For example, the model sizes of Light-SERNet (0.88 MB), GM-TCN (1.13 MB), and CPAC (1.23 MB) are all larger than TIM-Net (0.40 MB). Our proposed models are trained on an Nvidia GeForce RTX 3090 GPU with an average of 60 ms per step. The results demonstrate that our TIM-Net is lightweight yet effective.
We show the accuracy and loss curves on the whole six corpora in the following figures. The experimental results indicate that TIM-Net does not exhibit significant overfitting issues, and its convergence curves remain relatively stable.
TIM-NEt_SER
├─ Code
│ ├─ MFCC (Download MFCC files here)
│ ├─ Models (Store model files)
│ ├─ Results (Store result files)
│ ├─ Test_Models (Download pretrained models here)
│ ├─ Model.py
│ ├─ TIMNET.py
│ ├─ Common_Model.py
│ ├─ main.py
│ ├─ extract_feature.py
│ └─ requirement.txt
├─ README.md
- We thank the @adrianastan, @VlaDanilov, @NAM-hj, @rageSpin, and other researchers on the GitHub with many valuable and insightful suggestions.
- If you find this project useful for your research, please cite our paper:
@inproceedings{TIMNET,
title={Temporal Modeling Matters: A Novel Temporal Emotional Modeling Approach for Speech Emotion Recognition},
author = {Ye, Jiaxin and Wen, Xincheng and Wei, Yujie and Xu, Yong and Liu, Kunhong and Shan, Hongming},
booktitle = {ICASSP 2023-2023 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), Rhodes Island, Greece, June 4-10, 2023},
pages={1--5},
year = {2023}
}
After carefully rechecking the single-corpus SER code of CPAC [1] and GM-TCNet [2], we identified that there is the same improper utilization of the callback function leading to overfitting issues, which has not been addressed in some open-sourced projects and works. Here, we have updated the corresponding results to avoid overfitting issues. The updated experimental results show that the performance remain competitive.
UAR (%)/WAR (%) | CASIA | EMODB | RAVDESS | SAVEE |
---|---|---|---|---|
GM-TCNet | 85.50 / 85.50 | 86.17 / 85.70 | 82.78 / 82.62 | 75.83 / 73.57 |
CPAC | 88.33 / 88.33 | 86.92 / 86.15 | 81.25 / 80.47 | 75.63 / 73.21 |
TIM-Net | 91.08 / 91.08 | 89.19 / 90.28 | 90.04 / 90.07 | 77.26 / 79.36 |
[1] CTL-MTNet: A Novel CapsNet and Transfer Learning-Based Mixed Task Net for the Single-Corpus and Cross-Corpus Speech Emotion Recognition, IJCAI 2022.
[2] GM-TCNet: Gated Multi-scale Temporal Convolutional Network using Emotion Causality for Speech Emotion Recognition, Speech Communication 2022.