Metadata-Version: 2.1
Name: eslearn
Version: 0.1.22a0
Summary: This project is designed for machine learning in resting-state fMRI field
Home-page: https://github.com/easylearn-fmri/
Author: Chao Li; Mengshi Dong
Author-email: lichao19870617@gmail.com
Maintainer: Chao Li; Mengshi Dong
Maintainer-email: lichao19870617@gmail.com
License: MIT License
Description: # <img src="./eslearn/logo/logo-lower.jpg" width = "200" height = "60" div align=left />  <font size=10>Make machine learning easy!</font>  
         
        Easylearn is designed for machine learning mainly in resting-state fMRI, radiomics and other fields (such as EEG). Easylearn is built on top of scikit-learn, pytorch and other packages. Easylearn can assist doctors and researchers who have limited coding experience to easily realize machine learning, e.g., (MR/CT/PET/EEG)imaging-marker- or other biomarker-based disease diagnosis and prediction, treatment response prediction, disease subtyping, dimensional decoding for transdiagnostic psychiatric diseases or other diseases, disease mechanism exploration and etc.  
        
        We focus on machine learning rather than data preprocessing. Many software, such as SPM, GRETNA, DPABI, REST, RESTPlus, CCS, FSL, Freesufer, nipy, nipype, nibabel, fmriprep and etc, can be used for data preprocessing.  
        
        # Citing information:
        If you think this software (or some function) is useful, citing the easylearn software in your paper or code would be greatly appreciated!
        Citing link: https://github.com/easylearn-fmri/easylearn  
        
        # GUI preview
        #### Main Interface
        ![Main Window](./img/GUI_main.png)  
        #### <center> Data loading Interface </center>
        ![Data loading](./img/GUI_data_loading.png)    
        #### <center> Feature engineering Interface (feature preprocessing) </center>
        ![Featur engineering](./img/preprocessing.png)   
        #### <center> Feature engineering Interface (dimension reduction) </center>
        ![Featur engineering](./img/dimreduction.png)   
        #### <center> Feature engineering Interface (feature selection) </center>
        ![Featur engineering](./img/feature_selection.png)   
        #### <center> Feature engineering Interface (unbalance treatment) </center>
        ![Featur engineering](./img/unbalance_treatment.png) 
        #### <center> Machine learning Interface </center>
        ![Machine learning](./img/machine_learning.png) 
        # Core Dependencies 
        The follows will be automatically install if you use "pip install -U easylearn" command    
        
        - sklearn
        - numpy
        - pandas
        - python-dateutil
        - pytz
        - scikit-learn
        - scipy
        - six
        - nibabel
        - imbalanced-learn
        - skrebate
        - matplotlib
        
        # Install  
        ```
        pip install -U easylearn
        ```
        
        # Development    
        At present, the project is in the development stage. We hope you can join us!   
        Any contributions you make will be appreciated and announced.   
        Please refer to [developer link](https://github.com/easylearn-fmri/easylearn/tree/master/eslearn/developer) for details.
        # <img src="./img/easylearn-flow-chart.jpg" width = "1000" height = "1200" div align=left />
        > Email: lichao19870617@gmail.com  
        > Wechat: 13591648206  
        
        # Initiators
        ##### Ke Xu
            kexu@vip.sina.com  
            Brain Function Research Section, The First Affiliated Hospital of China Medical University, Shenyang, Liaoning, PR China.  
            Department of Radiology, The First Affiliated Hospital of China Medical University.
        
        ##### Chao Li
            lichao19870617@gmail.com
            Brain Function Research Section, The First Affiliated Hospital of China Medical University, Shenyang, Liaoning, PR China.  
            
        ##### Mengshi Dong
            dongmengshi1990@163.com  
            Department of Radiology, The First Affiliated Hospital of China Medical University, Shenyang, Liaoning, PR China.   
        
        # Supervisors/Consultants 
        ##### Yanqing Tang  
            yanqingtang@163.com  
            1 Brain Function Research Section, The First Affiliated Hospital of China Medical
            University, Shenyang, Liaoning, PR China.  
            2 Department of Psychiatry, The First Affiliated Hospital of China Medical University,
            Shenyang, Liaoning, PR China.        
            
        ##### Yong He  
            yong.he@bnu.edu.cn  
            1 National Key Laboratory of Cognitive Neuroscience and Learning, Beijing Normal University, Beijing 100875, China  
            2 Beijing Key Laboratory of Brain Imaging and Connectomics, Beijing Normal University, Beijing 100875, China  
            3 IDG/McGovern Institute for Brain Research, Beijing Normal University, Beijing 100875, China 
        
        # Maintainers
        ##### Vacancy 1   
        Contributors will first add to the [contributors_list.md](./eslearn/developer/contributors_list.md). Once your contribution is important or more than or equal to 1/4 of the total code, we will add you as a maintainer.  
        
        ##### Vacancy 2  
        Contributors will first add to the [contributors_list.md](./eslearn/developer/contributors_list.md). Once your contribution is important or more than or equal to 1/4 of the total code, we will add you as a maintainer. 
        
        # Contributors  
        The current contributors are in [contributors_list.md](./eslearn/developer/contributors_list.md). Once your contribution is important or more than or equal to 1/4 of the total code, we will add you as a maintainer. 
        
        # Curent team members
        The current team members are in [current_team_members.md](./eslearn/developer/current_team_members.md). If you contributed your code, please add yourself to the contributor list.
        
        # Sponsors
            We welcome potential sponsors to sponsor our project! Please contact me for details <Wechat: QQ312214129>
        
        # Demo
        Although, the GUI is under development, you can use simple commands to accomplish some machine learning tasks.  
        The simplest demo is in the eslearn/examples.  
        Below is a demo of training a model to classify insomnia patients using weighted functional connectivity strength as features (You can easily use other voxel-wise metrics as features, such as ReHo, ALFF).
        This demo use svc as classifier, Principal Component Analysis (PCA) as dimension reduction method and Recursive feature elimination (RFE) as feature selection method (inner cross-validation).
        In each fold, this program will upper-resampling the training dataset to balance the cases with +1 labels and 0 labels.
        ***
        ```
        import numpy as np
        import eslearn.machine_learning.classfication.pca_rfe_svc_cv as pca_rfe_svc
        
        # =============================================================================
        # All inputs
        path_patients = r'D:\WorkStation_2018\Workstation_Old\WorkStation_2018-05_MVPA_insomnia_FCS\Degree\degree_gray_matter\Zdegree\Z_degree_patient\Weighted'  # All patients' image files, .nii format
        path_HC = r'D:\WorkStation_2018\Workstation_Old\WorkStation_2018-05_MVPA_insomnia_FCS\Degree\degree_gray_matter\Zdegree\Z_degree_control\Weighted'  # All HCs' image files, .nii format
        path_mask = r'G:\Softer_DataProcessing\spm12\spm12\tpm\Reslice3_TPM_greaterThan0.2.nii'  # Mask file for filter image
        path_out = r'D:\WorkStation_2018\Workstation_Old\WorkStation_2018-05_MVPA_insomnia_FCS\Degree\degree_gray_matter\Zdegree'  # Directory for saving results
        data_preprocess_method='StandardScaler'
        data_preprocess_level='group'  # In which level to preprocess data 'subject' or 'group'
        num_of_fold_outer=5  # How many folds to perform cross validation
        is_dim_reduction=1  # Whether to perform dimension reduction, default is using PCA to reduce the dimension.
        components=0.95   # How many percentages of the cumulatively explained variance to be retained. This is used to select the top principal components.
        step=0.1  # RFE parameter: percentages or number of features removed each iteration.
        num_fold_of_inner_rfeCV=5  # RFE parameter:  how many folds to perform inner RFE loop.
        n_jobs=-1  # RFE parameter:  how many jobs (parallel works) to perform inner RFE loop.
        is_showfig_finally=True  # Whether show results figure finally.
        is_showfig_in_each_fold=False  # Whether show results in each fold.
        # =============================================================================
        ***
        clf = pca_rfe_svc.PcaRfeSvcCV(
                path_patients=path_patients,
                path_HC=path_HC,
                path_mask=path_mask,
                path_out=path_out,
                data_preprocess_method=data_preprocess_method,
                data_preprocess_level=data_preprocess_level,
                num_of_fold_outer=num_of_fold_outer,  # How many folds to perform cross validation (Default: 5-fold cross validation)
                is_dim_reduction=is_dim_reduction,  # Default is using PCA to reduce the dimension.
                components=components, 
                step=step,
                num_fold_of_inner_rfeCV=num_fold_of_inner_rfeCV,
                n_jobs=n_jobs,
                is_showfig_finally=is_showfig_finally,  # Whether show results figure finally.
                is_showfig_in_each_fold=is_showfig_in_each_fold  # Whether show results in each fold.
            )
        
        results = clf.main_function()
        results = results.__dict__
        
        print(f"mean accuracy = {np.mean(results['accuracy'])}")
        print(f"std of accuracy = {np.std(results['accuracy'])}")
        print(f"mean sensitivity = {np.mean(results['sensitivity'])}")
        print(f"std of sensitivity = {np.std(results['sensitivity'])}")
        print(f"mean specificity = {np.mean(results['specificity'])}")
        print(f"std of specificity = {np.std(results['specificity'])}")
        print(f"mean AUC = {np.mean(results['AUC'])}")
        print(f"std of AUC = {np.std(results['AUC'])}")
        ```
        <br> <br />
        If the program runs successfully, some results file will be generated under the results folder (path_out), as follows:
        #### <center> Classification performances </center>
        ![Classification performances](./img/classification_performances.png)  
        <br> <br />
        #### <center>Classification performances (text, each row are results of one fold of the 5-fold cross-validation)</center>
        ![wei](./img/perf.png)  
        <br> <br />
        #### <center>Classfication weights (top 1%, BrainNet Viewer) </center>
        ![Top classfication weights](./img/wei.jpg) 
        <br> <br />
        #### <center>Predicted decision, predicted label and real label</center>
        ![Predicted decision, predicted label and real label](./img/dec_label.png)  
        
        
Platform: all
Classifier: Development Status :: 2 - Pre-Alpha
Classifier: License :: OSI Approved :: MIT License
Classifier: Intended Audience :: Science/Research
Classifier: Intended Audience :: Education
Classifier: Natural Language :: English
Classifier: Natural Language :: Chinese (Simplified)
Classifier: Programming Language :: Python :: 3
Classifier: Operating System :: OS Independent
Requires-Python: >=3.5
Description-Content-Type: text/markdown
