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SPDNet_Local_Learning.py
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SPDNet_Local_Learning.py
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##################################################################################################
# FTL Draft Code for Subject-local Analysis
# Author:Ce Ju, Dashan Gao
# Date : July 29, 2020
# Paper : Ce Ju et al., Federated Transfer Learning for EEG Signal Classification, IEEE EMBS 2020.
# Description: One subject(participant) locally train an SPDNetwork for EEG signal classification using its own data.
##################################################################################################
import warnings
import datetime
import numpy as np
import torch
from torch.autograd import Variable
import torch.nn.functional as F
from mne.decoding import CSP
# pyriemann import
from pyriemann.classification import MDM, TSclassifier, FgMDM
from sklearn.pipeline import Pipeline
from sklearn.linear_model import LogisticRegression
from sklearn import svm
warnings.filterwarnings('ignore')
def SPD_experients(cov_data, labels):
import SPDNet
random_index = np.arange(cov_data.shape[0])
np.random.shuffle(random_index)
cov_data = cov_data[random_index, :, :]
labels = labels[random_index]
split_num = int(np.floor(cov_data.shape[0] * 0.8))
cov_data_train = cov_data[0:split_num, :, :]
cov_data_test = cov_data[split_num:cov_data.shape[0], :, :]
print('split_num: ', split_num)
print('rest_num: ', labels.shape[0] - split_num)
print('-------------------------------------------------------')
input_data_train = Variable(torch.from_numpy(cov_data_train)).double()
input_data_test = Variable(torch.from_numpy(cov_data_test)).double()
target_train = Variable(torch.LongTensor(labels[0:split_num]))
target_test = Variable(torch.LongTensor(labels[split_num:labels.shape[0]]))
model = SPDNet.SPDNetwork_2()
for _ in range(500):
stime = datetime.datetime.now()
logits = model(input_data_train)
output = F.log_softmax(logits, dim=-1)
loss = F.nll_loss(output, target_train)
pred = output.data.max(1, keepdim=True)[1]
correct = pred.eq(target_train.data.view_as(pred)).long().cpu().sum()
loss.backward()
lr = 0.1
model.update_all_layers(lr)
etime = datetime.datetime.now()
dtime = etime.second - stime.second
logits = model(input_data_test)
output = F.log_softmax(logits, dim=-1)
pred = output.data.max(1, keepdim=True)[1]
correct_test = pred.eq(target_test.data.view_as(pred)).long().cpu().sum()
return correct_test.item() / pred.shape[0]
if __name__ == '__main__':
# Load data.
data = np.load('raw_data/normalized_original_train_sample.npy')
epoch_data_train = np.load('raw_data/normalized_original_epoch_data_train.npy')
label = np.load('raw_data/train_label.npy')
index = np.load('raw_data/index.npy')
FULL_MDM = []
FULL_FGMDM = []
FULL_TSC = []
FULL_CSP_lr = []
FULL_CSP_svm = []
for bad_subject_index in range(108):
# bad_subject_index = [2, 8, 16, 17, 22, 23, 27, 35, 37, 38, 39, 40, 44, 46, 57, 62, 63, 66, 73, 75, 76, 77, 89, 95, 96, 98, 100, 101]
# bad_subject_index = 2
cov_data_bad = data[bad_subject_index]
labels_bad = label[bad_subject_index]
epochs_data_train_bad = epoch_data_train[bad_subject_index]
MDM_record = []
FGMDM_record = []
TSC_record = []
CSP_lr_record = []
CSP_svm_record = []
for fold in range(1, 6):
train = cov_data_bad[index[bad_subject_index] != fold]
train_CSP = epochs_data_train_bad[index[bad_subject_index] != fold]
train_label = labels_bad[index[bad_subject_index] != fold]
test = cov_data_bad[index[bad_subject_index] == fold]
test_CSP = epochs_data_train_bad[index[bad_subject_index] == fold]
test_label = labels_bad[index[bad_subject_index] == fold]
box_length = np.sum([index[bad_subject_index] == fold])
mdm = MDM(metric=dict(mean='riemann', distance='riemann'))
mdm.fit(train, train_label)
pred = mdm.predict(test)
print('MDM: {:4f}'.format(np.sum(pred == test_label) / box_length))
MDM_record.append(np.sum(pred == test_label) / box_length)
print('-----------------------------------------')
Fgmdm = FgMDM(metric=dict(mean='riemann', distance='riemann'))
Fgmdm.fit(train, train_label)
pred = Fgmdm.predict(test)
print('FGMDM: {:4f}'.format(np.sum(pred == test_label) / box_length))
FGMDM_record.append(np.sum(pred == test_label) / box_length)
print('-----------------------------------------')
clf = TSclassifier()
clf.fit(train, train_label)
pred = clf.predict(test)
print('TSC: {:4f}'.format(np.sum(pred == test_label) / box_length))
TSC_record.append(np.sum(pred == test_label) / box_length)
print('-----------------------------------------')
lr = LogisticRegression()
csp = CSP(n_components=4, reg='ledoit_wolf', log=True)
clf = Pipeline([('CSP', csp), ('LogisticRegression', lr)])
clf.fit(train_CSP, train_label)
pred = clf.predict(test_CSP)
print('CSP_lr: {:4f}'.format(np.sum(pred == test_label) / box_length))
CSP_lr_record.append(np.sum(pred == test_label) / box_length)
print('-----------------------------------------')
lr = svm.SVC(kernel='rbf')
csp = CSP(n_components=4, reg='ledoit_wolf', log=True)
clf = Pipeline([('CSP', csp), ('svc', lr)])
clf.fit(train_CSP, train_label)
pred = clf.predict(test_CSP)
print('CSP_svm: {:4f}'.format(np.sum(pred == test_label) / box_length))
CSP_svm_record.append(np.sum(pred == test_label) / box_length)
print("------------------------------------------------------------------------")
FULL_MDM.append(np.mean(MDM_record))
FULL_TSC.append(np.mean(TSC_record))
FULL_FGMDM.append(np.mean(FGMDM_record))
FULL_CSP_lr.append(np.mean(CSP_lr_record))
FULL_CSP_svm.append(np.mean(CSP_svm_record))
print('MDM Record: ', FULL_MDM)
print('R-Kernel Record: ', FULL_FGMDM)
print('TSC Record: ', FULL_TSC)
print('CSP_lr Record: ', FULL_CSP_lr)
print('CSP_svm Record: ', FULL_CSP_svm)
print('-----------------------')
print('MDM: ', np.mean(FULL_MDM))
print('R-Kernel: ', np.mean(FULL_FGMDM))
print('TSC: ', np.mean(FULL_TSC))
print('CSP_lr: ', np.mean(FULL_CSP_lr))
print('CSP_svm: ', np.mean(FULL_CSP_svm))