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Neural_Network/neuralnetwork_bp3.py
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134
Neural_Network/neuralnetwork_bp3.py
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#-*- coding:utf-8 -*-
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'''
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Author: Stephen Lee
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Date: 2017.9.21
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BP neural network with three layers
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'''
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import numpy as np
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import matplotlib.pyplot as plt
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class Bpnw():
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def __init__(self,n_layer1,n_layer2,n_layer3,rate_w=0.3,rate_t=0.3):
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'''
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:param n_layer1: number of input layer
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:param n_layer2: number of hiden layer
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:param n_layer3: number of output layer
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:param rate_w: rate of weight learning
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:param rate_t: rate of threshold learning
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'''
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self.num1 = n_layer1
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self.num2 = n_layer2
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self.num3 = n_layer3
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self.rate_weight = rate_w
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self.rate_thre = rate_t
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self.thre2 = -2*np.random.rand(self.num2)+1
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self.thre3 = -2*np.random.rand(self.num3)+1
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self.vji = np.mat(-2*np.random.rand(self.num2, self.num1)+1)
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self.wkj = np.mat(-2*np.random.rand(self.num3, self.num2)+1)
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def sig(self,x):
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return 1 / (1 + np.exp(-1*x))
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def sig_plain(self,x):
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return 1 / (1 + np.exp(-1*x))
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def do_round(self,x):
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return round(x, 3)
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def trian(self,patterns,data_train, data_teach, n_repeat, error_accuracy,draw_e = bool):
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'''
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:param patterns: the number of patterns
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:param data_train: training data x; numpy.ndarray
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:param data_teach: training data y; numpy.ndarray
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:param n_repeat: echoes
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:param error_accuracy: error accuracy
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:return: None
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'''
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data_train = np.asarray(data_train)
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data_teach = np.asarray(data_teach)
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print('-------------------Start Training-------------------------')
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print(' - - Shape: Train_Data ',np.shape(data_train))
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print(' - - Shape: Teach_Data ',np.shape(data_teach))
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rp = 0
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all_mse = []
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mse = 10000
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while rp < n_repeat and mse >= error_accuracy:
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alle = 0
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final_out = []
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for g in range(np.shape(data_train)[0]):
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net_i = data_train[g]
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out1 = net_i
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net_j = out1 * self.vji.T - self.thre2
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out2=self.sig(net_j)
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net_k = out2 * self.wkj.T - self.thre3
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out3 = self.sig(net_k)
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# learning process
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pd_k_all = np.multiply(np.multiply(out3,(1 - out3)),(data_teach[g]-out3))
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pd_j_all = np.multiply(pd_k_all * self.wkj,np.multiply(out2,1-out2))
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#upgrade weight
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self.wkj = self.wkj + pd_k_all.T * out2 *self.rate_weight
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self.vji = self.vji + pd_j_all.T * out1 * self.rate_weight
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#upgrade threshold
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self.thre3 = self.thre3 - pd_k_all * self.rate_thre
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self.thre2 = self.thre2 - pd_j_all * self.rate_thre
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#calculate sum of error
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errors = np.sum(abs((data_teach[g] - out3)))
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alle = alle + errors
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final_out.extend(out3.getA().tolist())
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final_out3 = [list(map(self.do_round,each)) for each in final_out]
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rp = rp + 1
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mse = alle/patterns
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all_mse.append(mse)
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def draw_error():
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yplot = [error_accuracy for i in range(int(n_repeat * 1.2))]
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plt.plot(all_mse, '+-')
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plt.plot(yplot, 'r--')
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plt.xlabel('Learning Times')
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plt.ylabel('All_mse')
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plt.grid(True,alpha = 0.7)
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plt.show()
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print('------------------Training Complished---------------------')
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print(' - - Training epoch: ', rp, ' - - Mse: %.6f'%mse)
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print(' - - Last Output: ', final_out3)
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if draw_e:
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draw_error()
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def predict(self,data_test):
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'''
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:param data_test: data test, numpy.ndarray
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:return: predict output data
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'''
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data_test = np.asarray(data_test)
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produce_out = []
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print('-------------------Start Testing-------------------------')
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print(' - - Shape: Test_Data ',np.shape(data_test))
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print(np.shape(data_test))
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for g in range(np.shape(data_test)[0]):
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net_i = data_test[g]
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out1 = net_i
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net_j = out1 * self.vji.T - self.thre2
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out2 = self.sig(net_j)
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net_k = out2 * self.wkj.T - self.thre3
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out3 = self.sig(net_k)
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produce_out.extend(out3.getA().tolist())
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res = [list(map(self.do_round,each)) for each in produce_out]
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return np.asarray(res)
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def main():
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#I will fish the mian function later
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pass
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if __name__ == '__main__':
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main()
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