王权富贵：通过BP的反向传输查看神经网络最匹配的特征图

王权富贵：通过BP的反向传输查看神经网络最匹配的特征图

这是使用BP反向还原机器认为最匹配的图案

（使用MNIST手写体数据库：）

比如：0

下面开始代码介绍：

这里的类中最后一个函数backquery（）是重点。这里有个问题应为使用S函数和S反函数所以值的范围不一样，需要校准。

import numpy
import scipy.special
import matplotlib.pyplot
class neuralNetwork:def __init__(self, inputnodes, hiddennodes, outputnodes, learningrate):self.inodes = inputnodesself.hnodes = des = outputnodesself.wih = al(0.0, pow(self.inodes, -0.5), (self.hnodes, self.inodes))self.who = al(0.0, pow(self.hnodes, -0.5), (des, self.hnodes))self.lr = learningrate#激活函数不可以随意更改，反向传输这里求导是固定的self.activation_function = lambda x: pit(x)self.inverse_activation_function = lambda x: scipy.special.logit(x)passdef train(self, inputs_list, targets_list):inputs = numpy.array(inputs_list, ndmin=2).Ttargets = numpy.array(targets_list, ndmin=2).Thidden_inputs = numpy.dot(self.wih, inputs)hidden_outputs = self.activation_function(hidden_inputs)final_inputs = numpy.dot(self.who, hidden_outputs)final_outputs = self.activation_function(final_inputs)output_errors = targets - final_outputshidden_errors = numpy.dot(self.who.T, output_errors) self.who += self.lr * numpy.dot((output_errors * final_outputs * (1.0 - final_outputs)), anspose(hidden_outputs))self.wih += self.lr * numpy.dot((hidden_errors * hidden_outputs * (1.0 - hidden_outputs)), anspose(inputs))passdef query(self, inputs_list):inputs = numpy.array(inputs_list, ndmin=2).Thidden_inputs = numpy.dot(self.wih, inputs)hidden_outputs = self.activation_function(hidden_inputs)final_inputs = numpy.dot(self.who, hidden_outputs)final_outputs = self.activation_function(final_inputs)return final_outputsdef backquery(self, targets_list):#这里是重点 主要是有效值的部分需要校准final_outputs = numpy.array(targets_list, ndmin=2).Tfinal_inputs = self.inverse_activation_function(final_outputs)hidden_outputs = numpy.dot(self.who.T, final_inputs)hidden_outputs -= numpy.min(hidden_outputs)hidden_outputs /= numpy.max(hidden_outputs)hidden_outputs *= 0.98hidden_outputs += 0.01hidden_inputs = self.inverse_activation_function(hidden_outputs)inputs = numpy.dot(self.wih.T, hidden_inputs)inputs -= numpy.min(inputs)inputs /= numpy.max(inputs)inputs *= 0.98inputs += 0.01return inputs

这里是开始训练，得到需要的权重。

input_nodes = 784
hidden_nodes = 200
output_nodes = 10
learning_rate = 0.1n = neuralNetwork(input_nodes,hidden_nodes,output_nodes, learning_rate)
training_data_file = open("mnist_train.csv", 'r')
training_data_list = training_adlines()
training_data_file.close()epochs = 5
for e in range(epochs):for record in training_data_list:all_values = record.split(',')inputs = (numpy.asfarray(all_values[1:]) / 255.0 * 0.99) + 0.01targets = s(output_nodes) + 0.01targets[int(all_values[0])] = ain(inputs, targets)passpasstest_data_file = open("mnist_test.csv", 'r')
test_data_list = test_adlines()
test_data_file.close()scorecard = []
for record in test_data_list:all_values = record.split(',')correct_label = int(all_values[0])inputs = (numpy.asfarray(all_values[1:]) / 255.0 * 0.99) + 0.01outputs = n.query(inputs)label = numpy.argmax(outputs)if (label == correct_label):scorecard.append(1)else:scorecard.append(0)passpassscorecard_array = numpy.asarray(scorecard)
print ("performance = ", scorecard_array.sum() / scorecard_array.size)

下面正式调用反向推理函数。

label = 1
# create the output signals for this label
targets = s(output_nodes) + 0.01
# all_values[0] is the target label for this record
targets[label] = 0.99
print(targets)# get image data
image_data = n.backquery(targets)# plot image data
matplotlib.pyplot.imshow(shape(28,28), cmap='Greys', interpolation='None')

下面是还原图片。