基于深度置信网络（DBN） 识别手写数据集minnist代码（直接上手，直接运行可用，亲测，python3）

二话不说给代码：

#urllib is used to download the utils file from deeplearning.net
import urllib.request
response = urllib.request.urlopen('http://deeplearning.net/tutorial/code/utils.py')
content = response.read()
target = open('utils.py', 'wb+')
target.write(content)
target.close()
#Import the math function for calculations
import math
#Tensorflow library. Used to implement machine learning models
import tensorflow as tf
#Numpy contains helpful functions for efficient mathematical calculations
import numpy as np
#Image library for image manipulation
from PIL import Image
#import Image
#Utils file

#导入MNIST数据

#Getting the MNIST data provided by Tensorflow
old_v = tf.compat.v1.logging.get_verbosity()
tf.compat.v1.logging.set_verbosity(tf.compat.v1.logging.ERROR)
from tensorflow.examples.tutorials.mnist import input_data

#Loading in the mnist data
mnist = input_data.read_data_sets("MNIST_data/", one_hot=True)
tf.compat.v1.logging.set_verbosity(old_v)
trX, trY, teX, teY = mnist.train.images, mnist.train.labels, mnist.test.images,
    mnist.test.labels




#构建RBM层

#Class that defines the behavior of the RBM
class RBM(object):

    def __init__(self, input_size, output_size):
        #Defining the hyperparameters
        self._input_size = input_size #Size of input
        self._output_size = output_size #Size of output
        self.epochs = 5 #Amount of training iterations
        self.learning_rate = 1.0 #The step used in gradient descent
        self.batchsize = 100 #The size of how much data will be used for training per sub iteration

        #Initializing weights and biases as matrices full of zeroes
        self.w = np.zeros([input_size, output_size], np.float32) #Creates and initializes the weights with 0
        self.hb = np.zeros([output_size], np.float32) #Creates and initializes the hidden biases with 0
        self.vb = np.zeros([input_size], np.float32) #Creates and initializes the visible biases with 0


    #Fits the result from the weighted visible layer plus the bias into a sigmoid curve
    def prob_h_given_v(self, visible, w, hb):
        #Sigmoid
        return tf.nn.sigmoid(tf.matmul(visible, w) + hb)

    #Fits the result from the weighted hidden layer plus the bias into a sigmoid curve
    def prob_v_given_h(self, hidden, w, vb):
        return tf.nn.sigmoid(tf.matmul(hidden, tf.transpose(w)) + vb)

    #Generate the sample probability
    def sample_prob(self, probs):
        return tf.nn.relu(tf.sign(probs - tf.random_uniform(tf.shape(probs))))

    #Training method for the model
    def train(self, X):
        #Create the placeholders for our parameters
        _w = tf.placeholder("float", [self._input_size, self._output_size])
        _hb = tf.placeholder("float", [self._output_size])
        _vb = tf.placeholder("float", [self._input_size])

        prv_w = np.zeros([self._input_size, self._output_size], np.float32) #Creates and initializes the weights with 0
        prv_hb = np.zeros([self._output_size], np.float32) #Creates and initializes the hidden biases with 0
        prv_vb = np.zeros([self._input_size], np.float32) #Creates and initializes the visible biases with 0


        cur_w = np.zeros([self._input_size, self._output_size], np.float32)
        cur_hb = np.zeros([self._output_size], np.float32)
        cur_vb = np.zeros([self._input_size], np.float32)
        v0 = tf.placeholder("float", [None, self._input_size])

        #Initialize with sample probabilities
        h0 = self.sample_prob(self.prob_h_given_v(v0, _w, _hb))
        v1 = self.sample_prob(self.prob_v_given_h(h0, _w, _vb))
        h1 = self.prob_h_given_v(v1, _w, _hb)

        #Create the Gradients
        positive_grad = tf.matmul(tf.transpose(v0), h0)
        negative_grad = tf.matmul(tf.transpose(v1), h1)

        #Update learning rates for the layers
        update_w = _w + self.learning_rate *(positive_grad - negative_grad) / tf.to_float(tf.shape(v0)[0])
        update_vb = _vb +  self.learning_rate * tf.reduce_mean(v0 - v1, 0)
        update_hb = _hb +  self.learning_rate * tf.reduce_mean(h0 - h1, 0)

        #Find the error rate
        err = tf.reduce_mean(tf.square(v0 - v1))

        #Training loop
        with tf.Session() as sess:
            sess.run(tf.initialize_all_variables())
            #For each epoch
            for epoch in range(self.epochs):
                #For each step/batch
                for start, end in zip(range(0, len(X), self.batchsize),range(self.batchsize,len(X), self.batchsize)):
                    batch = X[start:end]
                    #Update the rates
                    cur_w = sess.run(update_w, feed_dict={v0: batch, _w: prv_w, _hb: prv_hb, _vb: prv_vb})
                    cur_hb = sess.run(update_hb, feed_dict={v0: batch, _w: prv_w, _hb: prv_hb, _vb: prv_vb})
                    cur_vb = sess.run(update_vb, feed_dict={v0: batch, _w: prv_w, _hb: prv_hb, _vb: prv_vb})
                    prv_w = cur_w
                    prv_hb = cur_hb
                    prv_vb = cur_vb
                error=sess.run(err, feed_dict={v0: X, _w: cur_w, _vb: cur_vb, _hb: cur_hb})
                print('Epoch: %d' % epoch,'reconstruction error: %f' % error)
            self.w = prv_w
            self.hb = prv_hb
            self.vb = prv_vb

    #Create expected output for our DBN
    def rbm_outpt(self, X):
        input_X = tf.constant(X)
        _w = tf.constant(self.w)
        _hb = tf.constant(self.hb)
        out = tf.nn.sigmoid(tf.matmul(input_X, _w) + _hb)
        with tf.Session() as sess:
            sess.run(tf.global_variables_initializer())
            return sess.run(out)

#建立DBN

RBM_hidden_sizes = [500, 200 , 50 ] #create 2 layers of RBM with size 400 and 100

#Since we are training, set input as training data
inpX = trX

#Create list to hold our RBMs
rbm_list = []

#Size of inputs is the number of inputs in the training set
input_size = inpX.shape[1]

#For each RBM we want to generate
for i, size in enumerate(RBM_hidden_sizes):
    print('RBM: ',i,' ',input_size,'->', size)
    rbm_list.append(RBM(input_size, size))
    input_size = size




#神经网络

class NN(object):

    def __init__(self, sizes, X, Y):
        #Initialize hyperparameters
        self._sizes = sizes
        self._X = X
        self._Y = Y
        self.w_list = []
        self.b_list = []
        self._learning_rate =  1.0
        self._momentum = 0.0
        self._epoches = 10
        self._batchsize = 100
        input_size = X.shape[1]

        #initialization loop
        for size in self._sizes + [Y.shape[1]]:
            #Define upper limit for the uniform distribution range
            max_range = 4 * math.sqrt(6. / (input_size + size))

            #Initialize weights through a random uniform distribution
            self.w_list.append(
                np.random.uniform( -max_range, max_range, [input_size, size]).astype(np.float32))

            #Initialize bias as zeroes
            self.b_list.append(np.zeros([size], np.float32))
            input_size = size

    #load data from rbm
    def load_from_rbms(self, dbn_sizes,rbm_list):
        #Check if expected sizes are correct
        assert len(dbn_sizes) == len(self._sizes)

        for i in range(len(self._sizes)):
            #Check if for each RBN the expected sizes are correct
            assert dbn_sizes[i] == self._sizes[i]

        #If everything is correct, bring over the weights and biases
        for i in range(len(self._sizes)):
            self.w_list[i] = rbm_list[i].w
            self.b_list[i] = rbm_list[i].hb

    #Training method
    def train(self):
        #Create placeholders for input, weights, biases, output
        _a = [None] * (len(self._sizes) + 2)
        _w = [None] * (len(self._sizes) + 1)
        _b = [None] * (len(self._sizes) + 1)
        _a[0] = tf.placeholder("float", [None, self._X.shape[1]])
        y = tf.placeholder("float", [None, self._Y.shape[1]])

        #Define variables and activation functoin
        for i in range(len(self._sizes) + 1):
            _w[i] = tf.Variable(self.w_list[i])
            _b[i] = tf.Variable(self.b_list[i])
        for i in range(1, len(self._sizes) + 2):
            _a[i] = tf.nn.sigmoid(tf.matmul(_a[i - 1], _w[i - 1]) + _b[i - 1])

        #Define the cost function
        cost = tf.reduce_mean(tf.square(_a[-1] - y))

        #Define the training operation (Momentum Optimizer minimizing the Cost function)
        train_op = tf.train.MomentumOptimizer(
            self._learning_rate, self._momentum).minimize(cost)

        #Prediction operation
        predict_op = tf.argmax(_a[-1], 1)

        #Training Loop
        with tf.Session() as sess:
            #Initialize Variables
            sess.run(tf.global_variables_initializer())

            #For each epoch
            for i in range(self._epoches):

                #For each step
                for start, end in zip(
                    range(0, len(self._X), self._batchsize), range(self._batchsize, len(self._X), self._batchsize)):

                    #Run the training operation on the input data
                    sess.run(train_op, feed_dict={
                        _a[0]: self._X[start:end], y: self._Y[start:end]})
                for j in range(len(self._sizes) + 1):
                    #Retrieve weights and biases
                    self.w_list[j] = sess.run(_w[j])
                    self.b_list[j] = sess.run(_b[j])

                print("Accuracy rating for epoch " + str(i) + ": " + str(np.mean(np.argmax(self._Y, axis=1) ==
                              sess.run(predict_op, feed_dict={_a[0]: self._X, y: self._Y}))))


if __name__ =='__main__':
    ##训练数据集
    # For each RBM in our list
    for rbm in rbm_list:
        print('New RBM:')
        # Train a new one
        rbm.train(inpX)
        # Return the output layer
        inpX = rbm.rbm_outpt(inpX)

    print("正在训练。。。。。。")
    nNet = NN(RBM_hidden_sizes, trX, trY)
    nNet.load_from_rbms(RBM_hidden_sizes, rbm_list)
    nNet.train()