#coding:utf-8

#1.导入模块，生成模拟数据集

import tensorflow as tf

import numpy as np #np为科学计算模块

BATCH_SIZE = 8#表示一次喂入NN多少组数据，不能过大，会噎着

seed = 23455

#基于seed产生随机数

rng = np.random.RandomState(seed)

#随机数返回32*2列的矩阵，每行2个表示属性（体积和质量），作为输入数据集

X = rng.rand(32,2)

#从x这个矩阵中，取出每一行，判断如果和<1，y=1，否则，y=0

#作为输入数据集的标签（正确答案）

Y=[[int(x0+x1<1)] for (x0,x1) in X]

print("X:\n",X)

print("Y:\n",Y)

#2.定义神经网络的输入，参数和输出，定义前向传播过程

x = tf.placeholder(tf.float32,(None,2))

y_ = tf.placeholder(tf.float32,(None,1))

w1 = tf.Variable(tf.random_normal([2,3], stddev=1, seed=1))

w2 = tf.Variable(tf.random_normal([3,1], stddev=1, seed=1))

a = tf.matmul(x, w1)

y = tf.matmul(a, w2)

#3.定义损失函数及反向传播方法

loss = tf.reduce_mean(tf.square(y-y_))

train_step = tf.train.GradientDescentOptimizer(0.001).minimize(loss)#梯度下降

#train_step = tf.train.MomentumOptimizer(0.001,0.9).minimize(loss)

#train_step = tf.train.AdamOptimizer(0.001,0.9).minimize(loss)

#4.生成会话，训练STEPS轮

with tf.Session() as sess:

    init_op=tf.global_variables_initializer()

    sess.run(init_op)

    #输出目前还未训练的参数取值

    print("w1:\n", sess.run(w1))

    print("w2:\n", sess.run(w2))

    print("\n")

#训练模型

    STEPS=3000

    #训练3000轮，每次从训练集中挑选strart到end的数据，喂入数据

    for i in range(STEPS):

        start = (i*BATCH_SIZE)%32

        end = start + BATCH_SIZE

        sess.run(train_step, feed_dict={x:X[start:end], y_:Y[start:end]})

        if i%500 == 0:#每500次打印一轮

            total_loss = sess.run(loss,feed_dict={x:X,y_:Y})

            print("After %d training steps,loss on all data is %g" % (i,total_loss))

    #输出训练后的参数取值

    print("\n")

    print("w1:\n", sess.run(w1))

    print("w2:\n", sess.run(w2))

X:

 [[ 0.83494319  0.11482951]

 [ 0.66899751  0.46594987]

 [ 0.60181666  0.58838408]

 [ 0.31836656  0.20502072]

 [ 0.87043944  0.02679395]

 [ 0.41539811  0.43938369]

 [ 0.68635684  0.24833404]

 [ 0.97315228  0.68541849]

 [ 0.03081617  0.89479913]

 [ 0.24665715  0.28584862]

 [ 0.31375667  0.47718349]

 [ 0.56689254  0.77079148]

 [ 0.7321604   0.35828963]

 [ 0.15724842  0.94294584]

 [ 0.34933722  0.84634483]

 [ 0.50304053  0.81299619]

 [ 0.23869886  0.9895604 ]

 [ 0.4636501   0.32531094]

 [ 0.36510487  0.97365522]

 [ 0.73350238  0.83833013]

 [ 0.61810158  0.12580353]

 [ 0.59274817  0.18779828]

 [ 0.87150299  0.34679501]

 [ 0.25883219  0.50002932]

 [ 0.75690948  0.83429824]

 [ 0.29316649  0.05646578]

 [ 0.10409134  0.88235166]

 [ 0.06727785  0.57784761]

 [ 0.38492705  0.48384792]

 [ 0.69234428  0.19687348]

 [ 0.42783492  0.73416985]

 [ 0.09696069  0.04883936]]

Y:

 [[1], [0], [0], [1], [1], [1], [1], [0], [1], [1], [1], [0], [0], [0], [0], [0], [0], [1], [0], [0], [1], [1], [0], [1], [0], [1], [1], [1], [1], [1], [0], [1]]

w1:

 [[-0.81131822  1.48459876  0.06532937]

 [-2.4427042   0.0992484   0.59122431]]

w2:

 [[-0.81131822]

 [ 1.48459876]

 [ 0.06532937]]

After 0 training steps,loss on all data is 5.13118

After 500 training steps,loss on all data is 0.429111

After 1000 training steps,loss on all data is 0.409789

After 1500 training steps,loss on all data is 0.399923

After 2000 training steps,loss on all data is 0.394146

After 2500 training steps,loss on all data is 0.390597

w1:

 [[-0.70006633  0.9136318   0.08953571]

 [-2.3402493  -0.14641267  0.58823055]]

w2:

 [[-0.06024267]

 [ 0.91956186]

 [-0.0682071 ]]