#必須放開頭,否則報錯。作用:把python新版本中print_function函數的特性導入到當前版本
from future import print_function
import tensorflow.compat.v1 as tf#將v2版本轉化成v1版本使用
tf.disable_v2_behavior()
import numpy as np
import matplotlib.pyplot as plt
#Construct a function that adds a neural layer
#inputs指輸入,in_size指輸入層維度,out_size指輸出層維度,activation_function()指激勵函數,默認None
def add_layer(inputs,in_size,out_size,activation_function=None):
Weights=tf.Variable(tf.random.normal([in_size,out_size]))#權重
biases=tf.Variable(tf.zeros([1,out_size])+0.1)#偏置,因爲一般偏置不爲0,於是人爲加上0.1
Wx_plus_b=tf.matmul(inputs,Weights)+biases#tf.matmul矩陣相乘
if activation_function is None:
outputs = Wx_plus_b
else:
outputs = activation_function(Wx_plus_b)
return outputs
#Make up some real data
#隨機x_data,這裏一定要定義dtype,[:,np.newaxis]指降低一個維度
x_data = np.linspace(-1,1,300,dtype=np.float32)[:,np.newaxis]
#概率密度函數np.random.normal(loc,scale,size),loc指分佈中心,scale指標準差(越小擬合的越好),size指類型(默認size=None)
noise = np.random.normal(0,0.05,x_data.shape).astype(np.float32)
#real y_data
y_data = np.square(x_data) - 0.5 + noise
#defind placeholder for inputs to network
#此函數可以理解爲形參,用於定義過程,在執行的時候再賦具體的值
xs = tf.placeholder(tf.float32,[None,1])#一定要定義tf.float32,系統不默認
ys = tf.placeholder(tf.float32,[None,1])
#add hidden layer
#這裏的激勵函數爲relu函數,指輸入層一個神經元,輸出層十個神經元
l1 = add_layer(xs,1,10,activation_function = tf.nn.relu)
#add outputs layer
#這裏激勵函數爲None
prediction = add_layer(l1,10,1,activation_function = None)
#the error between real data and prediction
function(){ //常見問題:http://www.fx61.com/faq
#定義loss,指損失函數總和的平均值,注意這裏必須得加上一個reduction_indices=[]。(會說明)
loss = tf.reduce_mean(tf.reduce_sum(tf.square(ys - prediction),reduction_indices=[1]))
#這裏用GradientDescentOptimizer做爲優化器,就是梯度下降法
train_step = tf.train.GradientDescentOptimizer(0.1).minimize(loss)
#Activate
sess = tf.Session()#非常重要
#定義全局初始化(兩種表示方法:global_variables_initializer,initialize_all_variables)
#建議用global_variables_initializer新版本
init = tf.global_variables_initializer()
sess.run(init)
for i in range(1000):
#train,這裏的feed_dict是一個字典,用於導入數據x_data和y_data
sess.run(train_step,feed_dict = {xs : x_data, ys : y_data})
#每50步打印一次
if i % 50 == 0:
print(sess.run(loss,feed_dict = {xs : x_data, ys : y_data}))
可視化結果
#Visualization of results
fig = plt.figure()#建立一個背景
ax = fig.add_subplot(1,1,1)#建立標註
ax.scatter(x_data , y_data)#scatter指散點
plt.ion()#全局變量時,最好註釋掉。作用:使圖像連續
plt.show()
for i in range(1000):
training
sess.run(train_step, feed_dict={xs: x_data, ys: y_data})
if i % 50 == 0:
# to visualize the result and improvement
#指沒有圖像就跳過(簡單理解:先抹去線,再出現下一次線)
try:
ax.lines.remove(lines[0])
except Exception:
pass
prediction_value = sess.run(prediction, feed_dict={xs: x_data})
# plot the prediction
lines = ax.plot(x_data, prediction_value, 'r-', lw=3)#紅色,寬度爲3
plt.pause(0.1)#指暫停幾秒,作者實驗表明0.1~0.3可視化效果明顯