这篇文章主要介绍TensorFlow如何实现随机训练和批量训练,文中介绍的非常详细,具有一定的参考价值,感兴趣的小伙伴们一定要看完!
成都创新互联是一家集网站建设,张掖企业网站建设,张掖品牌网站建设,网站定制,张掖网站建设报价,网络营销,网络优化,张掖网站推广为一体的创新建站企业,帮助传统企业提升企业形象加强企业竞争力。可充分满足这一群体相比中小企业更为丰富、高端、多元的互联网需求。同时我们时刻保持专业、时尚、前沿,时刻以成就客户成长自我,坚持不断学习、思考、沉淀、净化自己,让我们为更多的企业打造出实用型网站。TensorFlow更新模型变量。它能一次操作一个数据点,也可以一次操作大量数据。一个训练例子上的操作可能导致比较“古怪”的学习过程,但使用大批量的训练会造成计算成本昂贵。到底选用哪种训练类型对机器学习算法的收敛非常关键。
为了TensorFlow计算变量梯度来让反向传播工作,我们必须度量一个或者多个样本的损失。
随机训练会一次随机抽样训练数据和目标数据对完成训练。另外一个可选项是,一次大批量训练取平均损失来进行梯度计算,批量训练大小可以一次上扩到整个数据集。这里将显示如何扩展前面的回归算法的例子——使用随机训练和批量训练。
批量训练和随机训练的不同之处在于它们的优化器方法和收敛。
# 随机训练和批量训练 #---------------------------------- # # This python function illustrates two different training methods: # batch and stochastic training. For each model, we will use # a regression model that predicts one model variable. import matplotlib.pyplot as plt import numpy as np import tensorflow as tf from tensorflow.python.framework import ops ops.reset_default_graph() # 随机训练: # Create graph sess = tf.Session() # 声明数据 x_vals = np.random.normal(1, 0.1, 100) y_vals = np.repeat(10., 100) x_data = tf.placeholder(shape=[1], dtype=tf.float32) y_target = tf.placeholder(shape=[1], dtype=tf.float32) # 声明变量 (one model parameter = A) A = tf.Variable(tf.random_normal(shape=[1])) # 增加操作到图 my_output = tf.multiply(x_data, A) # 增加L2损失函数 loss = tf.square(my_output - y_target) # 初始化变量 init = tf.global_variables_initializer() sess.run(init) # 声明优化器 my_opt = tf.train.GradientDescentOptimizer(0.02) train_step = my_opt.minimize(loss) loss_stochastic = [] # 运行迭代 for i in range(100): rand_index = np.random.choice(100) rand_x = [x_vals[rand_index]] rand_y = [y_vals[rand_index]] sess.run(train_step, feed_dict={x_data: rand_x, y_target: rand_y}) if (i+1)%5==0: print('Step #' + str(i+1) + ' A = ' + str(sess.run(A))) temp_loss = sess.run(loss, feed_dict={x_data: rand_x, y_target: rand_y}) print('Loss = ' + str(temp_loss)) loss_stochastic.append(temp_loss) # 批量训练: # 重置计算图 ops.reset_default_graph() sess = tf.Session() # 声明批量大小 # 批量大小是指通过计算图一次传入多少训练数据 batch_size = 20 # 声明模型的数据、占位符 x_vals = np.random.normal(1, 0.1, 100) y_vals = np.repeat(10., 100) x_data = tf.placeholder(shape=[None, 1], dtype=tf.float32) y_target = tf.placeholder(shape=[None, 1], dtype=tf.float32) # 声明变量 (one model parameter = A) A = tf.Variable(tf.random_normal(shape=[1,1])) # 增加矩阵乘法操作(矩阵乘法不满足交换律) my_output = tf.matmul(x_data, A) # 增加损失函数 # 批量训练时损失函数是每个数据点L2损失的平均值 loss = tf.reduce_mean(tf.square(my_output - y_target)) # 初始化变量 init = tf.global_variables_initializer() sess.run(init) # 声明优化器 my_opt = tf.train.GradientDescentOptimizer(0.02) train_step = my_opt.minimize(loss) loss_batch = [] # 运行迭代 for i in range(100): rand_index = np.random.choice(100, size=batch_size) rand_x = np.transpose([x_vals[rand_index]]) rand_y = np.transpose([y_vals[rand_index]]) sess.run(train_step, feed_dict={x_data: rand_x, y_target: rand_y}) if (i+1)%5==0: print('Step #' + str(i+1) + ' A = ' + str(sess.run(A))) temp_loss = sess.run(loss, feed_dict={x_data: rand_x, y_target: rand_y}) print('Loss = ' + str(temp_loss)) loss_batch.append(temp_loss) plt.plot(range(0, 100, 5), loss_stochastic, 'b-', label='Stochastic Loss') plt.plot(range(0, 100, 5), loss_batch, 'r--', label='Batch Loss, size=20') plt.legend(loc='upper right', prop={'size': 11}) plt.show()
输出:
Step #5 A = [ 1.47604525]
Loss = [ 72.55678558]
Step #10 A = [ 3.01128507]
Loss = [ 48.22986221]
Step #15 A = [ 4.27042341]
Loss = [ 28.97912598]
Step #20 A = [ 5.2984333]
Loss = [ 16.44779968]
Step #25 A = [ 6.17473984]
Loss = [ 16.373312]
Step #30 A = [ 6.89866304]
Loss = [ 11.71054649]
Step #35 A = [ 7.39849901]
Loss = [ 6.42773056]
Step #40 A = [ 7.84618378]
Loss = [ 5.92940331]
Step #45 A = [ 8.15709782]
Loss = [ 0.2142024]
Step #50 A = [ 8.54818344]
Loss = [ 7.11651039]
Step #55 A = [ 8.82354641]
Loss = [ 1.47823763]
Step #60 A = [ 9.07896614]
Loss = [ 3.08244276]
Step #65 A = [ 9.24868107]
Loss = [ 0.01143846]
Step #70 A = [ 9.36772251]
Loss = [ 2.10078788]
Step #75 A = [ 9.49171734]
Loss = [ 3.90913701]
Step #80 A = [ 9.6622715]
Loss = [ 4.80727625]
Step #85 A = [ 9.73786926]
Loss = [ 0.39915398]
Step #90 A = [ 9.81853104]
Loss = [ 0.14876099]
Step #95 A = [ 9.90371323]
Loss = [ 0.01657014]
Step #100 A = [ 9.86669159]
Loss = [ 0.444787]
Step #5 A = [[ 2.34371352]]
Loss = 58.766
Step #10 A = [[ 3.74766445]]
Loss = 38.4875
Step #15 A = [[ 4.88928795]]
Loss = 27.5632
Step #20 A = [[ 5.82038736]]
Loss = 17.9523
Step #25 A = [[ 6.58999157]]
Loss = 13.3245
Step #30 A = [[ 7.20851326]]
Loss = 8.68099
Step #35 A = [[ 7.71694899]]
Loss = 4.60659
Step #40 A = [[ 8.1296711]]
Loss = 4.70107
Step #45 A = [[ 8.47107315]]
Loss = 3.28318
Step #50 A = [[ 8.74283409]]
Loss = 1.99057
Step #55 A = [[ 8.98811722]]
Loss = 2.66906
Step #60 A = [[ 9.18062305]]
Loss = 3.26207
Step #65 A = [[ 9.31655025]]
Loss = 2.55459
Step #70 A = [[ 9.43130589]]
Loss = 1.95839
Step #75 A = [[ 9.55670166]]
Loss = 1.46504
Step #80 A = [[ 9.6354847]]
Loss = 1.49021
Step #85 A = [[ 9.73470974]]
Loss = 1.53289
Step #90 A = [[ 9.77956581]]
Loss = 1.52173
Step #95 A = [[ 9.83666706]]
Loss = 0.819207
Step #100 A = [[ 9.85569191]]
Loss = 1.2197
训练类型 | 优点 | 缺点 |
---|---|---|
随机训练 | 脱离局部最小 | 一般需更多次迭代才收敛 |
批量训练 | 快速得到最小损失 | 耗费更多计算资源 |
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