【深度学习】实验07 使用TensorFlow完成逻辑回归
文章目录
- 使用TensorFlow完成逻辑回归
- 1. 环境设定
- 2. 数据读取
- 3. 准备好placeholder
- 4. 准备好参数/权重
- 5. 计算多分类softmax的loss function
- 6. 准备好optimizer
- 7. 在session里执行graph里定义的运算
- 附:系列文章
使用TensorFlow完成逻辑回归
TensorFlow是一种开源的机器学习框架,由Google Brain团队于2015年开发。它被广泛应用于图像和语音识别、自然语言处理、推荐系统等领域。
TensorFlow的核心是用于计算的数据流图。在数据流图中,节点表示数学操作,边表示张量(多维数组)。将操作和数据组合在一起的数据流图可以使 TensorFlow 对复杂的数学模型进行优化,同时支持分布式计算。
TensorFlow提供了Python,C++,Java,Go等多种编程语言的接口,让开发者可以更便捷地使用TensorFlow构建和训练深度学习模型。此外,TensorFlow还具有丰富的工具和库,包括TensorBoard可视化工具、TensorFlow Serving用于生产环境的模型服务、Keras高层封装API等。
TensorFlow已经发展出了许多优秀的模型,如卷积神经网络、循环神经网络、生成对抗网络等。这些模型已经在许多领域取得了优秀的成果,如图像识别、语音识别、自然语言处理等。
除了开源的TensorFlow,Google还推出了基于TensorFlow的云端机器学习平台Google Cloud ML,为用户提供了更便捷的训练和部署机器学习模型的服务。
解决分类问题里最普遍的baseline model就是逻辑回归,简单同时可解释性好,使得它大受欢迎,我们来用tensorflow完成这个模型的搭建。
1. 环境设定
import os
os.environ['TF_CPP_MIN_LOG_LEVEL']='2'import warnings
warnings.filterwarnings("ignore")import numpy as np
import tensorflow as tf
from tensorflow.examples.tutorials.mnist import input_data
import time
2. 数据读取
#使用tensorflow自带的工具加载MNIST手写数字集合
mnist = input_data.read_data_sets('./data/mnist', one_hot=True)
Extracting ./data/mnist/train-images-idx3-ubyte.gz
Extracting ./data/mnist/train-labels-idx1-ubyte.gz
Extracting ./data/mnist/t10k-images-idx3-ubyte.gz
Extracting ./data/mnist/t10k-labels-idx1-ubyte.gz
#查看一下数据维度
mnist.train.images.shape
(55000, 784)
#查看target维度
mnist.train.labels.shape
(55000, 10)
3. 准备好placeholder
batch_size = 128
X = tf.placeholder(tf.float32, [batch_size, 784], name='X_placeholder')
Y = tf.placeholder(tf.int32, [batch_size, 10], name='Y_placeholder')
4. 准备好参数/权重
w = tf.Variable(tf.random_normal(shape=[784, 10], stddev=0.01), name='weights')
b = tf.Variable(tf.zeros([1, 10]), name="bias")
logits = tf.matmul(X, w) + b
5. 计算多分类softmax的loss function
# 求交叉熵损失
entropy = tf.nn.softmax_cross_entropy_with_logits(logits=logits, labels=Y, name='loss')
# 求平均
loss = tf.reduce_mean(entropy)
6. 准备好optimizer
这里的最优化用的是随机梯度下降,我们可以选择AdamOptimizer这样的优化器
learning_rate = 0.01
optimizer = tf.train.AdamOptimizer(learning_rate).minimize(loss)
7. 在session里执行graph里定义的运算
#迭代总轮次
n_epochs = 30with tf.Session() as sess:# 在Tensorboard里可以看到图的结构writer = tf.summary.FileWriter('../graphs/logistic_reg', sess.graph)start_time = time.time()sess.run(tf.global_variables_initializer()) n_batches = int(mnist.train.num_examples/batch_size)for i in range(n_epochs): # 迭代这么多轮total_loss = 0for _ in range(n_batches):X_batch, Y_batch = mnist.train.next_batch(batch_size)_, loss_batch = sess.run([optimizer, loss], feed_dict={X: X_batch, Y:Y_batch}) total_loss += loss_batchprint('Average loss epoch {0}: {1}'.format(i, total_loss/n_batches))print('Total time: {0} seconds'.format(time.time() - start_time))print('Optimization Finished!')# 测试模型preds = tf.nn.softmax(logits)correct_preds = tf.equal(tf.argmax(preds, 1), tf.argmax(Y, 1))accuracy = tf.reduce_sum(tf.cast(correct_preds, tf.float32))n_batches = int(mnist.test.num_examples/batch_size)total_correct_preds = 0for i in range(n_batches):X_batch, Y_batch = mnist.test.next_batch(batch_size)accuracy_batch = sess.run([accuracy], feed_dict={X: X_batch, Y:Y_batch}) total_correct_preds += accuracy_batch[0]print('Accuracy {0}'.format(total_correct_preds/mnist.test.num_examples))writer.close()
Average loss epoch 0: 0.36748782022571785 Average loss epoch 1: 0.2978815356126198 Average loss epoch 2: 0.27840628396797845 Average loss epoch 3: 0.2783186247437706 Average loss epoch 4: 0.2783641471138923 Average loss epoch 5: 0.2750668214473413 Average loss epoch 6: 0.2687560408126502 Average loss epoch 7: 0.2713795114126239 Average loss epoch 8: 0.2657588795522154 Average loss epoch 9: 0.26322007090686916 Average loss epoch 10: 0.26289192279735646 Average loss epoch 11: 0.26248606019989873 Average loss epoch 12: 0.2604622903056356 Average loss epoch 13: 0.26015280702939403 Average loss epoch 14: 0.2581879366319496 Average loss epoch 15: 0.2590309207117085 Average loss epoch 16: 0.2630510463581219 Average loss epoch 17: 0.25501730025578767 Average loss epoch 18: 0.2547102673000945 Average loss epoch 19: 0.258298404375851 Average loss epoch 20: 0.2549241428330784 Average loss epoch 21: 0.2546788509283866 Average loss epoch 22: 0.259556887067837 Average loss epoch 23: 0.25428259843365575 Average loss epoch 24: 0.25442713139565676 Average loss epoch 25: 0.2553852511383159 Average loss epoch 26: 0.2503043229415978 Average loss epoch 27: 0.25468004046828596 Average loss epoch 28: 0.2552785321479633 Average loss epoch 29: 0.2506257003663859 Total time: 28.603315353393555 seconds Optimization Finished! Accuracy 0.9187
附:系列文章
| 序号 | 文章目录 | 直达链接 |
|---|---|---|
| 1 | 波士顿房价预测 | https://want595.blog.csdn.net/article/details/132181950 |
| 2 | 鸢尾花数据集分析 | https://want595.blog.csdn.net/article/details/132182057 |
| 3 | 特征处理 | https://want595.blog.csdn.net/article/details/132182165 |
| 4 | 交叉验证 | https://want595.blog.csdn.net/article/details/132182238 |
| 5 | 构造神经网络示例 | https://want595.blog.csdn.net/article/details/132182341 |
| 6 | 使用TensorFlow完成线性回归 | https://want595.blog.csdn.net/article/details/132182417 |
| 7 | 使用TensorFlow完成逻辑回归 | https://want595.blog.csdn.net/article/details/132182496 |
| 8 | TensorBoard案例 | https://want595.blog.csdn.net/article/details/132182584 |
| 9 | 使用Keras完成线性回归 | https://want595.blog.csdn.net/article/details/132182723 |
| 10 | 使用Keras完成逻辑回归 | https://want595.blog.csdn.net/article/details/132182795 |
| 11 | 使用Keras预训练模型完成猫狗识别 | https://want595.blog.csdn.net/article/details/132243928 |
| 12 | 使用PyTorch训练模型 | https://want595.blog.csdn.net/article/details/132243989 |
| 13 | 使用Dropout抑制过拟合 | https://want595.blog.csdn.net/article/details/132244111 |
| 14 | 使用CNN完成MNIST手写体识别(TensorFlow) | https://want595.blog.csdn.net/article/details/132244499 |
| 15 | 使用CNN完成MNIST手写体识别(Keras) | https://want595.blog.csdn.net/article/details/132244552 |
| 16 | 使用CNN完成MNIST手写体识别(PyTorch) | https://want595.blog.csdn.net/article/details/132244641 |
| 17 | 使用GAN生成手写数字样本 | https://want595.blog.csdn.net/article/details/132244764 |
| 18 | 自然语言处理 | https://want595.blog.csdn.net/article/details/132276591 |