目录
1. 说明
本篇文章是CNN的另外一个例子,IKUN模型,是自制数据集的例子。之前的例子都是python中库自带的,但是这次的例子是自己搜集数据集,如下图所示整理。
在这里简单介绍如何自制数据集,本人采用爬虫下载图片,如下,只需要输入需要下载图片的名字,然后代码执行之后就会自动爬取图片。当然在使用爬虫的时候需要下载好相关的库。
"""
objective:爬取任意偶像/单词的百度图片
coding: UTF-8
"""
# 导入相关库
import re
import requests
import os
def download(html, search_word, j):
pic_url = re.findall('"objURL":"(.*?)",.*?"fromURL"', html, re.S) # 利用正则表达式找每一个图片的网址
# print(pic_url)
n = j * 60
for k in pic_url:
print('正在下载第' + str(n + 1) + '张图片,图片地址:' + str(k))
try:
pic = requests.get(k, timeout=20)
except requests.exceptions.ConnectionError:
print('当前图片无法下载')
continue
dir_path = r'D:\偶像图片\偶像' + search_word + '_' + str(n + 1) + '.jpg'
if not os.path.exists('D:\偶像图片'):
os.makedirs('D:\偶像图片')
fp = open(dir_path, 'wb')
fp.write(pic.content)
fp.close()
n += 1
if __name__ == '__main__':
name = input("输入你想要获取偶像的名称: ")
headers = {
'User-Agent': 'Mozilla/5.0 (Windows NT 10.0; Win64; x64) AppleWebKit/537.36 (KHTML, like Gecko) Chrome/84.0.4147.125 Safari/537.36'}
page = 2 # 可以自定义,想获取几页就是几页,一页有60张图片,但是有的可能就很少,自己注意下
for i in range(page):
url = 'https://image.baidu.com/search/flip?tn=baiduimage&ie=utf-8&word=' + name + '&pn=' + str(i * 20) # 网址
result = requests.get(url, headers=headers) # 请求网址
# print(result.content) # 如果运行失败,一步一步找到原因,可以先看下网页输出的内容
download(result.content.decode('utf-8'), name, i) # 保存图片
print("偶像图片下载完成")
2. IKUN模型
2.1 导入相关库
以下第三方库是python专门用于深度学习的库。需要提前下载并安装
from keras.models import Sequential
from keras.layers import Dense, Conv2D, Flatten, Dropout, MaxPool2D
from keras.optimizers import RMSprop, Adam
from keras.preprocessing.image import ImageDataGenerator
import sys, os # 目录结构
import matplotlib.pyplot as plt
from keras.callbacks import EarlyStopping, ReduceLROnPlateau
2.2 建立模型
这是采用另外一种书写方式建立模型。
构建了三层卷积层,三层池化层,然后是展平层(将二维特征图拉直输入给全连接层),然后是三层全连接层,并且加入了dropout层。
"1.模型建立"
# 1.卷积层,输入图片大小(150, 150, 3), 卷积核个数16,卷积核大小(5, 5), 激活函数'relu'
conv_layer1 = Conv2D(input_shape=(150, 150, 3), filters=16, kernel_size=(5, 5), activation='relu')
# 2.最大池化层,池化层大小(2, 2), 步长为2
max_pool1 = MaxPool2D(pool_size=(2, 2), strides=2)
# 3.卷积层,卷积核个数32,卷积核大小(5, 5), 激活函数'relu'
conv_layer2 = Conv2D(filters=32, kernel_size=(5, 5), activation='relu')
# 4.最大池化层,池化层大小(2, 2), 步长为2
max_pool2 = MaxPool2D(pool_size=(2, 2), strides=2)
# 5.卷积层,卷积核个数64,卷积核大小(5, 5), 激活函数'relu'
conv_layer3 = Conv2D(filters=64, kernel_size=(5, 5), activation='relu')
# 6.最大池化层,池化层大小(2, 2), 步长为2
max_pool3 = MaxPool2D(pool_size=(2, 2), strides=2)
# 7.卷积层,卷积核个数128,卷积核大小(5, 5), 激活函数'relu'
conv_layer4 = Conv2D(filters=128, kernel_size=(5, 5), activation='relu')
# 8.最大池化层,池化层大小(2, 2), 步长为2
max_pool4 = MaxPool2D(pool_size=(2, 2), strides=2)
# 9.展平层
flatten_layer = Flatten()
# 10.Dropout层, Dropout(0.2)
third_dropout = Dropout(0.2)
# 11.全连接层/隐藏层1,240个节点, 激活函数'relu'
hidden_layer1 = Dense(240, activation='relu')
# 12.全连接层/隐藏层2,84个节点, 激活函数'relu'
hidden_layer3 = Dense(84, activation='relu')
# 13.Dropout层, Dropout(0.2)
fif_dropout = Dropout(0.5)
# 14.输出层,输出节点个数1, 激活函数'sigmoid'
output_layer = Dense(1, activation='sigmoid')
model = Sequential([conv_layer1, max_pool1, conv_layer2, max_pool2,
conv_layer3, max_pool3, conv_layer4, max_pool4,
flatten_layer, third_dropout, hidden_layer1,
hidden_layer3, fif_dropout, output_layer])
2.3 模型编译
模型的优化器是Adam,学习率是0.01,
损失函数是binary_crossentropy,二分类交叉熵,
性能指标是正确率accuracy,
另外还加入了回调机制。
回调机制简单理解为训练集的准确率持续上升,而验证集准确率基本不变,此时已经出现过拟合,应该调制学习率,让验证集的准确率也上升。
"2.模型编译"
# 模型编译,2分类:binary_crossentropy
model.compile(optimizer=Adam(lr=0.0001), # 优化器选择Adam,初始学习率设置为0.0001
loss='binary_crossentropy', # 代价函数选择 binary_crossentropy
metrics=['accuracy']) # 设置指标为准确率
model.summary() # 模型统计
# 回调机制 动态调整学习率
reduce = ReduceLROnPlateau(monitor='val_accuracy', # 设置监测的值为val_accuracy
patience=2, # 设置耐心容忍次数为2
verbose=1, #
factor=0.5, # 缩放学习率的值为0.5,学习率将以lr = lr*factor的形式被减少
min_lr=0.000001 # 学习率最小值0.000001
) # 监控val_accuracy增加趋势
2.4 数据生成器
加载自制数据集
利用数据生成器对数据进行数据加强,即每次训练时输入的图片会是原图片的翻转,平移,旋转,缩放,这样是为了降低过拟合的影响。
然后通过迭代器进行数据加载,目标图像大小统一尺寸1501503,设置每次加载到训练网络的图像数目,设置而分类模型(默认one-hot编码),并且数据打乱。
# 生成器对象1: 归一化
gen = ImageDataGenerator(rescale=1 / 255.0)
# 生成器对象2: 归一化 + 数据加强
gen1 = ImageDataGenerator(
rescale=1 / 255.0,
rotation_range=5, # 图片随机旋转的角度5度
width_shift_range=0.1,
height_shift_range=0.1, # 水平和竖直方向随机移动0.1
shear_range=0.1, # 剪切变换的程度0.1
zoom_range=0.1, # 随机放大的程度0.1
fill_mode='nearest') # 当需要进行像素填充时选择最近的像素进行填充
# 拼接训练和验证的两个路径
train_path = os.path.join(sys.path[0], 'imgs', 'train')
val_path = os.path.join(sys.path[0], 'imgs', 'val')
print('训练数据路径: ', train_path)
print('验证数据路径: ', val_path)
# 训练和验证的两个迭代器
train_iter = gen1.flow_from_directory(train_path, # 训练train目录路径
target_size=(150, 150), # 目标图像大小统一尺寸150
batch_size=8, # 设置每次加载到内存的图像大小
class_mode='binary', # 设置分类模型(默认one-hot编码)
shuffle=True) # 是否打乱
val_iter = gen.flow_from_directory(val_path, # 测试val目录路径
target_size=(150, 150), # 目标图像大小统一尺寸150
batch_size=8, # 设置每次加载到内存的图像大小
class_mode='binary', # 设置分类模型(默认one-hot编码)
shuffle=True) # 是否打乱
2.5 模型训练
模型训练的次数是20,每1次循环进行测试
"3.模型训练"
# 模型的训练, model.fit
result = model.fit(train_iter, # 设置训练数据的迭代器
epochs=20, # 循环次数12次
validation_data=val_iter, # 验证数据的迭代器
callbacks=[reduce], # 回调机制设置为reduce
verbose=1)
2.6 模型保存
以.h5文件格式保存模型
"4.模型保存"
# 保存训练好的模型
model.save('my_ikun.h5')
2.7 模型训练结果的可视化
对模型的训练结果进行可视化,可视化的结果用曲线图的形式展现
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"5.模型训练时的可视化"
# 显示训练集和验证集的acc和loss曲线
acc = result.history['accuracy'] # 获取模型训练中的accuracy
val_acc = result.history['val_accuracy'] # 获取模型训练中的val_accuracy
loss = result.history['loss'] # 获取模型训练中的loss
val_loss = result.history['val_loss'] # 获取模型训练中的val_loss
# 绘值acc曲线
plt.figure(1)
plt.plot(acc, label='Training Accuracy')
plt.plot(val_acc, label='Validation Accuracy')
plt.title('Training and Validation Accuracy')
plt.legend()
plt.savefig('my_ikun_acc.png', dpi=600)
# 绘制loss曲线
plt.figure(2)
plt.plot(loss, label='Training Loss')
plt.plot(val_loss, label='Validation Loss')
plt.title('Training and Validation Loss')
plt.legend()
plt.savefig('my_ikun_loss.png', dpi=600)
plt.show() # 将结果显示出来
3. IKUN的CNN模型可视化结果图
Epoch 1/20
125/125 [==============================] - 30s 229ms/step - loss: 0.6012 - accuracy: 0.6450 - val_loss: 0.3728 - val_accuracy: 0.8200 - lr: 1.0000e-04
Epoch 2/20
125/125 [==============================] - 28s 223ms/step - loss: 0.3209 - accuracy: 0.8710 - val_loss: 0.3090 - val_accuracy: 0.8900 - lr: 1.0000e-04
Epoch 3/20
125/125 [==============================] - 34s 270ms/step - loss: 0.2564 - accuracy: 0.8990 - val_loss: 0.4873 - val_accuracy: 0.8075 - lr: 1.0000e-04
Epoch 4/20
125/125 [==============================] - ETA: 0s - loss: 0.2546 - accuracy: 0.9050
Epoch 4: ReduceLROnPlateau reducing learning rate to 4.999999873689376e-05.
125/125 [==============================] - 34s 275ms/step - loss: 0.2546 - accuracy: 0.9050 - val_loss: 0.3298 - val_accuracy: 0.8875 - lr: 1.0000e-04
Epoch 5/20
125/125 [==============================] - 31s 246ms/step - loss: 0.1867 - accuracy: 0.9310 - val_loss: 0.3577 - val_accuracy: 0.8500 - lr: 5.0000e-05
Epoch 6/20
125/125 [==============================] - 31s 245ms/step - loss: 0.1805 - accuracy: 0.9260 - val_loss: 0.2816 - val_accuracy: 0.8975 - lr: 5.0000e-05
Epoch 7/20
125/125 [==============================] - 30s 238ms/step - loss: 0.1689 - accuracy: 0.9340 - val_loss: 0.2679 - val_accuracy: 0.9100 - lr: 5.0000e-05
Epoch 8/20
125/125 [==============================] - 30s 237ms/step - loss: 0.2230 - accuracy: 0.9200 - val_loss: 0.2561 - val_accuracy: 0.9075 - lr: 5.0000e-05
Epoch 9/20
125/125 [==============================] - ETA: 0s - loss: 0.1542 - accuracy: 0.9480
Epoch 9: ReduceLROnPlateau reducing learning rate to 2.499999936844688e-05.
125/125 [==============================] - 30s 238ms/step - loss: 0.1542 - accuracy: 0.9480 - val_loss: 0.2527 - val_accuracy: 0.9100 - lr: 5.0000e-05
Epoch 10/20
125/125 [==============================] - 30s 239ms/step - loss: 0.1537 - accuracy: 0.9450 - val_loss: 0.2685 - val_accuracy: 0.9125 - lr: 2.5000e-05
Epoch 11/20
125/125 [==============================] - 33s 263ms/step - loss: 0.1395 - accuracy: 0.9540 - val_loss: 0.2703 - val_accuracy: 0.9100 - lr: 2.5000e-05
Epoch 12/20
125/125 [==============================] - ETA: 0s - loss: 0.1331 - accuracy: 0.9560
Epoch 12: ReduceLROnPlateau reducing learning rate to 1.249999968422344e-05.
125/125 [==============================] - 31s 250ms/step - loss: 0.1331 - accuracy: 0.9560 - val_loss: 0.2739 - val_accuracy: 0.9025 - lr: 2.5000e-05
Epoch 13/20
125/125 [==============================] - 31s 245ms/step - loss: 0.1374 - accuracy: 0.9500 - val_loss: 0.2551 - val_accuracy: 0.9250 - lr: 1.2500e-05
Epoch 14/20
125/125 [==============================] - 32s 254ms/step - loss: 0.1261 - accuracy: 0.9590 - val_loss: 0.2705 - val_accuracy: 0.9050 - lr: 1.2500e-05
Epoch 15/20
125/125 [==============================] - ETA: 0s - loss: 0.1256 - accuracy: 0.9620
Epoch 15: ReduceLROnPlateau reducing learning rate to 6.24999984211172e-06.
125/125 [==============================] - 31s 248ms/step - loss: 0.1256 - accuracy: 0.9620 - val_loss: 0.2449 - val_accuracy: 0.9125 - lr: 1.2500e-05
Epoch 16/20
125/125 [==============================] - 31s 245ms/step - loss: 0.1182 - accuracy: 0.9610 - val_loss: 0.2460 - val_accuracy: 0.9225 - lr: 6.2500e-06
Epoch 17/20
125/125 [==============================] - ETA: 0s - loss: 0.1261 - accuracy: 0.9610
Epoch 17: ReduceLROnPlateau reducing learning rate to 3.12499992105586e-06.
125/125 [==============================] - 30s 243ms/step - loss: 0.1261 - accuracy: 0.9610 - val_loss: 0.2466 - val_accuracy: 0.9250 - lr: 6.2500e-06
Epoch 18/20
125/125 [==============================] - 30s 240ms/step - loss: 0.1098 - accuracy: 0.9630 - val_loss: 0.2544 - val_accuracy: 0.9125 - lr: 3.1250e-06
Epoch 19/20
125/125 [==============================] - ETA: 0s - loss: 0.1165 - accuracy: 0.9630
Epoch 19: ReduceLROnPlateau reducing learning rate to 1.56249996052793e-06.
125/125 [==============================] - 31s 246ms/step - loss: 0.1165 - accuracy: 0.9630 - val_loss: 0.2476 - val_accuracy: 0.9225 - lr: 3.1250e-06
Epoch 20/20
125/125 [==============================] - 35s 281ms/step - loss: 0.1214 - accuracy: 0.9570 - val_loss: 0.2503 - val_accuracy: 0.9225 - lr: 1.5625e-06
从以上结果可知,模型的准确率达到了92%,准确率还是很高的。
4. 完整代码
from keras.models import Sequential
from keras.layers import Dense, Conv2D, Flatten, Dropout, MaxPool2D
from keras.optimizers import RMSprop, Adam
from keras.preprocessing.image import ImageDataGenerator
import sys, os # 目录结构
import matplotlib.pyplot as plt
from keras.callbacks import EarlyStopping, ReduceLROnPlateau
"1.模型建立"
# 1.卷积层,输入图片大小(150, 150, 3), 卷积核个数16,卷积核大小(5, 5), 激活函数'relu'
conv_layer1 = Conv2D(input_shape=(150, 150, 3), filters=16, kernel_size=(5, 5), activation='relu')
# 2.最大池化层,池化层大小(2, 2), 步长为2
max_pool1 = MaxPool2D(pool_size=(2, 2), strides=2)
# 3.卷积层,卷积核个数32,卷积核大小(5, 5), 激活函数'relu'
conv_layer2 = Conv2D(filters=32, kernel_size=(5, 5), activation='relu')
# 4.最大池化层,池化层大小(2, 2), 步长为2
max_pool2 = MaxPool2D(pool_size=(2, 2), strides=2)
# 5.卷积层,卷积核个数64,卷积核大小(5, 5), 激活函数'relu'
conv_layer3 = Conv2D(filters=64, kernel_size=(5, 5), activation='relu')
# 6.最大池化层,池化层大小(2, 2), 步长为2
max_pool3 = MaxPool2D(pool_size=(2, 2), strides=2)
# 7.卷积层,卷积核个数128,卷积核大小(5, 5), 激活函数'relu'
conv_layer4 = Conv2D(filters=128, kernel_size=(5, 5), activation='relu')
# 8.最大池化层,池化层大小(2, 2), 步长为2
max_pool4 = MaxPool2D(pool_size=(2, 2), strides=2)
# 9.展平层
flatten_layer = Flatten()
# 10.Dropout层, Dropout(0.2)
third_dropout = Dropout(0.2)
# 11.全连接层/隐藏层1,240个节点, 激活函数'relu'
hidden_layer1 = Dense(240, activation='relu')
# 12.全连接层/隐藏层2,84个节点, 激活函数'relu'
hidden_layer3 = Dense(84, activation='relu')
# 13.Dropout层, Dropout(0.2)
fif_dropout = Dropout(0.5)
# 14.输出层,输出节点个数1, 激活函数'sigmoid'
output_layer = Dense(1, activation='sigmoid')
model = Sequential([conv_layer1, max_pool1, conv_layer2, max_pool2,
conv_layer3, max_pool3, conv_layer4, max_pool4,
flatten_layer, third_dropout, hidden_layer1,
hidden_layer3, fif_dropout, output_layer])
"2.模型编译"
# 模型编译,2分类:binary_crossentropy
model.compile(optimizer=Adam(lr=0.0001), # 优化器选择Adam,初始学习率设置为0.0001
loss='binary_crossentropy', # 代价函数选择 binary_crossentropy
metrics=['accuracy']) # 设置指标为准确率
model.summary() # 模型统计
# 回调机制 动态调整学习率
reduce = ReduceLROnPlateau(monitor='val_accuracy', # 设置监测的值为val_accuracy
patience=2, # 设置耐心容忍次数为2
verbose=1, #
factor=0.5, # 缩放学习率的值为0.5,学习率将以lr = lr*factor的形式被减少
min_lr=0.000001 # 学习率最小值0.000001
) # 监控val_accuracy增加趋势
# 生成器对象1: 归一化
gen = ImageDataGenerator(rescale=1 / 255.0)
# 生成器对象2: 归一化 + 数据加强
gen1 = ImageDataGenerator(
rescale=1 / 255.0,
rotation_range=5, # 图片随机旋转的角度5度
width_shift_range=0.1,
height_shift_range=0.1, # 水平和竖直方向随机移动0.1
shear_range=0.1, # 剪切变换的程度0.1
zoom_range=0.1, # 随机放大的程度0.1
fill_mode='nearest') # 当需要进行像素填充时选择最近的像素进行填充
# 拼接训练和验证的两个路径
train_path = os.path.join(sys.path[0], 'imgs', 'train')
val_path = os.path.join(sys.path[0], 'imgs', 'val')
print('训练数据路径: ', train_path)
print('验证数据路径: ', val_path)
# 训练和验证的两个迭代器
train_iter = gen1.flow_from_directory(train_path, # 训练train目录路径
target_size=(150, 150), # 目标图像大小统一尺寸150
batch_size=8, # 设置每次加载到内存的图像大小
class_mode='binary', # 设置分类模型(默认one-hot编码)
shuffle=True) # 是否打乱
val_iter = gen.flow_from_directory(val_path, # 测试val目录路径
target_size=(150, 150), # 目标图像大小统一尺寸150
batch_size=8, # 设置每次加载到内存的图像大小
class_mode='binary', # 设置分类模型(默认one-hot编码)
shuffle=True) # 是否打乱
"3.模型训练"
# 模型的训练, model.fit
result = model.fit(train_iter, # 设置训练数据的迭代器
epochs=20, # 循环次数12次
validation_data=val_iter, # 验证数据的迭代器
callbacks=[reduce], # 回调机制设置为reduce
verbose=1)
"4.模型保存"
# 保存训练好的模型
model.save('my_ikun.h5')
"5.模型训练时的可视化"
# 显示训练集和验证集的acc和loss曲线
acc = result.history['accuracy'] # 获取模型训练中的accuracy
val_acc = result.history['val_accuracy'] # 获取模型训练中的val_accuracy
loss = result.history['loss'] # 获取模型训练中的loss
val_loss = result.history['val_loss'] # 获取模型训练中的val_loss
# 绘值acc曲线
plt.figure(1)
plt.plot(acc, label='Training Accuracy')
plt.plot(val_acc, label='Validation Accuracy')
plt.title('Training and Validation Accuracy')
plt.legend()
plt.savefig('my_ikun_acc.png', dpi=600)
# 绘制loss曲线
plt.figure(2)
plt.plot(loss, label='Training Loss')
plt.plot(val_loss, label='Validation Loss')
plt.title('Training and Validation Loss')
plt.legend()
plt.savefig('my_ikun_loss.png', dpi=600)
plt.show() # 将结果显示出来