Python-使用keras进行图像分类
图像分类是一种使用某种方法将图像分类为各自类别的方法-
从头开始训练小型网络
使用VGG16微调模型的顶层
示例
#First, include following libraries: # Importing all necessary libraries from keras.preprocessing.image import ImageDataGenerator from keras.models import Sequential from keras.layers import Conv2D, MaxPooling2D from keras.layers import Activation, Dropout, Flatten, Dense from keras import backend as K #Here, the train_data_dir is the train dataset directory. validation_data_dir is the #directory for validation data. nb_train_samples is the total number train #samples. nb_validation_samples is the total number of validation samples. img_width, img_height = 224, 224 train_data_dir = 'v_data/train' validation_data_dir = 'v_data/test' nb_train_samples =400 nb_validation_samples = 100 epochs = 10 batch_size = 16 #checking the format of the image if K.image_data_format() == 'channels_first': input_shape = (3, img_width, img_height) else: input_shape = (img_width, img_height, 3) model = Sequential()#Conv2D is the layer to convolve the image into multiple images model.add(Conv2D(32, (2, 2), input_shape=input_shape)) #Activation is the activation function. model.add(Activation('relu')) #MaxPooling2D is used to max pool the value from the given size #matrix and same is used for the next 2 layers. model.add(MaxPooling2D(pool_size=(2, 2))) model.add(Conv2D(32, (2, 2))) model.add(Activation('relu')) model.add(MaxPooling2D(pool_size=(2, 2))) model.add(Conv2D(64, (2, 2))) model.add(Activation('relu')) model.add(MaxPooling2D(pool_size=(2, 2))) #MaxPooling2D is used to max pool the value from the given size #matrix and same is used for the next 2 layers. model.add(Flatten()) #Dense is used to make this a fully connected model and is the #hidden layer. model.add(Dense(64)) model.add(Activation('relu')) #Dropout is used to avoid overfitting on the dataset. model.add(Dropout(0.5)) model.add(Dense(1)) model.add(Activation('sigmoid')) #Compile function is used here that involve use of loss, optimizers #and metrics.here loss function used is binary_crossentropy, #optimizer used is rmsprop. model.compile(loss='binary_crossentropy',optimizer='rmsprop', metrics=['accuracy']) #ImageDataGenerator that rescales the image, applies shear in some #range, zooms the image #and does horizontal flipping with the #image. This ImageDataGenerator includes all possible #orientation #of the image. train_datagen = ImageDataGenerator(rescale=1. / 255,shear_range=0.2, zoom_range=0.2,horizontal_flip=True) test_datagen = ImageDataGenerator(rescale=1. / 255) #train_datagen.flow_from_directory is the function that is used to #prepare data from the train_dataset directory Target_size specifies #the target size of the image. train_generator = train_datagen.flow_from_directory( train_data_dir, target_size=(img_width, img_height),batch_size=batch_size,class_mode='binary') validation_generator = test_datagen.flow_from_directory( validation_data_dir, target_size=(img_width, img_height), batch_size=batch_size, class_mode='binary') #fit_generator is used to fit the data into the model made above, #other factors used are steps_per_epochs tells us about the number #of times the model will execute for the training data. #epochs tells us the number of times model will be trained in forward #and backward pass. #validation_data is used to feed the validation/test data into the #model. #validation_steps denotes the number of validation/test samples. model.fit_generator(train_generator,steps_per_epoch=nb_train_samples // batch_size, epochs=epochs, validation_data=validation_generator, validation_steps=nb_validation_samples // batch_size) #Save the model model.save_weights('ImgmodelKeras_saved.h5')