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这篇文章将为大家详细讲解有关keras导入weights的方法是什么?,小编觉得挺实用的,因此分享给大家做个参考,希望大家阅读完这篇文章后可以有所收获。
keras源码engine中toplogy.py定义了加载权重的函数:
load_weights(self, filepath, by_name=False)
其中默认by_name为False,这时候加载权重按照网络拓扑结构加载,适合直接使用keras中自带的网络模型,如VGG16
VGG19/resnet50等,源码描述如下:
If `by_name` is False (default) weights are loaded
based on the network's topology, meaning the architecture
should be the same as when the weights were saved.
Note that layers that don't have weights are not taken
into account in the topological ordering, so adding or
removing layers is fine as long as they don't have weights.
若将by_name改为True则加载权重按照layer的name进行,layer的name相同时加载权重,适合用于改变了
模型的相关结构或增加了节点但利用了原网络的主体结构情况下使用,源码描述如下:
If `by_name` is True, weights are loaded into layers
only if they share the same name. This is useful
for fine-tuning or transfer-learning models where
some of the layers have changed.
在进行边缘检测时,利用VGG网络的主体结构,网络中增加反卷积层,这时加载权重应该使用
model.load_weights(filepath,by_name=True)
补充知识:Keras下实现mnist手写数字
之前一直在用tensorflow,被同学推荐来用keras了,把之前文档中的mnist手写数字数据集拿来练手,
代码如下。
import struct import numpy as np import os import keras from keras.models import Sequential from keras.layers import Dense from keras.optimizers import SGD def load_mnist(path, kind): labels_path = os.path.join(path, '%s-labels.idx1-ubyte' % kind) images_path = os.path.join(path, '%s-images.idx3-ubyte' % kind) with open(labels_path, 'rb') as lbpath: magic, n = struct.unpack('>II', lbpath.read(8)) labels = np.fromfile(lbpath, dtype=np.uint8) with open(images_path, 'rb') as imgpath: magic, num, rows, cols = struct.unpack(">IIII", imgpath.read(16)) images = np.fromfile(imgpath, dtype=np.uint8).reshape(len(labels), 784) #28*28=784 return images, labels #loading train and test data X_train, Y_train = load_mnist('.\\data', kind='train') X_test, Y_test = load_mnist('.\\data', kind='t10k') #turn labels to one_hot code Y_train_ohe = keras.utils.to_categorical(Y_train, num_classes=10) #define models model = Sequential() model.add(Dense(input_dim=X_train.shape[1],output_dim=50,init='uniform',activation='tanh')) model.add(Dense(input_dim=50,output_dim=50,init='uniform',activation='tanh')) model.add(Dense(input_dim=50,output_dim=Y_train_ohe.shape[1],init='uniform',activation='softmax')) sgd = SGD(lr=0.001, decay=1e-7, momentum=0.9, nesterov=True) model.compile(loss='categorical_crossentropy', optimizer=sgd, metrics=["accuracy"]) #start training model.fit(X_train,Y_train_ohe,epochs=50,batch_size=300,shuffle=True,verbose=1,validation_split=0.3) #count accuracy y_train_pred = model.predict_classes(X_train, verbose=0) train_acc = np.sum(Y_train == y_train_pred, axis=0) / X_train.shape[0] print('Training accuracy: %.2f%%' % (train_acc * 100)) y_test_pred = model.predict_classes(X_test, verbose=0) test_acc = np.sum(Y_test == y_test_pred, axis=0) / X_test.shape[0] print('Test accuracy: %.2f%%' % (test_acc * 100))
训练结果如下:
Epoch 45/50 42000/42000 [==============================] - 1s 17us/step - loss: 0.2174 - acc: 0.9380 - val_loss: 0.2341 - val_acc: 0.9323 Epoch 46/50 42000/42000 [==============================] - 1s 17us/step - loss: 0.2061 - acc: 0.9404 - val_loss: 0.2244 - val_acc: 0.9358 Epoch 47/50 42000/42000 [==============================] - 1s 17us/step - loss: 0.1994 - acc: 0.9413 - val_loss: 0.2295 - val_acc: 0.9347 Epoch 48/50 42000/42000 [==============================] - 1s 17us/step - loss: 0.2003 - acc: 0.9413 - val_loss: 0.2224 - val_acc: 0.9350 Epoch 49/50 42000/42000 [==============================] - 1s 18us/step - loss: 0.2013 - acc: 0.9417 - val_loss: 0.2248 - val_acc: 0.9359 Epoch 50/50 42000/42000 [==============================] - 1s 17us/step - loss: 0.1960 - acc: 0.9433 - val_loss: 0.2300 - val_acc: 0.9346 Training accuracy: 94.11% Test accuracy: 93.61%
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