[实战]200类鸟类细粒度分类识别

我又来了！！！！

一、图像分类

这次进行实战项目，鸟类细粒度分类识别实战。再讲细粒度分类之前，让我们先回顾一下图像分类吧。

图像分类是计算机视觉的最基础的一个任务，从最开始的入门级的mnist手写数字识别、猫狗图像二分类到后来的imagenet任务。图像分类模型随着数据集的增长，一步步提升到了今天的水平。计算机的图像分类水准已经超过了人类。

在这里我把图像分类任务分为了两种，一种是单标签的图像分类任务，一种是多标签的图像分类任务。

多标签的图像分类任务，更加符合人们的认知习惯。因为现实生活中的图片往往会包含多个类别物体。

而在单标签的图像分类任务中又可以分为三类：一种是跨物种语义级别的图像分类，即在不同物种的层次上识别不同类别对象，比如我们常见的猫狗分类。
一种是实例级图像分类即区分不同的个体，最典型的任务那就是人脸识别。而还剩下最后一种就是细粒度分类，那么什么是细粒度分类呢？

二、图像细粒度分类

而细粒度图像分类，相比较我们前面所说的跨物种的图像分类，级别更低一些。但相比较实例级的图像分类，级别稍高一些。

概念上的说法是对同一大类中的子类的分类，
通俗来讲，其主要是解决我们在日常生活中可能看到一只狗，确分不清是哪种狗。

如下图所示，我们知道下图中哪一只是阿拉斯加哪一只是哈士奇，左边是哈士奇右边是阿拉斯加
这里可以当做可判别性部分是阿拉斯加犬的鼻梁是与黑色毛色是相连的，这就是discriminative part 即可判别性模块。

三、图像细粒度分类目前的挑战

然后再讲讲细粒度分类实验目前所遇到的挑战吧。

细粒度分类的挑战，但如今面临着如下三大问题：类内差异大、类间差异小，以及有限的数据集。

由于光线，物体的姿势，视角、遮挡、背景干扰等等问题，
类内差异大，像这里的黑脚信天翁，由于光照，背景，姿势的干扰，从肉眼上很难看出属于同一个子类

类间差异小不同个体归属于不同子类可能是由于一些微小的不同，如鸟的翅膀的颜色以及鸟喙颜色的不同

以及有限的数据集的问题，数据集的标注通常需要专业的知识以及耗费大量的标注时间。

由于上述挑战问题，我们很难根据现有的粗粒度神经网络模型得到精准的分类结果。

四、图像细粒度分类的研究现状

那么目前的研究现状是如何呢？

目前细粒度分类主要是通过寻找可判别性的特征来进行分类的，研究方法目前主要是可分为强监督学习和弱监督学习。

强监督学习是指通常使用边界框和局部标注信息，来获取目标的位置、大小，从而提高分类精度。即给出了图片标注中物体的某些显著特征，即discriminative。

而弱监督学习是指仅利用图像的类别标注信息，不使用额外的标注，

目前弱监督学习的主要思路是定位出判别性的部位，取得判别性的特征做辅助来分类。

其实这很符合人类辨别细粒度物体的流程，先看全局信息知道大类，然后根据经验把注意力放在一些关键部位来做出判断，而这些部位就是弱监督网络所要找的discriminative parts。

目前的强监督学习方法有part-based r-cnn基于r-cnn算法完成了局部区域的检测，利用约束条件对r-cnn提取到的区域信息进行修正之后提取卷积特征，并将不同区域的特征进行拼接，构成最好的特征表示，然后通过SVM分类器进行分类训练。 Posed-normalized Cnn对每一张图片进行位置检测，然后将检测框内的图像进行裁剪，从而提取不同层次、不同位置的图像，再对提取到的图像块进行姿态对其送入CNN，将得到的特征拼接后利用SVM分类器进行分类。 Multi-proposal Net通过Edge Box Crop方法获取图像块，并引入关键点及视觉特征的输出层，进一步强化了局部特征与全部信息直接的位置关联。

弱监督方法，有图像过滤，仅借助于图像的类别信息过滤图片中与物体无关的模块，其中最有代表性的是Two-level算法。two attention level利用物体级和局部级的信息，通过Search Selective算法过滤掉无关背景，然后将过滤掉的背景送入CNN网络进行训练，得到物体级的分类结果，随后通过聚类算法将不同位置的特征继续区分，并将不同区域的特征拼接后送入svm分类器进行训练。

人在认知物体和事物时，往往需要完成对其特征的理解及类别名称的记忆，B-CNN根据大脑工作时同认知类别和关注显著特征的方法，构建了两个线性网络，协调完成局部特征提取和分类的任务。

到这里，前期的基础知识差不多就完成了，下面准备进入正题。

五、200类鸟类细粒度图像分类实战

1.CUB200-2011数据集

首先还是一如既往先介绍我们的驱动力----数据。

不对，放错图了，应该是下面这张。

本次细粒度分类所采取的数据集CUB200-2011，该数据集是由加州理工学院在2010年提出的细粒度数据集，也是目前细粒度分类识别研究的基准图像数据集，该数据集共有117888张鸟类图像，包含了200类鸟类子类，其中训练数据集有5994张图像，测试集有5794张图像，每张图像均提供了图像类标注信息，图像中鸟的bounding box，鸟的关键part信息，以及鸟的属性信息。

评判标准就是以准确率了。

好了，准备上模型了！

2.VGG16模型

先用VGG16来投石问路

在此之前准备好我们的微调模型

# fine-tune 模型
def fine_tune_model(model, optimizer, batch_size, epochs, freeze_num):
    '''
    discription: 对指定预训练模型进行fine-tune，并保存为.hdf5格式
    
    MODEL：传入的模型，VGG16， ResNet50, ...

    optimizer: fine-tune all layers 的优化器, first part默认用adadelta
    batch_size: 每一批的尺寸，建议32/64/128
    epochs: fine-tune all layers的代数
    freeze_num: first part冻结卷积层的数量
    '''

    # datagen = ImageDataGenerator(
    #     rescale=1.255,
    #     # shear_range=0.2,
    #     # zoom_range=0.2,
    #     # horizontal_flip=True,
    #     # vertical_flip=True,
    #     # fill_mode="nearest"
    #   )
    
    # datagen.fit(X_train)
    
    
    # first: 仅训练全连接层（权重随机初始化的）
    # 冻结所有卷积层
    
    for layer in model.layers[:freeze_num]:
        layer.trainable = False
    
    model.compile(optimizer=optimizer, 
                  loss="categorical_crossentropy",
                  metrics=["accuracy"])

    # model.fit_generator(datagen.flow(x_train,y_train,batch_size=batch_size),
    #                     steps_per_epoch=len(x_train)/32,
    #                     epochs=3,
    #                     shuffle=True,
    #                     verbose=1,
    #                     datagen.flow(x_valid, y_valid))
    model.fit(x_train,
         y_train,
         batch_size=batch_size,
         epochs=3,
         shuffle=True,
         verbose=1,
         validation_data=(x_valid,y_valid)
        )
    print('Finish step_1')
    
    
    # second: fine-tune all layers
    for layer in model.layers[:]:
        layer.trainable = True
    
    rc = ReduceLROnPlateau(monitor="val_acc",
                factor=0.2,
                patience=4,
                verbose=1,
                mode='max')

    model_name = model.name  + ".hdf5"
    mc = ModelCheckpoint(model_name, 
               monitor="val_acc", 
               save_best_only=True,
               verbose=1,
               mode='max')
    el = EarlyStopping(monitor="val_acc",
              min_delta=0,
              patience=5,
              verbose=1,
              restore_best_weights=True)
    
    model.compile(optimizer=optimizer, 
           loss='categorical_crossentropy', 
           metrics=["accuracy"])

    # history_fit = model.fit_generator(datagen.flow(x_train,y_train,batch_size=32),
    #                                  steps_per_epoch=len(x_train)/32,
    #                                  epochs=epochs,
    #                                  shuffle=True,
    #                                  verbose=1,
    #                                  callbacks=[mc,rc,el],
    #                                  datagen.flow(x_valid, y_valid))
    history_fit = model.fit(x_train,
                 y_train,
                 batch_size=batch_size,
                 epochs=epochs,
                 shuffle=True,
                 verbose=1,
                 validation_data=(x_valid,y_valid),
                 callbacks=[mc,rc,el])
    
    print('Finish fine-tune')
    return history_fit

1.VGG16模型

# 定义一个VGG16的模型
def vgg16_model(img_rows,img_cols):
  x = Input(shape=(img_rows, img_cols, 3))
  x = Lambda(imagenet_utils.preprocess_input)(x)
  base_model = VGG16(input_tensor=x,weights="imagenet",include_top=False, pooling='avg')
  x = base_model.output
  x = Dense(1024,activation="relu",name="fc1")(x)
  x = Dropout(0.5)(x)
  predictions = Dense(n_classes,activation="softmax",name="predictions")(x)

  vgg16_model = Model(inputs=base_model.input,outputs=predictions,name="vgg16")
  
  return vgg16_model

# 创建VGG16模型
img_rows, img_cols = 300, 300
vgg16_model = vgg16_model(img_rows,img_cols)

for i,layer in enumerate(vgg16_model.layers):
  print(i,layer.name)

0 input_3
1 lambda_3
2 block1_conv1
3 block1_conv2
4 block1_pool
5 block2_conv1
6 block2_conv2
7 block2_pool
8 block3_conv1
9 block3_conv2
10 block3_conv3
11 block3_pool
12 block4_conv1
13 block4_conv2
14 block4_conv3
15 block4_pool
16 block5_conv1
17 block5_conv2
18 block5_conv3
19 block5_pool
20 global_average_pooling2d_3
21 fc1
22 dropout_3
23 predictions

optimizer = optimizers.Adam(lr=0.0001)
batch_size = 32
epochs = 30
freeze_num = 21


%time vgg16_history = fine_tune_model(vgg16_model,optimizer,batch_size,epochs,freeze_num)

WARNING:tensorflow:From /usr/local/lib/python3.6/dist-packages/keras/optimizers.py:790: The name tf.train.Optimizer is deprecated. Please use tf.compat.v1.train.Optimizer instead.    
Train on 7013 samples, validate on 3006 samples
Epoch 1/3
7013/7013 [==============================] - 53s 8ms/step - loss: 7.1095 - acc: 0.0211 - val_loss: 4.4823 - val_acc: 0.0915
Epoch 2/3
7013/7013 [==============================] - 46s 7ms/step - loss: 4.4798 - acc: 0.0914 - val_loss: 3.6892 - val_acc: 0.2239
Epoch 3/3
7013/7013 [==============================] - 46s 7ms/step - loss: 3.6436 - acc: 0.1925 - val_loss: 3.0040 - val_acc: 0.3440
Finish step_1
Train on 7013 samples, validate on 3006 samples
Epoch 1/30
7013/7013 [==============================] - 47s 7ms/step - loss: 2.9171 - acc: 0.3087 - val_loss: 2.1821 - val_acc: 0.4667

Epoch 00001: val_loss improved from inf to 2.18212, saving model to vgg16.hdf5
Epoch 2/30
7013/7013 [==============================] - 46s 7ms/step - loss: 1.9944 - acc: 0.4840 - val_loss: 1.8748 - val_acc: 0.5226

Epoch 00002: val_loss improved from 2.18212 to 1.87480, saving model to vgg16.hdf5
Epoch 3/30
7013/7013 [==============================] - 46s 7ms/step - loss: 1.6493 - acc: 0.5551 - val_loss: 1.7540 - val_acc: 0.5492

Epoch 00003: val_loss improved from 1.87480 to 1.75400, saving model to vgg16.hdf5
Epoch 4/30
7013/7013 [==============================] - 46s 7ms/step - loss: 1.4144 - acc: 0.6144 - val_loss: 1.6711 - val_acc: 0.5655

Epoch 00004: val_loss improved from 1.75400 to 1.67106, saving model to vgg16.hdf5
Epoch 5/30
7013/7013 [==============================] - 46s 7ms/step - loss: 1.2055 - acc: 0.6628 - val_loss: 1.6020 - val_acc: 0.5749

Epoch 00005: val_loss improved from 1.67106 to 1.60200, saving model to vgg16.hdf5


Epoch 00026: val_loss improved from 1.32242 to 1.32005, saving model to vgg16.hdf5
Epoch 27/30
7013/7013 [==============================] - 46s 7ms/step - loss: 0.1979 - acc: 0.9511 - val_loss: 1.3209 - val_acc: 0.6517

Epoch 00027: val_loss did not improve from 1.32005
Epoch 28/30
7013/7013 [==============================] - 46s 7ms/step - loss: 0.1996 - acc: 0.9528 - val_loss: 1.3206 - val_acc: 0.6514

Epoch 00028: val_loss did not improve from 1.32005
Epoch 29/30
7013/7013 [==============================] - 46s 7ms/step - loss: 0.1956 - acc: 0.9555 - val_loss: 1.3216 - val_acc: 0.6517

Epoch 00029: val_loss did not improve from 1.32005

Epoch 00029: ReduceLROnPlateau reducing learning rate to 3.999999898951501e-06.
Epoch 30/30
7013/7013 [==============================] - 46s 7ms/step - loss: 0.1884 - acc: 0.9558 - val_loss: 1.3194 - val_acc: 0.6514

Epoch 00030: val_loss improved from 1.32005 to 1.31935, saving model to vgg16.hdf5
Finish fine-tune
CPU times: user 10min, sys: 3min 58s, total: 13min 58s
Wall time: 25min 37s

history_plot(vgg16_history)

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进过上面的一系列操作，我们可以看到VGG16的分类效果，并不是很好呀，只能刚刚及格。

那么下面有请我们的二号选手EfficientNet

2.EfficientNetB4

咚咚咚，它来了，它来了，它踩着七彩祥云来了！！！

好了，不多说了，直接上代码来搭建EfficientNet网络架构。

# 定义一个EfficientNet模型
def efficient_model(img_rows,img_cols):
  K.clear_session()
  x = Input(shape=(img_rows,img_cols,3))
  x = Lambda(imagenet_utils.preprocess_input)(x)
  
  base_model = EfficientNetB4(input_tensor=x,weights="imagenet",include_top=False,pooling="avg")
  x = base_model.output
  x = Dense(1024,activation="relu",name="fc1")(x)
  x = Dropout(0.5)(x)
  predictions = Dense(n_classes,activation="softmax",name="predictions")(x)

  eB_model = Model(inputs=base_model.input,outputs=predictions,name="eB4")

  return eB_model

# 创建Efficient模型
img_rows,img_cols=224,224
eB_model = efficient_model(img_rows,img_cols)

optimizer = optimizers.Adam(lr=0.0001)
batch_size = 32
epochs = 30
freeze_num = 469
eB_model_history  = fine_tune_model(eB_model,optimizer,batch_size,epochs,freeze_num)

Train on 8251 samples, validate on 1768 samples
Epoch 1/3
8251/8251 [==============================] - 49s 6ms/step - loss: 9.3405 - acc: 0.0053 - val_loss: 5.5664 - val_acc: 0.0051
Epoch 2/3
8251/8251 [==============================] - 38s 5ms/step - loss: 6.8968 - acc: 0.0052 - val_loss: 5.3289 - val_acc: 0.0040
Epoch 3/3
8251/8251 [==============================] - 39s 5ms/step - loss: 5.8723 - acc: 0.0061 - val_loss: 5.3021 - val_acc: 0.0040
Finish step_1
Train on 8251 samples, validate on 1768 samples
Epoch 1/30
8251/8251 [==============================] - 261s 32ms/step - loss: 4.4794 - acc: 0.0980 - val_loss: 2.7448 - val_acc: 0.3399

Epoch 00001: val_loss improved from inf to 2.74482, saving model to eB4.hdf5
Epoch 2/30
8251/8251 [==============================] - 155s 19ms/step - loss: 2.2635 - acc: 0.4157 - val_loss: 1.4371 - val_acc: 0.5973

Epoch 00002: val_loss improved from 2.74482 to 1.43707, saving model to eB4.hdf5
Epoch 3/30
8251/8251 [==============================] - 155s 19ms/step - loss: 1.3465 - acc: 0.6244 - val_loss: 1.1637 - val_acc: 0.6719

Epoch 00003: val_loss improved from 1.43707 to 1.16373, saving model to eB4.hdf5
Epoch 4/30
8251/8251 [==============================] - 154s 19ms/step - loss: 0.8824 - acc: 0.7488 - val_loss: 0.9904 - val_acc: 0.7110


Epoch 00016: val_loss did not improve from 0.89365
Epoch 17/30
8251/8251 [==============================] - 154s 19ms/step - loss: 0.0718 - acc: 0.9867 - val_loss: 0.8993 - val_acc: 0.7749

Epoch 00017: val_loss did not improve from 0.89365
Restoring model weights from the end of the best epoch
Epoch 00017: early stopping
Finish fine-tune

history_plot(eB_model_history)

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效果很不错呀，EfficientNet不愧是谷歌出品的，必是精品。那么既然EfficientNet的效果已经这么好了，你是不是就不想接着看了，你是不是已经迫不及待想尝试EfficientNet的效果了呢。

不要急，下面还有几个小尝试，首先是在EfficientNet中加入Attention机制，至于Attention机制的话，可以去看我的博客里面有写到，那是在我未解放天性之前，写的可正经了。当然这里更是正经！！！

3.efficientnet-with-attention

# 定义一个加入Attention模块的Efficient网络架构即efficientnet-with-attention

def efficient_attention_model(img_rows,img_cols):
  K.clear_session()
  
  in_lay = Input(shape=(img_rows,img_cols,3))
  base_model = EfficientNetB3(input_shape=(img_rows,img_cols,3),weights="imagenet",include_top=False)

  pt_depth = base_model.get_output_shape_at(0)[-1]

  pt_features = base_model(in_lay)
  bn_features = BatchNormalization()(pt_features)

  # here we do an attention mechanism to turn pixels in the GAP on an off
  atten_layer = Conv2D(64,kernel_size=(1,1),padding="same",activation="relu")(Dropout(0.5)(bn_features))
  atten_layer = Conv2D(16,kernel_size=(1,1),padding="same",activation="relu")(atten_layer)
  atten_layer = Conv2D(8,kernel_size=(1,1),padding="same",activation="relu")(atten_layer)
  atten_layer = Conv2D(1,kernel_size=(1,1),padding="valid",activation="sigmoid")(atten_layer)# H,W,1
  # fan it out to all of the channels
  up_c2_w = np.ones((1,1,1,pt_depth)) #1,1,C
  up_c2 = Conv2D(pt_depth,kernel_size=(1,1),padding="same",activation="linear",use_bias=False,weights=[up_c2_w])
  up_c2.trainable = False
  atten_layer = up_c2(atten_layer)# H,W,C

  mask_features = multiply([atten_layer,bn_features])# H,W,C

  gap_features = GlobalAveragePooling2D()(mask_features)# 1,1,C
  # gap_mask = GlobalAveragePooling2D()(atten_layer)# 1,1,C

  # # to account for missing values from the attention model
  # gap = Lambda(lambda x:x[0]/x[1],name="RescaleGAP")([gap_features,gap_mask])
  gap_dr = Dropout(0.25)(gap_features)
  dr_steps = Dropout(0.25)(Dense(1000,activation="relu")(gap_dr))
  out_layer = Dense(200,activation="softmax")(dr_steps)
  eb_atten_model = Model(inputs=[in_lay],outputs=[out_layer])

  return eb_atten_model

img_rows,img_cols = 224,224
eB_atten_model = efficient_attention_model(img_rows,img_cols)

eB_atten_model.save("eb_atten_model.h5")

for i,layer in enumerate(eB_atten_model.layers):
  print(i,layer.name)

0 input_1
1 efficientnet-b3
2 batch_normalization_1
3 dropout_1
4 conv2d_1
5 conv2d_2
6 conv2d_3
7 conv2d_4
8 conv2d_5
9 multiply_1
10 global_average_pooling2d_1
11 dropout_2
12 dense_1
13 dropout_3
14 dense_2

optimizer = optimizers.Adam(lr=0.0001)
batch_size = 32
epochs = 30
freeze_num = 12
eB_atten_model_history  = fine_tune_model(eB_atten_model,optimizer,batch_size,epochs,freeze_num)

WARNING:tensorflow:From /usr/local/lib/python3.6/dist-packages/keras/optimizers.py:793: The name tf.train.Optimizer is deprecated. Please use tf.compat.v1.train.Optimizer instead.



Train on 8251 samples, validate on 1768 samples
Epoch 1/3
8251/8251 [==============================] - 39s 5ms/step - loss: 5.2083 - acc: 0.0221 - val_loss: 16.0324 - val_acc: 0.0040
Epoch 2/3
8251/8251 [==============================] - 28s 3ms/step - loss: 4.7719 - acc: 0.1130 - val_loss: 16.0147 - val_acc: 0.0057
Epoch 3/3
8251/8251 [==============================] - 28s 3ms/step - loss: 4.3135 - acc: 0.2112 - val_loss: 16.0056 - val_acc: 0.0062
Finish step_1
Train on 8251 samples, validate on 1768 samples
Epoch 1/30
8251/8251 [==============================] - 168s 20ms/step - loss: 2.1612 - acc: 0.4549 - val_loss: 1.1888 - val_acc: 0.6725

Epoch 00001: val_loss improved from inf to 1.18880, saving model to model_1.hdf5
Epoch 2/30
8251/8251 [==============================] - 121s 15ms/step - loss: 0.9003 - acc: 0.7442 - val_loss: 0.9400 - val_acc: 0.7330

Epoch 00002: val_loss improved from 1.18880 to 0.94002, saving model to model_1.hdf5
Epoch 3/30
8251/8251 [==============================] - 121s 15ms/step - loss: 0.5455 - acc: 0.8467 - val_loss: 0.8569 - val_acc: 0.7574


Epoch 00013: val_loss did not improve from 0.78748
Epoch 14/30
8251/8251 [==============================] - 121s 15ms/step - loss: 0.0417 - acc: 0.9924 - val_loss: 0.7958 - val_acc: 0.7924

Epoch 00014: val_loss did not improve from 0.78748

Epoch 00014: ReduceLROnPlateau reducing learning rate to 3.999999898951501e-06.
Epoch 15/30
8251/8251 [==============================] - 121s 15ms/step - loss: 0.0370 - acc: 0.9936 - val_loss: 0.7938 - val_acc: 0.7941

Epoch 00015: val_loss did not improve from 0.78748
Epoch 16/30
8251/8251 [==============================] - 121s 15ms/step - loss: 0.0379 - acc: 0.9933 - val_loss: 0.7932 - val_acc: 0.7952

Epoch 00016: val_loss did not improve from 0.78748
Restoring model weights from the end of the best epoch
Epoch 00016: early stopping
Finish fine-tune

history_plot(eB_atten_model_history)

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效果还是提升了一点点的，下面是又尝试了另外一种attention的写法，用到senet和cbam。当然如果你不了解的话，还是老规矩，去看我的博客，卷积神经网络发展史里面有提到。

4.EfficientNetB3 with attention v2

from keras.layers import GlobalAveragePooling2D, GlobalMaxPooling2D, Reshape, Dense, multiply, Permute, Concatenate, Conv2D, Add, Activation, Lambda
from keras import backend as K
from keras.activations import sigmoid

def attach_attention_module(net, attention_module):
  if attention_module == 'se_block': # SE_block
    net = se_block(net)
  elif attention_module == 'cbam_block': # CBAM_block
    net = cbam_block(net)
  else:
    raise Exception("'{}' is not supported attention module!".format(attention_module))

  return net

def se_block(input_feature, ratio=8):
	"""Contains the implementation of Squeeze-and-Excitation(SE) block.
	As described in https://arxiv.org/abs/1709.01507.
	"""
	
	channel_axis = 1 if K.image_data_format() == "channels_first" else -1
	channel = input_feature._keras_shape[channel_axis]

	se_feature = GlobalAveragePooling2D()(input_feature)
	se_feature = Reshape((1, 1, channel))(se_feature)
	assert se_feature._keras_shape[1:] == (1,1,channel)
	se_feature = Dense(channel // ratio,
					   activation='relu',
					   kernel_initializer='he_normal',
					   use_bias=True,
					   bias_initializer='zeros')(se_feature)
	assert se_feature._keras_shape[1:] == (1,1,channel//ratio)
	se_feature = Dense(channel,
					   activation='sigmoid',
					   kernel_initializer='he_normal',
					   use_bias=True,
					   bias_initializer='zeros')(se_feature)
	assert se_feature._keras_shape[1:] == (1,1,channel)
	if K.image_data_format() == 'channels_first':
		se_feature = Permute((3, 1, 2))(se_feature)

	se_feature = multiply([input_feature, se_feature])
	return se_feature

def cbam_block(cbam_feature, ratio=8):
	"""Contains the implementation of Convolutional Block Attention Module(CBAM) block.
	As described in https://arxiv.org/abs/1807.06521.
	"""
	
	cbam_feature = channel_attention(cbam_feature, ratio)
	cbam_feature = spatial_attention(cbam_feature)
	return cbam_feature

def channel_attention(input_feature, ratio=8):
	
	channel_axis = 1 if K.image_data_format() == "channels_first" else -1
	channel = input_feature._keras_shape[channel_axis]
	
	shared_layer_one = Dense(channel//ratio,
							 activation='relu',
							 kernel_initializer='he_normal',
							 use_bias=True,
							 bias_initializer='zeros')
	shared_layer_two = Dense(channel,
							 kernel_initializer='he_normal',
							 use_bias=True,
							 bias_initializer='zeros')
	
	avg_pool = GlobalAveragePooling2D()(input_feature)    
	avg_pool = Reshape((1,1,channel))(avg_pool)
	assert avg_pool._keras_shape[1:] == (1,1,channel)
	avg_pool = shared_layer_one(avg_pool)
	assert avg_pool._keras_shape[1:] == (1,1,channel//ratio)
	avg_pool = shared_layer_two(avg_pool)
	assert avg_pool._keras_shape[1:] == (1,1,channel)
	
	max_pool = GlobalMaxPooling2D()(input_feature)
	max_pool = Reshape((1,1,channel))(max_pool)
	assert max_pool._keras_shape[1:] == (1,1,channel)
	max_pool = shared_layer_one(max_pool)
	assert max_pool._keras_shape[1:] == (1,1,channel//ratio)
	max_pool = shared_layer_two(max_pool)
	assert max_pool._keras_shape[1:] == (1,1,channel)
	
	cbam_feature = Add()([avg_pool,max_pool])
	cbam_feature = Activation('sigmoid')(cbam_feature)
	
	if K.image_data_format() == "channels_first":
		cbam_feature = Permute((3, 1, 2))(cbam_feature)
	
	return multiply([input_feature, cbam_feature])

def spatial_attention(input_feature):
	kernel_size = 7
	
	if K.image_data_format() == "channels_first":
		channel = input_feature._keras_shape[1]
		cbam_feature = Permute((2,3,1))(input_feature)
	else:
		channel = input_feature._keras_shape[-1]
		cbam_feature = input_feature
	
	avg_pool = Lambda(lambda x: K.mean(x, axis=3, keepdims=True))(cbam_feature)
	assert avg_pool._keras_shape[-1] == 1
	max_pool = Lambda(lambda x: K.max(x, axis=3, keepdims=True))(cbam_feature)
	assert max_pool._keras_shape[-1] == 1
	concat = Concatenate(axis=3)([avg_pool, max_pool])
	assert concat._keras_shape[-1] == 2
	cbam_feature = Conv2D(filters = 1,
					kernel_size=kernel_size,
					strides=1,
					padding='same',
					activation='sigmoid',
					kernel_initializer='he_normal',
					use_bias=False)(concat)	
	assert cbam_feature._keras_shape[-1] == 1
	
	if K.image_data_format() == "channels_first":
		cbam_feature = Permute((3, 1, 2))(cbam_feature)
		
	return multiply([input_feature, cbam_feature])

# 定义一个EfficientNet模型
def efficient__atten2_model(img_rows,img_cols):
  K.clear_session()
  
  in_lay = Input(shape=(img_rows,img_cols,3))
  base_model = EfficientNetB3(input_shape=(img_rows,img_cols,3),weights="imagenet",include_top=False)
  pt_features = base_model(in_lay)
  bn_features = BatchNormalization()(pt_features)

  atten_features = attach_attention_module(bn_features,"se_block")
  gap_features = GlobalAveragePooling2D()(atten_features)

  gap_dr = Dropout(0.25)(gap_features)
  dr_steps = Dropout(0.25)(Dense(1000,activation="relu")(gap_dr))
  out_layer = Dense(n_classes,activation="softmax")(dr_steps)
  eb_atten_model = Model(inputs=[in_lay],outputs=[out_layer])

  return eb_atten_model

img_rows,img_cols = 224,224
eB_atten2_model = efficient__atten2_model(img_rows,img_cols)

optimizer = optimizers.Adam(lr=0.0001)
batch_size = 32
epochs = 30
freeze_num = 19
eB_atten2_model_history  = fine_tune_model(eB_atten2_model,optimizer,batch_size,epochs,freeze_num)

Train on 8251 samples, validate on 1768 samples
Epoch 1/3
8251/8251 [==============================] - 33s 4ms/step - loss: 5.3202 - acc: 0.0061 - val_loss: 16.0269 - val_acc: 0.0057
Epoch 2/3
8251/8251 [==============================] - 26s 3ms/step - loss: 5.3261 - acc: 0.0051 - val_loss: 16.0269 - val_acc: 0.0057
Epoch 3/3
8251/8251 [==============================] - 26s 3ms/step - loss: 5.3248 - acc: 0.0048 - val_loss: 16.0269 - val_acc: 0.0057
Finish step_1
Train on 8251 samples, validate on 1768 samples
Epoch 1/30
8251/8251 [==============================] - 153s 19ms/step - loss: 3.9559 - acc: 0.1742 - val_loss: 2.1066 - val_acc: 0.4712

Epoch 00001: val_loss improved from inf to 2.10657, saving model to model_1.hdf5
Epoch 2/30
8251/8251 [==============================] - 119s 14ms/step - loss: 1.6183 - acc: 0.5708 - val_loss: 1.1768 - val_acc: 0.6618

Epoch 00002: val_loss improved from 2.10657 to 1.17679, saving model to model_1.hdf5
Epoch 3/30
8251/8251 [==============================] - 119s 14ms/step - loss: 0.9172 - acc: 0.7374 - val_loss: 0.9507 - val_acc: 0.7189

Epoch 00003: val_loss improved from 1.17679 to 0.95071, saving model to model_1.hdf5
Epoch 4/30
8251/8251 [==============================] - 119s 14ms/step - loss: 0.5897 - acc: 0.8317 - val_loss: 0.8628 - val_acc: 0.7562

Epoch 00004: val_loss improved from 0.95071 to 0.86283, saving model to model_1.hdf5
Epoch 5/30
8251/8251 [==============================] - 119s 14ms/step - loss: 0.3838 - acc: 0.8956 - val_loss: 0.8359 - val_acc: 0.7636

Epoch 00005: val_loss improved from 0.86283 to 0.83592, saving model to model_1.hdf5
Epoch 6/30
8251/8251 [==============================] - 119s 14ms/step - loss: 0.2797 - acc: 0.9234 - val_loss: 0.8280 - val_acc: 0.7647

Epoch 00006: val_loss improved from 0.83592 to 0.82797, saving model to model_1.hdf5
Epoch 7/30
8251/8251 [==============================] - 119s 14ms/step - loss: 0.1997 - acc: 0.9495 - val_loss: 0.8620 - val_acc: 0.7602

Epoch 00007: val_loss did not improve from 0.82797
Epoch 8/30
8251/8251 [==============================] - 119s 14ms/step - loss: 0.1408 - acc: 0.9667 - val_loss: 0.8602 - val_acc: 0.7800

Epoch 00008: val_loss did not improve from 0.82797
Epoch 9/30
8251/8251 [==============================] - 119s 14ms/step - loss: 0.1103 - acc: 0.9739 - val_loss: 0.9202 - val_acc: 0.7545

Epoch 00009: val_loss did not improve from 0.82797

Epoch 00009: ReduceLROnPlateau reducing learning rate to 1.9999999494757503e-05.
Epoch 10/30
8251/8251 [==============================] - 119s 14ms/step - loss: 0.0803 - acc: 0.9824 - val_loss: 0.8677 - val_acc: 0.7709

Epoch 00010: val_loss did not improve from 0.82797
Epoch 11/30
8251/8251 [==============================] - 119s 14ms/step - loss: 0.0772 - acc: 0.9833 - val_loss: 0.8560 - val_acc: 0.7771

Epoch 00011: val_loss did not improve from 0.82797
Restoring model weights from the end of the best epoch
Epoch 00011: early stopping
Finish fine-tune

history_plot(eB_atten2_model_history)

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咱也不知道为什么，这个效果比上面那个attention的写法，会提升一点点，这就是炼丹吧。

5.双线性EfficientNet

下面就是尝试了一种双线性的网络架构，这里我还画了图呢！！！

该模型的整体流程是：

将图片输入,并对输入图片进行数据增强操作；
之后主干网络用19年google提出的efficientnet架构来提取feature maps；
之后再结合注意力模块，提取attention maps。
然后将attention maps与feature maps逐一相乘，最后在加入全连接层进行分类，从而得到最终的分类结果。

这里也一并给出attention机制的图吧！

# 定义一个双线性EfficientNet Attention模型
def blinear_efficient__atten_model(img_rows,img_cols):
  K.clear_session()
  
  in_lay = Input(shape=(img_rows,img_cols,3))
  base_model = EfficientNetB3(input_shape=(img_rows,img_cols,3),weights="imagenet",include_top=False)
  
  pt_depth = base_model.get_output_shape_at(0)[-1]

  cnn_features_a = base_model(in_lay)
  cnn_bn_features_a = BatchNormalization()(cnn_features_a)
  
  # attention mechanism
  # here we do an attention mechanism to turn pixels in the GAP on an off
  atten_layer = Conv2D(64,kernel_size=(1,1),padding="same",activation="relu")(Dropout(0.5)(cnn_bn_features_a))
  atten_layer = Conv2D(16,kernel_size=(1,1),padding="same",activation="relu")(atten_layer)
  atten_layer = Conv2D(8,kernel_size=(1,1),padding="same",activation="relu")(atten_layer)
  atten_layer = Conv2D(1,kernel_size=(1,1),padding="valid",activation="sigmoid")(atten_layer)# H,W,1
  # fan it out to all of the channels
  up_c2_w = np.ones((1,1,1,pt_depth)) #1,1,C
  up_c2 = Conv2D(pt_depth,kernel_size=(1,1),padding="same",activation="linear",use_bias=False,weights=[up_c2_w])
  up_c2.trainable = True
  atten_layer = up_c2(atten_layer)# H,W,C

  cnn_atten_out_a = multiply([atten_layer,cnn_bn_features_a])# H,W,C

  cnn_atten_out_b = cnn_atten_out_a

  cnn_out_dot = multiply([cnn_atten_out_a,cnn_atten_out_b])
  gap_features = GlobalAveragePooling2D()(cnn_out_dot)
  gap_dr = Dropout(0.25)(gap_features)
  dr_steps = Dropout(0.25)(Dense(1000,activation="relu")(gap_dr))
  out_layer = Dense(200,activation="softmax")(dr_steps)
  
  b_eff_atten_model = Model(inputs=[in_lay],outputs=[out_layer],name="blinear_efficient_atten")

  return b_eff_atten_model

# 创建双线性EfficientNet Attention模型
img_rows,img_cols = 256,256
befficient_model = blinear_efficient__atten_model(img_rows,img_cols)

befficient_model.save("befficient_model.h5")

optimizer = optimizers.Adam(lr=0.0001)
batch_size = 32
epochs = 30
freeze_num = 19
befficient_model_history  = fine_tune_model(befficient_model,optimizer,batch_size,epochs,freeze_num)

Train on 8251 samples, validate on 1768 samples
Epoch 1/3
8251/8251 [==============================] - 38s 5ms/step - loss: 5.3903 - acc: 0.0052 - val_loss: 14.1897 - val_acc: 0.0040
Epoch 2/3
8251/8251 [==============================] - 33s 4ms/step - loss: 5.3926 - acc: 0.0052 - val_loss: 14.1897 - val_acc: 0.0040
Epoch 3/3
8251/8251 [==============================] - 33s 4ms/step - loss: 5.3948 - acc: 0.0068 - val_loss: 14.1897 - val_acc: 0.0040
Finish step_1
Train on 8251 samples, validate on 1768 samples
Epoch 1/30
8251/8251 [==============================] - 193s 23ms/step - loss: 4.7127 - acc: 0.0749 - val_loss: 2.9079 - val_acc: 0.3060

Epoch 00001: val_acc improved from -inf to 0.30600, saving model to blinear_efficient_atten.hdf5
Epoch 2/30
8251/8251 [==============================] - 148s 18ms/step - loss: 2.1653 - acc: 0.4462 - val_loss: 1.3817 - val_acc: 0.6160

Epoch 00002: val_acc improved from 0.30600 to 0.61595, saving model to blinear_efficient_atten.hdf5
Epoch 3/30
8251/8251 [==============================] - 149s 18ms/step - loss: 1.1834 - acc: 0.6676 - val_loss: 1.0714 - val_acc: 0.7002

Epoch 00003: val_acc improved from 0.61595 to 0.70023, saving model to blinear_efficient_atten.hdf5
Epoch 4/30
8251/8251 [==============================] - 149s 18ms/step - loss: 0.8070 - acc: 0.7666 - val_loss: 0.9743 - val_acc: 0.7342

Epoch 00004: val_acc improved from 0.70023 to 0.73416, saving model to blinear_efficient_atten.hdf5
Epoch 5/30


Epoch 00007: val_acc improved from 0.74830 to 0.75735, saving model to blinear_efficient_atten.hdf5

Epoch 00010: val_acc did not improve from 0.76867
Epoch 11/30
8251/8251 [==============================] - 149s 18ms/step - loss: 0.1421 - acc: 0.9547 - val_loss: 1.1319 - val_acc: 0.7692

Epoch 00011: val_acc improved from 0.76867 to 0.76923, saving model to blinear_efficient_atten.hdf5
Epoch 12/30
8251/8251 [==============================] - 149s 18ms/step - loss: 0.1232 - acc: 0.9622 - val_loss: 1.0809 - val_acc: 0.7704



Epoch 00018: val_acc improved from 0.77489 to 0.78224, saving model to blinear_efficient_atten.hdf5
Epoch 19/30
8251/8251 [==============================] - 149s 18ms/step - loss: 0.0880 - acc: 0.9714 - val_loss: 1.2171 - val_acc: 0.7721



Epoch 00022: ReduceLROnPlateau reducing learning rate to 1.9999999494757503e-05.
Epoch 23/30
8251/8251 [==============================] - 148s 18ms/step - loss: 0.0465 - acc: 0.9859 - val_loss: 1.1591 - val_acc: 0.7930

Epoch 00023: val_acc improved from 0.78224 to 0.79299, saving model to blinear_efficient_atten.hdf5
Epoch 24/30
8251/8251 [==============================] - 148s 18ms/step - loss: 0.0360 - acc: 0.9893 - val_loss: 1.1312 - val_acc: 0.7969

Epoch 00024: val_acc improved from 0.79299 to 0.79695, saving model to blinear_efficient_atten.hdf5
Epoch 25/30
8251/8251 [==============================] - 148s 18ms/step - loss: 0.0275 - acc: 0.9920 - val_loss: 1.1477 - val_acc: 0.8015



Epoch 00028: val_acc did not improve from 0.80147
Epoch 29/30
8251/8251 [==============================] - 148s 18ms/step - loss: 0.0248 - acc: 0.9922 - val_loss: 1.1467 - val_acc: 0.8020

Epoch 00029: val_acc improved from 0.80147 to 0.80204, saving model to blinear_efficient_atten.hdf5
Epoch 30/30
8251/8251 [==============================] - 148s 18ms/step - loss: 0.0232 - acc: 0.9919 - val_loss: 1.1427 - val_acc: 0.8003

Epoch 00030: val_acc did not improve from 0.80204
Finish fine-tune

history_plot(befficient_model_history)

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可以从图中看到，双线性的结构，准确率还会提升一些。

终于来到故事的结尾处了，最后在尝试一些双线性的VGG16。

6.双线性VGG16模型

# 定义双线性VGG16模型

from keras import backend as K

def batch_dot(cnn_ab):
    return K.batch_dot(cnn_ab[0], cnn_ab[1], axes=[1, 1])

def sign_sqrt(x):
    return K.sign(x) * K.sqrt(K.abs(x) + 1e-10)

def l2_norm(x):
    return K.l2_normalize(x, axis=-1)
 
 
def bilinear_vgg16(img_rows,img_cols):
    input_tensor = Input(shape=(img_rows,img_cols,3))
    input_tensor = Lambda(imagenet_utils.preprocess_input)(input_tensor)

    model_vgg16 = VGG16(include_top=False, weights="imagenet",
                        input_tensor=input_tensor,pooling="avg")
    
    cnn_out_a = model_vgg16.layers[-2].output
    cnn_out_shape = model_vgg16.layers[-2].output_shape
    cnn_out_a = Reshape([cnn_out_shape[1]*cnn_out_shape[2],
                         cnn_out_shape[-1]])(cnn_out_a)

    cnn_out_b = cnn_out_a

    cnn_out_dot = Lambda(batch_dot)([cnn_out_a, cnn_out_b])
    cnn_out_dot = Reshape([cnn_out_shape[-1]*cnn_out_shape[-1]])(cnn_out_dot)
 
    sign_sqrt_out = Lambda(sign_sqrt)(cnn_out_dot)
    l2_norm_out = Lambda(l2_norm)(sign_sqrt_out)
    
    fc1 = Dense(1024,activation="relu",name="fc1")(l2_norm_out)
    dropout = Dropout(0.5)(fc1)
    output = Dense(n_classes, activation="softmax",name="output")(dropout)
    bvgg16_model = Model(inputs=model_vgg16.input, outputs=output,name="bvgg16")

    return bvgg16_model

# 创建双线性VGG16模型
img_rows,img_cols = 300,300
bvgg16_model = bilinear_vgg16(img_rows,img_cols)

for i,layer in enumerate(bvgg16_model.layers):
  print(i,layer.name)

0 input_1
1 lambda_1
2 block1_conv1
3 block1_conv2
4 block1_pool
5 block2_conv1
6 block2_conv2
7 block2_pool
8 block3_conv1
9 block3_conv2
10 block3_conv3
11 block3_pool
12 block4_conv1
13 block4_conv2
14 block4_conv3
15 block4_pool
16 block5_conv1
17 block5_conv2
18 block5_conv3
19 block5_pool
20 reshape_1
21 lambda_2
22 reshape_2
23 lambda_3
24 lambda_4
25 fc1
26 dropout_1
27 output

optimizer = optimizers.Adam(lr=0.0001)
batch_size = 32
epochs = 100
freeze_num = 25
bvgg16_history = fine_tune_model(bvgg16_model,optimizer,batch_size,epochs,freeze_num)

WARNING:tensorflow:From /usr/local/lib/python3.6/dist-packages/keras/optimizers.py:793: The name tf.train.Optimizer is deprecated. Please use tf.compat.v1.train.Optimizer instead.



Train on 8251 samples, validate on 1768 samples
Epoch 1/3
8251/8251 [==============================] - 80s 10ms/step - loss: 5.1197 - acc: 0.0572 - val_loss: 4.8534 - val_acc: 0.2002
Epoch 2/3
8251/8251 [==============================] - 71s 9ms/step - loss: 4.4758 - acc: 0.1863 - val_loss: 4.1177 - val_acc: 0.3569
Epoch 3/3
8251/8251 [==============================] - 71s 9ms/step - loss: 3.7386 - acc: 0.2743 - val_loss: 3.4439 - val_acc: 0.4378
Finish step_1
Train on 8251 samples, validate on 1768 samples
Epoch 1/100
8251/8251 [==============================] - 76s 9ms/step - loss: 2.9186 - acc: 0.3475 - val_loss: 2.5064 - val_acc: 0.5334

Epoch 00001: val_loss improved from inf to 2.50638, saving model to bvgg16.hdf5
Epoch 2/100
8251/8251 [==============================] - 70s 9ms/step - loss: 2.3073 - acc: 0.4696 - val_loss: 2.1717 - val_acc: 0.5888

Epoch 00002: val_loss improved from 2.50638 to 2.17170, saving model to bvgg16.hdf5
Epoch 3/100
8251/8251 [==============================] - 70s 9ms/step - loss: 2.0086 - acc: 0.5355 - val_loss: 1.9604 - val_acc: 0.6222


Epoch 00067: val_loss did not improve from 0.89483
Epoch 68/100
8251/8251 [==============================] - 71s 9ms/step - loss: 0.0539 - acc: 0.9971 - val_loss: 0.8984 - val_acc: 0.7590

Epoch 00068: val_loss did not improve from 0.89483

Epoch 00068: ReduceLROnPlateau reducing learning rate to 3.999999898951501e-06.
Epoch 69/100
8251/8251 [==============================] - 71s 9ms/step - loss: 0.0536 - acc: 0.9972 - val_loss: 0.8972 - val_acc: 0.7602

Epoch 00069: val_loss did not improve from 0.89483
Epoch 70/100
8251/8251 [==============================] - 71s 9ms/step - loss: 0.0517 - acc: 0.9973 - val_loss: 0.8968 - val_acc: 0.7630

Epoch 00070: val_loss did not improve from 0.89483
Restoring model weights from the end of the best epoch
Epoch 00070: early stopping
Finish fine-tune