def inference(input_shape, N_CLASSES): '''build the model args: image: image batch, 4D tensor [batch_size, width, height, channels=3], dtype=tf.float32 return: output tensor with the computed logits, float, [batch_size, n_classes] ''' inputs = Input(shape=input_shape) K.set_learning_phase( False) # all new operations will be in test mode from now on ## Conv layer 1 x = dn_layer(inputs=inputs, name='layer1') x = MaxPooling2D((2, 2), strides=(2, 2), name='layer1_maxpool')(x) ## Conv layer 2 x = dn_layer(inputs=x, num_filters=32, name='layer2') x = MaxPooling2D((2, 2), strides=(2, 2), name='layer2_maxpool')(x) ## Conv layer 3 x = dn_layer(inputs=x, num_filters=64, name='layer3') x = MaxPooling2D((2, 2), strides=(2, 2), name='layer3_maxpool')(x) x = GlobalAveragePooling2D(name='GlobalAveragePooling2D')(x) #x = Flatten(name='flatten')(x) x = Dense(N_CLASSES, activation='softmax', name='predictions')(x) model = Model(inputs=inputs, outputs=x) return model
def Squeeze_excitation_layer(input_x): ratio = 4 out_dim = int(np.shape(input_x)[-1]) squeeze = GlobalAveragePooling2D()(input_x) excitation = Dense(units=int(out_dim / ratio))(squeeze) excitation = Activation('relu')(excitation) excitation = Dense(units=out_dim)(excitation) excitation = Activation('sigmoid')(excitation) excitation = layers.Reshape([-1, 1, out_dim])(excitation) scale = layers.multiply([input_x, excitation]) return scale
def build(self,alpha, img_input, temp_softmax): shape = (1, 1, int(1024 * alpha)) """ This looks dangerous. Not sure how the model would get affected with the laarning_phase variable set to True. """ K.set_learning_phase(True) with tf.name_scope('teacher') as scope: self.conv1 = Conv2D( int(32*alpha), (3,3), padding='same', use_bias=False, strides=(1,1), name='teacher_conv1', trainable=self.trainable)(img_input) self.conv2 = BatchNormalization(axis=-1, name='teacher_conv1_bn', trainable=self.trainable)(self.conv1) self.conv3 = Activation(self.relu6, name='teacher_conv1_relu', trainable=self.trainable)(self.conv2) self.conv4 = self._depthwise_conv_block(self.conv3, 64, alpha, depth_multiplier, block_id = 15) self.conv5 = self._depthwise_conv_block(self.conv4, 128, alpha, depth_multiplier,strides=(2, 2), block_id =16) self.conv6 =self. _depthwise_conv_block(self.conv5, 128, alpha, depth_multiplier,block_id =17) self.conv7 = self._depthwise_conv_block(self.conv6, 256, alpha, depth_multiplier, strides=(2,2),block_id =18) self.conv8 = self._depthwise_conv_block(self.conv7, 256, alpha, depth_multiplier, block_id =19) self.conv9 = self._depthwise_conv_block(self.conv8, 512, alpha, depth_multiplier, strides = (2,2), block_id =20) self.conv10 = self._depthwise_conv_block(self.conv9, 512, alpha, depth_multiplier, block_id =21) self.conv11 = self._depthwise_conv_block(self.conv10, 512, alpha, depth_multiplier, block_id =22) self.conv12 = self._depthwise_conv_block(self.conv11, 512, alpha, depth_multiplier, block_id =23) self.conv13 = self._depthwise_conv_block(self.conv12, 512, alpha, depth_multiplier, block_id =24) self.conv14 = self._depthwise_conv_block(self.conv13, 512, alpha, depth_multiplier, block_id =25) self.conv15 = self._depthwise_conv_block(self.conv14, 1024, alpha, depth_multiplier,strides=(2,2), block_id =26) self.conv16 = self._depthwise_conv_block(self.conv15, 1024, alpha, depth_multiplier, block_id =27) self.conv17 = GlobalAveragePooling2D()(self.conv16) self.conv18 = Reshape(shape, name='teacher_reshape_1', trainable=self.trainable)(self.conv17) self.conv19 = Dropout(0.5, name='teacher_dropout', trainable=self.trainable)(self.conv18) self.conv20 = Conv2D(self.num_classes, (1, 1), padding='same', name='teacher_conv_preds', trainable=self.trainable)(self.conv18) self.conv21 = Activation('softmax', name='teacher_act_softmax', trainable=self.trainable)(tf.divide(self.conv20, temp_softmax)) self.conv22 = Reshape((self.num_classes,), name='teacher_reshape_2', trainable=self.trainable)(self.conv21) return self
def VGG16(include_top=True, weights='imagenet', input_tensor=None, input_shape=None, pooling=None, classes=1000): """Instantiates the VGG16 architecture. Optionally loads weights pre-trained on ImageNet. Note that when using TensorFlow, for best performance you should set `image_data_format="channels_last"` in your Keras config at ~/.keras/keras.json. The model and the weights are compatible with both TensorFlow and Theano. The data format convention used by the model is the one specified in your Keras config file. Arguments: include_top: whether to include the 3 fully-connected layers at the top of the network. weights: one of `None` (random initialization) or "imagenet" (pre-training on ImageNet). input_tensor: optional Keras tensor (i.e. output of `layers.Input()`) to use as image input for the model. input_shape: optional shape tuple, only to be specified if `include_top` is False (otherwise the input shape has to be `(224, 224, 3)` (with `channels_last` data format) or `(3, 224, 224)` (with `channels_first` data format). It should have exactly 3 inputs channels, and width and height should be no smaller than 48. E.g. `(200, 200, 3)` would be one valid value. pooling: Optional pooling mode for feature extraction when `include_top` is `False`. - `None` means that the output of the model will be the 4D tensor output of the last convolutional layer. - `avg` means that global average pooling will be applied to the output of the last convolutional layer, and thus the output of the model will be a 2D tensor. - `max` means that global max pooling will be applied. classes: optional number of classes to classify images into, only to be specified if `include_top` is True, and if no `weights` argument is specified. Returns: A Keras model instance. Raises: ValueError: in case of invalid argument for `weights`, or invalid input shape. """ if weights not in {'imagenet', None}: raise ValueError('The `weights` argument should be either ' '`None` (random initialization) or `imagenet` ' '(pre-training on ImageNet).') if weights == 'imagenet' and include_top and classes != 1000: raise ValueError('If using `weights` as imagenet with `include_top`' ' as true, `classes` should be 1000') # Determine proper input shape input_shape = _obtain_input_shape(input_shape, default_size=224, min_size=48, data_format=K.image_data_format(), include_top=include_top) if input_tensor is None: img_input = Input(shape=input_shape) else: img_input = Input(tensor=input_tensor, shape=input_shape) # Block 1 x = Conv2D(64, (3, 3), activation='relu', padding='same', name='block1_conv1')(img_input) x = Conv2D(64, (3, 3), activation='relu', padding='same', name='block1_conv2')(x) x = MaxPooling2D((2, 2), strides=(2, 2), name='block1_pool')(x) # Block 2 x = Conv2D(128, (3, 3), activation='relu', padding='same', name='block2_conv1')(x) x = Conv2D(128, (3, 3), activation='relu', padding='same', name='block2_conv2')(x) x = MaxPooling2D((2, 2), strides=(2, 2), name='block2_pool')(x) # Block 3 x = Conv2D(256, (3, 3), activation='relu', padding='same', name='block3_conv1')(x) x = Conv2D(256, (3, 3), activation='relu', padding='same', name='block3_conv2')(x) x = Conv2D(256, (3, 3), activation='relu', padding='same', name='block3_conv3')(x) x = MaxPooling2D((2, 2), strides=(2, 2), name='block3_pool')(x) # Block 4 x = Conv2D(512, (3, 3), activation='relu', padding='same', name='block4_conv1')(x) x = Conv2D(512, (3, 3), activation='relu', padding='same', name='block4_conv2')(x) x = Conv2D(512, (3, 3), activation='relu', padding='same', name='block4_conv3')(x) x = MaxPooling2D((2, 2), strides=(2, 2), name='block4_pool')(x) # Block 5 x = Conv2D(512, (3, 3), activation='relu', padding='same', name='block5_conv1')(x) x = Conv2D(512, (3, 3), activation='relu', padding='same', name='block5_conv2')(x) x = Conv2D(512, (3, 3), activation='relu', padding='same', name='block5_conv3')(x) x = MaxPooling2D((2, 2), strides=(2, 2), name='block5_pool')(x) if include_top: # Classification block x = Flatten(name='flatten')(x) x = Dense(4096, activation='relu', name='fc1')(x) x = Dense(4096, activation='relu', name='fc2')(x) x = Dense(classes, activation='softmax', name='predictions')(x) else: if pooling == 'avg': x = GlobalAveragePooling2D()(x) elif pooling == 'max': x = GlobalMaxPooling2D()(x) # Ensure that the model takes into account # any potential predecessors of `input_tensor`. if input_tensor is not None: inputs = get_source_inputs(input_tensor) else: inputs = img_input # Create model. model = Model(inputs, x, name='vgg16') # load weights if weights == 'imagenet': if include_top: weights_path = get_file( 'vgg16_weights_tf_dim_ordering_tf_kernels.h5', WEIGHTS_PATH, cache_subdir='models') else: weights_path = get_file( 'vgg16_weights_tf_dim_ordering_tf_kernels_notop.h5', WEIGHTS_PATH_NO_TOP, cache_subdir='models') model.load_weights(weights_path) if K.backend() == 'theano': layer_utils.convert_all_kernels_in_model(model) if K.image_data_format() == 'channels_first': if include_top: maxpool = model.get_layer(name='block5_pool') shape = maxpool.output_shape[1:] dense = model.get_layer(name='fc1') layer_utils.convert_dense_weights_data_format( dense, shape, 'channels_first') if K.backend() == 'tensorflow': warnings.warn('You are using the TensorFlow backend, yet you ' 'are using the Theano ' 'image data format convention ' '(`image_data_format="channels_first"`). ' 'For best performance, set ' '`image_data_format="channels_last"` in ' 'your Keras config ' 'at ~/.keras/keras.json.') return model
def Xception(include_top=True, weights='imagenet', input_tensor=None, input_shape=None, pooling=None, classes=1000): """Instantiates the Xception architecture. Optionally loads weights pre-trained on ImageNet. This model is available for TensorFlow only, and can only be used with inputs following the TensorFlow data format `(width, height, channels)`. You should set `image_data_format="channels_last"` in your Keras config located at ~/.keras/keras.json. Note that the default input image size for this model is 299x299. Arguments: include_top: whether to include the fully-connected layer at the top of the network. weights: one of `None` (random initialization) or "imagenet" (pre-training on ImageNet). input_tensor: optional Keras tensor (i.e. output of `layers.Input()`) to use as image input for the model. input_shape: optional shape tuple, only to be specified if `include_top` is False (otherwise the input shape has to be `(299, 299, 3)`. It should have exactly 3 input channels, and width and height should be no smaller than 71. E.g. `(150, 150, 3)` would be one valid value. pooling: Optional pooling mode for feature extraction when `include_top` is `False`. - `None` means that the output of the model will be the 4D tensor output of the last convolutional layer. - `avg` means that global average pooling will be applied to the output of the last convolutional layer, and thus the output of the model will be a 2D tensor. - `max` means that global max pooling will be applied. classes: optional number of classes to classify images into, only to be specified if `include_top` is True, and if no `weights` argument is specified. Returns: A Keras model instance. Raises: ValueError: in case of invalid argument for `weights`, or invalid input shape. RuntimeError: If attempting to run this model with a backend that does not support separable convolutions. """ if weights not in {'imagenet', None}: raise ValueError('The `weights` argument should be either ' '`None` (random initialization) or `imagenet` ' '(pre-training on ImageNet).') if weights == 'imagenet' and include_top and classes != 1000: raise ValueError('If using `weights` as imagenet with `include_top`' ' as true, `classes` should be 1000') if K.backend() != 'tensorflow': raise RuntimeError('The Xception model is only available with ' 'the TensorFlow backend.') if K.image_data_format() != 'channels_last': logging.warning( 'The Xception model is only available for the ' 'input data format "channels_last" ' '(width, height, channels). ' 'However your settings specify the default ' 'data format "channels_first" (channels, width, height). ' 'You should set `image_data_format="channels_last"` in your Keras ' 'config located at ~/.keras/keras.json. ' 'The model being returned right now will expect inputs ' 'to follow the "channels_last" data format.') K.set_image_data_format('channels_last') old_data_format = 'channels_first' else: old_data_format = None # Determine proper input shape input_shape = _obtain_input_shape(input_shape, default_size=299, min_size=71, data_format=K.image_data_format(), require_flatten=False, weights=weights) if input_tensor is None: img_input = Input(shape=input_shape) else: img_input = Input(tensor=input_tensor, shape=input_shape) x = Conv2D(32, (3, 3), strides=(2, 2), use_bias=False, name='block1_conv1')(img_input) x = BatchNormalization(name='block1_conv1_bn')(x) x = Activation('relu', name='block1_conv1_act')(x) x = Conv2D(64, (3, 3), use_bias=False, name='block1_conv2')(x) x = BatchNormalization(name='block1_conv2_bn')(x) x = Activation('relu', name='block1_conv2_act')(x) residual = Conv2D(128, (1, 1), strides=(2, 2), padding='same', use_bias=False)(x) residual = BatchNormalization()(residual) x = SeparableConv2D(128, (3, 3), padding='same', use_bias=False, name='block2_sepconv1')(x) x = BatchNormalization(name='block2_sepconv1_bn')(x) x = Activation('relu', name='block2_sepconv2_act')(x) x = SeparableConv2D(128, (3, 3), padding='same', use_bias=False, name='block2_sepconv2')(x) x = BatchNormalization(name='block2_sepconv2_bn')(x) x = MaxPooling2D((3, 3), strides=(2, 2), padding='same', name='block2_pool')(x) x = layers.add([x, residual]) residual = Conv2D(256, (1, 1), strides=(2, 2), padding='same', use_bias=False)(x) residual = BatchNormalization()(residual) x = Activation('relu', name='block3_sepconv1_act')(x) x = SeparableConv2D(256, (3, 3), padding='same', use_bias=False, name='block3_sepconv1')(x) x = BatchNormalization(name='block3_sepconv1_bn')(x) x = Activation('relu', name='block3_sepconv2_act')(x) x = SeparableConv2D(256, (3, 3), padding='same', use_bias=False, name='block3_sepconv2')(x) x = BatchNormalization(name='block3_sepconv2_bn')(x) x = MaxPooling2D((3, 3), strides=(2, 2), padding='same', name='block3_pool')(x) x = layers.add([x, residual]) residual = Conv2D(728, (1, 1), strides=(2, 2), padding='same', use_bias=False)(x) residual = BatchNormalization()(residual) x = Activation('relu', name='block4_sepconv1_act')(x) x = SeparableConv2D(728, (3, 3), padding='same', use_bias=False, name='block4_sepconv1')(x) x = BatchNormalization(name='block4_sepconv1_bn')(x) x = Activation('relu', name='block4_sepconv2_act')(x) x = SeparableConv2D(728, (3, 3), padding='same', use_bias=False, name='block4_sepconv2')(x) x = BatchNormalization(name='block4_sepconv2_bn')(x) x = MaxPooling2D((3, 3), strides=(2, 2), padding='same', name='block4_pool')(x) x = layers.add([x, residual]) for i in range(8): residual = x prefix = 'block' + str(i + 5) x = Activation('relu', name=prefix + '_sepconv1_act')(x) x = SeparableConv2D(728, (3, 3), padding='same', use_bias=False, name=prefix + '_sepconv1')(x) x = BatchNormalization(name=prefix + '_sepconv1_bn')(x) x = Activation('relu', name=prefix + '_sepconv2_act')(x) x = SeparableConv2D(728, (3, 3), padding='same', use_bias=False, name=prefix + '_sepconv2')(x) x = BatchNormalization(name=prefix + '_sepconv2_bn')(x) x = Activation('relu', name=prefix + '_sepconv3_act')(x) x = SeparableConv2D(728, (3, 3), padding='same', use_bias=False, name=prefix + '_sepconv3')(x) x = BatchNormalization(name=prefix + '_sepconv3_bn')(x) x = layers.add([x, residual]) residual = Conv2D(1024, (1, 1), strides=(2, 2), padding='same', use_bias=False)(x) residual = BatchNormalization()(residual) x = Activation('relu', name='block13_sepconv1_act')(x) x = SeparableConv2D(728, (3, 3), padding='same', use_bias=False, name='block13_sepconv1')(x) x = BatchNormalization(name='block13_sepconv1_bn')(x) x = Activation('relu', name='block13_sepconv2_act')(x) x = SeparableConv2D(1024, (3, 3), padding='same', use_bias=False, name='block13_sepconv2')(x) x = BatchNormalization(name='block13_sepconv2_bn')(x) x = MaxPooling2D((3, 3), strides=(2, 2), padding='same', name='block13_pool')(x) x = layers.add([x, residual]) x = SeparableConv2D(1536, (3, 3), padding='same', use_bias=False, name='block14_sepconv1')(x) x = BatchNormalization(name='block14_sepconv1_bn')(x) x = Activation('relu', name='block14_sepconv1_act')(x) x = SeparableConv2D(2048, (3, 3), padding='same', use_bias=False, name='block14_sepconv2')(x) x = BatchNormalization(name='block14_sepconv2_bn')(x) x = Activation('relu', name='block14_sepconv2_act')(x) if include_top: x = GlobalAveragePooling2D(name='avg_pool')(x) x = Dense(classes, activation='softmax', name='predictions')(x) else: if pooling == 'avg': x = GlobalAveragePooling2D()(x) elif pooling == 'max': x = GlobalMaxPooling2D()(x) # Ensure that the model takes into account # any potential predecessors of `input_tensor`. if input_tensor is not None: inputs = get_source_inputs(input_tensor) else: inputs = img_input # Create model. model = Model(inputs, x, name='xception') # load weights if weights == 'imagenet': if include_top: weights_path = get_file( 'xception_weights_tf_dim_ordering_tf_kernels.h5', TF_WEIGHTS_PATH, cache_subdir='models') else: weights_path = get_file( 'xception_weights_tf_dim_ordering_tf_kernels_notop.h5', TF_WEIGHTS_PATH_NO_TOP, cache_subdir='models') model.load_weights(weights_path) if old_data_format: K.set_image_data_format(old_data_format) return model
def InceptionV3(include_top=True, weights='imagenet', input_tensor=None, input_shape=None, pooling=None, classes=1000): """Instantiates the Inception v3 architecture. Optionally loads weights pre-trained on ImageNet. Note that when using TensorFlow, for best performance you should set `image_data_format="channels_last"` in your Keras config at ~/.keras/keras.json. The model and the weights are compatible with both TensorFlow and Theano. The data format convention used by the model is the one specified in your Keras config file. Note that the default input image size for this model is 299x299. Arguments: include_top: whether to include the fully-connected layer at the top of the network. weights: one of `None` (random initialization) or "imagenet" (pre-training on ImageNet). input_tensor: optional Keras tensor (i.e. output of `layers.Input()`) to use as image input for the model. input_shape: optional shape tuple, only to be specified if `include_top` is False (otherwise the input shape has to be `(299, 299, 3)` (with `channels_last` data format) or `(3, 299, 299)` (with `channels_first` data format). It should have exactly 3 input channels, and width and height should be no smaller than 139. E.g. `(150, 150, 3)` would be one valid value. pooling: Optional pooling mode for feature extraction when `include_top` is `False`. - `None` means that the output of the model will be the 4D tensor output of the last convolutional layer. - `avg` means that global average pooling will be applied to the output of the last convolutional layer, and thus the output of the model will be a 2D tensor. - `max` means that global max pooling will be applied. classes: optional number of classes to classify images into, only to be specified if `include_top` is True, and if no `weights` argument is specified. Returns: A Keras model instance. Raises: ValueError: in case of invalid argument for `weights`, or invalid input shape. """ if weights not in {'imagenet', None}: raise ValueError('The `weights` argument should be either ' '`None` (random initialization) or `imagenet` ' '(pre-training on ImageNet).') if weights == 'imagenet' and include_top and classes != 1000: raise ValueError('If using `weights` as imagenet with `include_top`' ' as true, `classes` should be 1000') # Determine proper input shape input_shape = _obtain_input_shape( input_shape, default_size=299, min_size=139, data_format=K.image_data_format(), require_flatten=False, weights=weights) if input_tensor is None: img_input = Input(shape=input_shape) else: img_input = Input(tensor=input_tensor, shape=input_shape) if K.image_data_format() == 'channels_first': channel_axis = 1 else: channel_axis = 3 x = conv2d_bn(img_input, 32, 3, 3, strides=(2, 2), padding='valid') x = conv2d_bn(x, 32, 3, 3, padding='valid') x = conv2d_bn(x, 64, 3, 3) x = MaxPooling2D((3, 3), strides=(2, 2))(x) x = conv2d_bn(x, 80, 1, 1, padding='valid') x = conv2d_bn(x, 192, 3, 3, padding='valid') x = MaxPooling2D((3, 3), strides=(2, 2))(x) # mixed 0, 1, 2: 35 x 35 x 256 branch1x1 = conv2d_bn(x, 64, 1, 1) branch5x5 = conv2d_bn(x, 48, 1, 1) branch5x5 = conv2d_bn(branch5x5, 64, 5, 5) branch3x3dbl = conv2d_bn(x, 64, 1, 1) branch3x3dbl = conv2d_bn(branch3x3dbl, 96, 3, 3) branch3x3dbl = conv2d_bn(branch3x3dbl, 96, 3, 3) branch_pool = AveragePooling2D((3, 3), strides=(1, 1), padding='same')(x) branch_pool = conv2d_bn(branch_pool, 32, 1, 1) x = layers.concatenate( [branch1x1, branch5x5, branch3x3dbl, branch_pool], axis=channel_axis, name='mixed0') # mixed 1: 35 x 35 x 256 branch1x1 = conv2d_bn(x, 64, 1, 1) branch5x5 = conv2d_bn(x, 48, 1, 1) branch5x5 = conv2d_bn(branch5x5, 64, 5, 5) branch3x3dbl = conv2d_bn(x, 64, 1, 1) branch3x3dbl = conv2d_bn(branch3x3dbl, 96, 3, 3) branch3x3dbl = conv2d_bn(branch3x3dbl, 96, 3, 3) branch_pool = AveragePooling2D((3, 3), strides=(1, 1), padding='same')(x) branch_pool = conv2d_bn(branch_pool, 64, 1, 1) x = layers.concatenate( [branch1x1, branch5x5, branch3x3dbl, branch_pool], axis=channel_axis, name='mixed1') # mixed 2: 35 x 35 x 256 branch1x1 = conv2d_bn(x, 64, 1, 1) branch5x5 = conv2d_bn(x, 48, 1, 1) branch5x5 = conv2d_bn(branch5x5, 64, 5, 5) branch3x3dbl = conv2d_bn(x, 64, 1, 1) branch3x3dbl = conv2d_bn(branch3x3dbl, 96, 3, 3) branch3x3dbl = conv2d_bn(branch3x3dbl, 96, 3, 3) branch_pool = AveragePooling2D((3, 3), strides=(1, 1), padding='same')(x) branch_pool = conv2d_bn(branch_pool, 64, 1, 1) x = layers.concatenate( [branch1x1, branch5x5, branch3x3dbl, branch_pool], axis=channel_axis, name='mixed2') # mixed 3: 17 x 17 x 768 branch3x3 = conv2d_bn(x, 384, 3, 3, strides=(2, 2), padding='valid') branch3x3dbl = conv2d_bn(x, 64, 1, 1) branch3x3dbl = conv2d_bn(branch3x3dbl, 96, 3, 3) branch3x3dbl = conv2d_bn( branch3x3dbl, 96, 3, 3, strides=(2, 2), padding='valid') branch_pool = MaxPooling2D((3, 3), strides=(2, 2))(x) x = layers.concatenate( [branch3x3, branch3x3dbl, branch_pool], axis=channel_axis, name='mixed3') # mixed 4: 17 x 17 x 768 branch1x1 = conv2d_bn(x, 192, 1, 1) branch7x7 = conv2d_bn(x, 128, 1, 1) branch7x7 = conv2d_bn(branch7x7, 128, 1, 7) branch7x7 = conv2d_bn(branch7x7, 192, 7, 1) branch7x7dbl = conv2d_bn(x, 128, 1, 1) branch7x7dbl = conv2d_bn(branch7x7dbl, 128, 7, 1) branch7x7dbl = conv2d_bn(branch7x7dbl, 128, 1, 7) branch7x7dbl = conv2d_bn(branch7x7dbl, 128, 7, 1) branch7x7dbl = conv2d_bn(branch7x7dbl, 192, 1, 7) branch_pool = AveragePooling2D((3, 3), strides=(1, 1), padding='same')(x) branch_pool = conv2d_bn(branch_pool, 192, 1, 1) x = layers.concatenate( [branch1x1, branch7x7, branch7x7dbl, branch_pool], axis=channel_axis, name='mixed4') # mixed 5, 6: 17 x 17 x 768 for i in range(2): branch1x1 = conv2d_bn(x, 192, 1, 1) branch7x7 = conv2d_bn(x, 160, 1, 1) branch7x7 = conv2d_bn(branch7x7, 160, 1, 7) branch7x7 = conv2d_bn(branch7x7, 192, 7, 1) branch7x7dbl = conv2d_bn(x, 160, 1, 1) branch7x7dbl = conv2d_bn(branch7x7dbl, 160, 7, 1) branch7x7dbl = conv2d_bn(branch7x7dbl, 160, 1, 7) branch7x7dbl = conv2d_bn(branch7x7dbl, 160, 7, 1) branch7x7dbl = conv2d_bn(branch7x7dbl, 192, 1, 7) branch_pool = AveragePooling2D((3, 3), strides=(1, 1), padding='same')(x) branch_pool = conv2d_bn(branch_pool, 192, 1, 1) x = layers.concatenate( [branch1x1, branch7x7, branch7x7dbl, branch_pool], axis=channel_axis, name='mixed' + str(5 + i)) # mixed 7: 17 x 17 x 768 branch1x1 = conv2d_bn(x, 192, 1, 1) branch7x7 = conv2d_bn(x, 192, 1, 1) branch7x7 = conv2d_bn(branch7x7, 192, 1, 7) branch7x7 = conv2d_bn(branch7x7, 192, 7, 1) branch7x7dbl = conv2d_bn(x, 192, 1, 1) branch7x7dbl = conv2d_bn(branch7x7dbl, 192, 7, 1) branch7x7dbl = conv2d_bn(branch7x7dbl, 192, 1, 7) branch7x7dbl = conv2d_bn(branch7x7dbl, 192, 7, 1) branch7x7dbl = conv2d_bn(branch7x7dbl, 192, 1, 7) branch_pool = AveragePooling2D((3, 3), strides=(1, 1), padding='same')(x) branch_pool = conv2d_bn(branch_pool, 192, 1, 1) x = layers.concatenate( [branch1x1, branch7x7, branch7x7dbl, branch_pool], axis=channel_axis, name='mixed7') # mixed 8: 8 x 8 x 1280 branch3x3 = conv2d_bn(x, 192, 1, 1) branch3x3 = conv2d_bn(branch3x3, 320, 3, 3, strides=(2, 2), padding='valid') branch7x7x3 = conv2d_bn(x, 192, 1, 1) branch7x7x3 = conv2d_bn(branch7x7x3, 192, 1, 7) branch7x7x3 = conv2d_bn(branch7x7x3, 192, 7, 1) branch7x7x3 = conv2d_bn( branch7x7x3, 192, 3, 3, strides=(2, 2), padding='valid') branch_pool = MaxPooling2D((3, 3), strides=(2, 2))(x) x = layers.concatenate( [branch3x3, branch7x7x3, branch_pool], axis=channel_axis, name='mixed8') # mixed 9: 8 x 8 x 2048 for i in range(2): branch1x1 = conv2d_bn(x, 320, 1, 1) branch3x3 = conv2d_bn(x, 384, 1, 1) branch3x3_1 = conv2d_bn(branch3x3, 384, 1, 3) branch3x3_2 = conv2d_bn(branch3x3, 384, 3, 1) branch3x3 = layers.concatenate( [branch3x3_1, branch3x3_2], axis=channel_axis, name='mixed9_' + str(i)) branch3x3dbl = conv2d_bn(x, 448, 1, 1) branch3x3dbl = conv2d_bn(branch3x3dbl, 384, 3, 3) branch3x3dbl_1 = conv2d_bn(branch3x3dbl, 384, 1, 3) branch3x3dbl_2 = conv2d_bn(branch3x3dbl, 384, 3, 1) branch3x3dbl = layers.concatenate( [branch3x3dbl_1, branch3x3dbl_2], axis=channel_axis) branch_pool = AveragePooling2D((3, 3), strides=(1, 1), padding='same')(x) branch_pool = conv2d_bn(branch_pool, 192, 1, 1) x = layers.concatenate( [branch1x1, branch3x3, branch3x3dbl, branch_pool], axis=channel_axis, name='mixed' + str(9 + i)) if include_top: # Classification block x = GlobalAveragePooling2D(name='avg_pool')(x) x = Dense(classes, activation='softmax', name='predictions')(x) else: if pooling == 'avg': x = GlobalAveragePooling2D()(x) elif pooling == 'max': x = GlobalMaxPooling2D()(x) # Ensure that the model takes into account # any potential predecessors of `input_tensor`. if input_tensor is not None: inputs = get_source_inputs(input_tensor) else: inputs = img_input # Create model. model = Model(inputs, x, name='inception_v3') # load weights if weights == 'imagenet': if include_top: weights_path = get_file( 'inception_v3_weights_tf_dim_ordering_tf_kernels.h5', WEIGHTS_PATH, cache_subdir='models', md5_hash='9a0d58056eeedaa3f26cb7ebd46da564') else: weights_path = get_file( 'inception_v3_weights_tf_dim_ordering_tf_kernels_notop.h5', WEIGHTS_PATH_NO_TOP, cache_subdir='models', md5_hash='bcbd6486424b2319ff4ef7d526e38f63') model.load_weights(weights_path) return model
def ResNet50(include_top=True, weights='imagenet', input_tensor=None, input_shape=None, pooling=None, classes=1000): """Instantiates the ResNet50 architecture. Optionally loads weights pre-trained on ImageNet. Note that when using TensorFlow, for best performance you should set `image_data_format="channels_last"` in your Keras config at ~/.keras/keras.json. The model and the weights are compatible with both TensorFlow and Theano. The data format convention used by the model is the one specified in your Keras config file. Arguments: include_top: whether to include the 3 fully-connected layers at the top of the network. weights: one of `None` (random initialization) or "imagenet" (pre-training on ImageNet). input_tensor: optional Keras tensor (i.e. output of `layers.Input()`) to use as image input for the model. input_shape: optional shape tuple, only to be specified if `include_top` is False (otherwise the input shape has to be `(224, 224, 3)` (with `channels_last` data format) or `(3, 224, 244)` (with `channels_first` data format). It should have exactly 3 inputs channels, and width and height should be no smaller than 197. E.g. `(200, 200, 3)` would be one valid value. pooling: Optional pooling mode for feature extraction when `include_top` is `False`. - `None` means that the output of the model will be the 4D tensor output of the last convolutional layer. - `avg` means that global average pooling will be applied to the output of the last convolutional layer, and thus the output of the model will be a 2D tensor. - `max` means that global max pooling will be applied. classes: optional number of classes to classify images into, only to be specified if `include_top` is True, and if no `weights` argument is specified. Returns: A Keras model instance. Raises: ValueError: in case of invalid argument for `weights`, or invalid input shape. """ if weights not in {'imagenet', None}: raise ValueError('The `weights` argument should be either ' '`None` (random initialization) or `imagenet` ' '(pre-training on ImageNet).') if weights == 'imagenet' and include_top and classes != 1000: raise ValueError('If using `weights` as imagenet with `include_top`' ' as true, `classes` should be 1000') # Determine proper input shape input_shape = _obtain_input_shape( input_shape, default_size=224, min_size=197, data_format=K.image_data_format(), include_top=include_top) if input_tensor is None: img_input = Input(shape=input_shape) else: img_input = Input(tensor=input_tensor, shape=input_shape) if K.image_data_format() == 'channels_last': bn_axis = 3 else: bn_axis = 1 x = ZeroPadding2D((3, 3))(img_input) x = Conv2D(64, (7, 7), strides=(2, 2), name='conv1')(x) x = BatchNormalization(axis=bn_axis, name='bn_conv1')(x) x = Activation('relu')(x) x = MaxPooling2D((3, 3), strides=(2, 2))(x) x = conv_block(x, 3, [64, 64, 256], stage=2, block='a', strides=(1, 1)) x = identity_block(x, 3, [64, 64, 256], stage=2, block='b') x = identity_block(x, 3, [64, 64, 256], stage=2, block='c') x = conv_block(x, 3, [128, 128, 512], stage=3, block='a') x = identity_block(x, 3, [128, 128, 512], stage=3, block='b') x = identity_block(x, 3, [128, 128, 512], stage=3, block='c') x = identity_block(x, 3, [128, 128, 512], stage=3, block='d') x = conv_block(x, 3, [256, 256, 1024], stage=4, block='a') x = identity_block(x, 3, [256, 256, 1024], stage=4, block='b') x = identity_block(x, 3, [256, 256, 1024], stage=4, block='c') x = identity_block(x, 3, [256, 256, 1024], stage=4, block='d') x = identity_block(x, 3, [256, 256, 1024], stage=4, block='e') x = identity_block(x, 3, [256, 256, 1024], stage=4, block='f') x = conv_block(x, 3, [512, 512, 2048], stage=5, block='a') x = identity_block(x, 3, [512, 512, 2048], stage=5, block='b') x = identity_block(x, 3, [512, 512, 2048], stage=5, block='c') x = AveragePooling2D((7, 7), name='avg_pool')(x) if include_top: x = Flatten()(x) x = Dense(classes, activation='softmax', name='fc1000')(x) else: if pooling == 'avg': x = GlobalAveragePooling2D()(x) elif pooling == 'max': x = GlobalMaxPooling2D()(x) # Ensure that the model takes into account # any potential predecessors of `input_tensor`. if input_tensor is not None: inputs = get_source_inputs(input_tensor) else: inputs = img_input # Create model. model = Model(inputs, x, name='resnet50') # load weights if weights == 'imagenet': if include_top: weights_path = get_file( 'resnet50_weights_tf_dim_ordering_tf_kernels.h5', WEIGHTS_PATH, cache_subdir='models', md5_hash='a7b3fe01876f51b976af0dea6bc144eb') else: weights_path = get_file( 'resnet50_weights_tf_dim_ordering_tf_kernels_notop.h5', WEIGHTS_PATH_NO_TOP, cache_subdir='models', md5_hash='a268eb855778b3df3c7506639542a6af') model.load_weights(weights_path) if K.backend() == 'theano': layer_utils.convert_all_kernels_in_model(model) if K.image_data_format() == 'channels_first': if include_top: maxpool = model.get_layer(name='avg_pool') shape = maxpool.output_shape[1:] dense = model.get_layer(name='fc1000') layer_utils.convert_dense_weights_data_format(dense, shape, 'channels_first') if K.backend() == 'tensorflow': warnings.warn('You are using the TensorFlow backend, yet you ' 'are using the Theano ' 'image data format convention ' '(`image_data_format="channels_first"`). ' 'For best performance, set ' '`image_data_format="channels_last"` in ' 'your Keras config ' 'at ~/.keras/keras.json.') return model
def MobileNet( input_shape=None, # pylint: disable=invalid-name alpha=1.0, depth_multiplier=1, dropout=1e-3, include_top=True, weights='imagenet', input_tensor=None, pooling=None, classes=1000): """Instantiates the MobileNet architecture. Note that only TensorFlow is supported for now, therefore it only works with the data format `image_data_format='channels_last'` in your Keras config at `~/.keras/keras.json`. To load a MobileNet model via `load_model`, import the custom objects `relu6` and `DepthwiseConv2D` and pass them to the `custom_objects` parameter. E.g. model = load_model('mobilenet.h5', custom_objects={ 'relu6': mobilenet.relu6, 'DepthwiseConv2D': mobilenet.DepthwiseConv2D}) Arguments: input_shape: optional shape tuple, only to be specified if `include_top` is False (otherwise the input shape has to be `(224, 224, 3)` (with `channels_last` data format) or (3, 224, 224) (with `channels_first` data format). It should have exactly 3 input channels, and width and height should be no smaller than 32. E.g. `(200, 200, 3)` would be one valid value. alpha: controls the width of the network. - If `alpha` < 1.0, proportionally decreases the number of filters in each layer. - If `alpha` > 1.0, proportionally increases the number of filters in each layer. - If `alpha` = 1, default number of filters from the paper are used at each layer. depth_multiplier: depth multiplier for depthwise convolution (also called the resolution multiplier) dropout: dropout rate include_top: whether to include the fully-connected layer at the top of the network. weights: `None` (random initialization) or `imagenet` (ImageNet weights) input_tensor: optional Keras tensor (i.e. output of `layers.Input()`) to use as image input for the model. pooling: Optional pooling mode for feature extraction when `include_top` is `False`. - `None` means that the output of the model will be the 4D tensor output of the last convolutional layer. - `avg` means that global average pooling will be applied to the output of the last convolutional layer, and thus the output of the model will be a 2D tensor. - `max` means that global max pooling will be applied. classes: optional number of classes to classify images into, only to be specified if `include_top` is True, and if no `weights` argument is specified. Returns: A Keras model instance. Raises: ValueError: in case of invalid argument for `weights`, or invalid input shape. RuntimeError: If attempting to run this model with a backend that does not support separable convolutions. """ if K.backend() != 'tensorflow': raise RuntimeError('Only TensorFlow backend is currently supported, ' 'as other backends do not support ' 'depthwise convolution.') if weights not in {'imagenet', None}: raise ValueError('The `weights` argument should be either ' '`None` (random initialization) or `imagenet` ' '(pre-training on ImageNet).') if weights == 'imagenet' and include_top and classes != 1000: raise ValueError('If using `weights` as ImageNet with `include_top` ' 'as true, `classes` should be 1000') # Determine proper input shape. if input_shape is None: default_size = 224 else: if K.image_data_format() == 'channels_first': rows = input_shape[1] cols = input_shape[2] else: rows = input_shape[0] cols = input_shape[1] if rows == cols and rows in [128, 160, 192, 224]: default_size = rows else: default_size = 224 input_shape = _obtain_input_shape(input_shape, default_size=default_size, min_size=32, data_format=K.image_data_format(), require_flatten=include_top, weights=weights) if K.image_data_format() == 'channels_last': row_axis, col_axis = (0, 1) else: row_axis, col_axis = (1, 2) rows = input_shape[row_axis] cols = input_shape[col_axis] if weights == 'imagenet': if depth_multiplier != 1: raise ValueError('If imagenet weights are being loaded, ' 'depth multiplier must be 1') if alpha not in [0.25, 0.50, 0.75, 1.0]: raise ValueError('If imagenet weights are being loaded, ' 'alpha can be one of' '`0.25`, `0.50`, `0.75` or `1.0` only.') if rows != cols or rows not in [128, 160, 192, 224]: raise ValueError('If imagenet weights are being loaded, ' 'input must have a static square shape (one of ' '(128,128), (160,160), (192,192), or (224, 224)).' ' Input shape provided = %s' % (input_shape, )) if K.image_data_format() != 'channels_last': warnings.warn('The MobileNet family of models is only available ' 'for the input data format "channels_last" ' '(width, height, channels). ' 'However your settings specify the default ' 'data format "channels_first" (channels, width, height).' ' You should set `image_data_format="channels_last"` ' 'in your Keras config located at ~/.keras/keras.json. ' 'The model being returned right now will expect inputs ' 'to follow the "channels_last" data format.') K.set_image_data_format('channels_last') old_data_format = 'channels_first' else: old_data_format = None if input_tensor is None: img_input = Input(shape=input_shape) else: if not K.is_keras_tensor(input_tensor): img_input = Input(tensor=input_tensor, shape=input_shape) else: img_input = input_tensor x = _conv_block(img_input, 32, alpha, strides=(2, 2)) x = _depthwise_conv_block(x, 64, alpha, depth_multiplier, block_id=1) x = _depthwise_conv_block(x, 128, alpha, depth_multiplier, strides=(2, 2), block_id=2) x = _depthwise_conv_block(x, 128, alpha, depth_multiplier, block_id=3) x = _depthwise_conv_block(x, 256, alpha, depth_multiplier, strides=(2, 2), block_id=4) x = _depthwise_conv_block(x, 256, alpha, depth_multiplier, block_id=5) x = _depthwise_conv_block(x, 512, alpha, depth_multiplier, strides=(2, 2), block_id=6) x = _depthwise_conv_block(x, 512, alpha, depth_multiplier, block_id=7) x = _depthwise_conv_block(x, 512, alpha, depth_multiplier, block_id=8) x = _depthwise_conv_block(x, 512, alpha, depth_multiplier, block_id=9) x = _depthwise_conv_block(x, 512, alpha, depth_multiplier, block_id=10) x = _depthwise_conv_block(x, 512, alpha, depth_multiplier, block_id=11) x = _depthwise_conv_block(x, 1024, alpha, depth_multiplier, strides=(2, 2), block_id=12) x = _depthwise_conv_block(x, 1024, alpha, depth_multiplier, block_id=13) if include_top: if K.image_data_format() == 'channels_first': shape = (int(1024 * alpha), 1, 1) else: shape = (1, 1, int(1024 * alpha)) x = GlobalAveragePooling2D()(x) x = Reshape(shape, name='reshape_1')(x) x = Dropout(dropout, name='dropout')(x) x = Conv2D(classes, (1, 1), padding='same', name='conv_preds')(x) x = Activation('softmax', name='act_softmax')(x) x = Reshape((classes, ), name='reshape_2')(x) else: if pooling == 'avg': x = GlobalAveragePooling2D()(x) elif pooling == 'max': x = GlobalMaxPooling2D()(x) # Ensure that the model takes into account # any potential predecessors of `input_tensor`. if input_tensor is not None: inputs = get_source_inputs(input_tensor) else: inputs = img_input # Create model. model = Model(inputs, x, name='mobilenet_%0.2f_%s' % (alpha, rows)) # load weights if weights == 'imagenet': if K.image_data_format() == 'channels_first': raise ValueError('Weights for "channels_last" format ' 'are not available.') if alpha == 1.0: alpha_text = '1_0' elif alpha == 0.75: alpha_text = '7_5' elif alpha == 0.50: alpha_text = '5_0' else: alpha_text = '2_5' if include_top: model_name = 'mobilenet_%s_%d_tf.h5' % (alpha_text, rows) weigh_path = BASE_WEIGHT_PATH + model_name weights_path = get_file(model_name, weigh_path, cache_subdir='models') else: model_name = 'mobilenet_%s_%d_tf_no_top.h5' % (alpha_text, rows) weigh_path = BASE_WEIGHT_PATH + model_name weights_path = get_file(model_name, weigh_path, cache_subdir='models') model.load_weights(weights_path) if old_data_format: K.set_image_data_format(old_data_format) return model
def InceptionResNetV2(include_top=True, weights='imagenet', input_tensor=None, input_shape=None, pooling=None, classes=1000): """Instantiates the Inception-ResNet v2 architecture. Optionally loads weights pre-trained on ImageNet. Note that when using TensorFlow, for best performance you should set `"image_data_format": "channels_last"` in your Keras config at `~/.keras/keras.json`. The model and the weights are compatible with TensorFlow, Theano and CNTK backends. The data format convention used by the model is the one specified in your Keras config file. Note that the default input image size for this model is 299x299, instead of 224x224 as in the VGG16 and ResNet models. Also, the input preprocessing function is different (i.e., do not use `imagenet_utils.preprocess_input()` with this model. Use `preprocess_input()` defined in this module instead). # Arguments include_top: whether to include the fully-connected layer at the top of the network. weights: one of `None` (random initialization) or `'imagenet'` (pre-training on ImageNet). input_tensor: optional Keras tensor (i.e. output of `layers.Input()`) to use as image input for the model. input_shape: optional shape tuple, only to be specified if `include_top` is `False` (otherwise the input shape has to be `(299, 299, 3)` (with `'channels_last'` data format) or `(3, 299, 299)` (with `'channels_first'` data format). It should have exactly 3 inputs channels, and width and height should be no smaller than 139. E.g. `(150, 150, 3)` would be one valid value. pooling: Optional pooling mode for feature extraction when `include_top` is `False`. - `None` means that the output of the model will be the 4D tensor output of the last convolutional layer. - `'avg'` means that global average pooling will be applied to the output of the last convolutional layer, and thus the output of the model will be a 2D tensor. - `'max'` means that global max pooling will be applied. classes: optional number of classes to classify images into, only to be specified if `include_top` is `True`, and if no `weights` argument is specified. # Returns A Keras `Model` instance. # Raises ValueError: in case of invalid argument for `weights`, or invalid input shape. """ if weights not in {'imagenet', None}: raise ValueError('The `weights` argument should be either ' '`None` (random initialization) or `imagenet` ' '(pre-training on ImageNet).') if weights == 'imagenet' and include_top and classes != 1000: raise ValueError('If using `weights` as imagenet with `include_top`' ' as true, `classes` should be 1000') # Determine proper input shape input_shape = _obtain_input_shape(input_shape, default_size=299, min_size=139, data_format=K.image_data_format(), require_flatten=False, weights=weights) if input_tensor is None: img_input = Input(shape=input_shape) else: if not K.is_keras_tensor(input_tensor): img_input = Input(tensor=input_tensor, shape=input_shape) else: img_input = input_tensor # Stem block: 35 x 35 x 192 x = conv2d_bn(img_input, 32, 3, strides=2, padding='valid') x = conv2d_bn(x, 32, 3, padding='valid') x = conv2d_bn(x, 64, 3) x = MaxPooling2D(3, strides=2)(x) x = conv2d_bn(x, 80, 1, padding='valid') x = conv2d_bn(x, 192, 3, padding='valid') x = MaxPooling2D(3, strides=2)(x) # Mixed 5b (Inception-A block): 35 x 35 x 320 branch_0 = conv2d_bn(x, 96, 1) branch_1 = conv2d_bn(x, 48, 1) branch_1 = conv2d_bn(branch_1, 64, 5) branch_2 = conv2d_bn(x, 64, 1) branch_2 = conv2d_bn(branch_2, 96, 3) branch_2 = conv2d_bn(branch_2, 96, 3) branch_pool = AveragePooling2D(3, strides=1, padding='same')(x) branch_pool = conv2d_bn(branch_pool, 64, 1) branches = [branch_0, branch_1, branch_2, branch_pool] channel_axis = 1 if K.image_data_format() == 'channels_first' else 3 x = Concatenate(axis=channel_axis, name='mixed_5b')(branches) # 10x block35 (Inception-ResNet-A block): 35 x 35 x 320 for block_idx in range(1, 11): x = inception_resnet_block(x, scale=0.17, block_type='block35', block_idx=block_idx) # Mixed 6a (Reduction-A block): 17 x 17 x 1088 branch_0 = conv2d_bn(x, 384, 3, strides=2, padding='valid') branch_1 = conv2d_bn(x, 256, 1) branch_1 = conv2d_bn(branch_1, 256, 3) branch_1 = conv2d_bn(branch_1, 384, 3, strides=2, padding='valid') branch_pool = MaxPooling2D(3, strides=2, padding='valid')(x) branches = [branch_0, branch_1, branch_pool] x = Concatenate(axis=channel_axis, name='mixed_6a')(branches) # 20x block17 (Inception-ResNet-B block): 17 x 17 x 1088 for block_idx in range(1, 21): x = inception_resnet_block(x, scale=0.1, block_type='block17', block_idx=block_idx) # Mixed 7a (Reduction-B block): 8 x 8 x 2080 branch_0 = conv2d_bn(x, 256, 1) branch_0 = conv2d_bn(branch_0, 384, 3, strides=2, padding='valid') branch_1 = conv2d_bn(x, 256, 1) branch_1 = conv2d_bn(branch_1, 288, 3, strides=2, padding='valid') branch_2 = conv2d_bn(x, 256, 1) branch_2 = conv2d_bn(branch_2, 288, 3) branch_2 = conv2d_bn(branch_2, 320, 3, strides=2, padding='valid') branch_pool = MaxPooling2D(3, strides=2, padding='valid')(x) branches = [branch_0, branch_1, branch_2, branch_pool] x = Concatenate(axis=channel_axis, name='mixed_7a')(branches) # 10x block8 (Inception-ResNet-C block): 8 x 8 x 2080 for block_idx in range(1, 10): x = inception_resnet_block(x, scale=0.2, block_type='block8', block_idx=block_idx) x = inception_resnet_block(x, scale=1., activation=None, block_type='block8', block_idx=10) # Final convolution block: 8 x 8 x 1536 x = conv2d_bn(x, 1536, 1, name='conv_7b') if include_top: # Classification block x = GlobalAveragePooling2D(name='avg_pool')(x) x = Dense(classes, activation='softmax', name='predictions')(x) else: if pooling == 'avg': x = GlobalAveragePooling2D()(x) elif pooling == 'max': x = GlobalMaxPooling2D()(x) # Ensure that the model takes into account # any potential predecessors of `input_tensor` if input_tensor is not None: inputs = get_source_inputs(input_tensor) else: inputs = img_input # Create model model = Model(inputs, x, name='inception_resnet_v2') # Load weights if weights == 'imagenet': if K.image_data_format() == 'channels_first': if K.backend() == 'tensorflow': warnings.warn('You are using the TensorFlow backend, yet you ' 'are using the Theano ' 'image data format convention ' '(`image_data_format="channels_first"`). ' 'For best performance, set ' '`image_data_format="channels_last"` in ' 'your Keras config ' 'at ~/.keras/keras.json.') if include_top: weights_filename = 'inception_resnet_v2_weights_tf_dim_ordering_tf_kernels.h5' weights_path = get_file( weights_filename, BASE_WEIGHT_URL + weights_filename, cache_subdir='models', file_hash='e693bd0210a403b3192acc6073ad2e96') else: weights_filename = 'inception_resnet_v2_weights_tf_dim_ordering_tf_kernels_notop.h5' weights_path = get_file( weights_filename, BASE_WEIGHT_URL + weights_filename, cache_subdir='models', file_hash='d19885ff4a710c122648d3b5c3b684e4') model.load_weights(weights_path) return model
default='../dataset/flowers/flower_photos') parser.add_argument('--training_percentage', type=float, default=0.8) parser.add_argument('--testing_percentage', type=float, default=0.2) parser.add_argument('--batch_size', type=int, default=32) parser.add_argument('--input_image_size', type=int, default=299) FLAGS, unparsed = parser.parse_known_args() # load pretrained model model_inception_v3 = inception_v3.InceptionV3(include_top=False, weights='imagenet', input_tensor=None, input_shape=None, pooling=None) # add a global spatial average pooling layer x = model_inception_v3.output x = GlobalAveragePooling2D()(x) # add a fully-connected layer x = Dense(1024, activation='relu')(x) # and a logistic layer predictions = Dense(5, activation='softmax')(x) # the model for transform learning model = Model(inputs=model_inception_v3.input, outputs=predictions) print model.summary() # first: train only the top layers (which were randomly initialized) # i.e. freeze all convolutional InceptionV3 layers for layer in model_inception_v3.layers: layer.trainable = False # load dataset # flowers_dataset = create_image_dataset(FLAGS.image_dir, training_percentage=FLAGS.training_percentage,
def SSD300(input_shape, num_classes=21): """SSD300 architecture. # Arguments input_shape: Shape of the input image, expected to be either (300, 300, 3) or (3, 300, 300)(not tested). num_classes: Number of classes including background. # References https://arxiv.org/abs/1512.02325 """ net = {} # Block 1 input_tensor = input_tensor = Input(shape=input_shape) img_size = (input_shape[1], input_shape[0]) net['input'] = input_tensor net['conv1_1'] = Convolution2D(64, (3, 3), activation='relu', padding='same', name='conv1_1')(net['input']) net['conv1_2'] = Convolution2D(64, (3, 3), activation='relu', padding='same', name='conv1_2')(net['conv1_1']) net['pool1'] = MaxPooling2D((2, 2), strides=(2, 2), padding='same', name='pool1')(net['conv1_2']) # Block 2 net['conv2_1'] = Convolution2D(128, (3, 3), activation='relu', padding='same', name='conv2_1')(net['pool1']) net['conv2_2'] = Convolution2D(128, (3, 3), activation='relu', padding='same', name='conv2_2')(net['conv2_1']) net['pool2'] = MaxPooling2D((2, 2), strides=(2, 2), padding='same', name='pool2')(net['conv2_2']) # Block 3 net['conv3_1'] = Convolution2D(256, (3, 3), activation='relu', padding='same', name='conv3_1')(net['pool2']) net['conv3_2'] = Convolution2D(256, (3, 3), activation='relu', padding='same', name='conv3_2')(net['conv3_1']) net['conv3_3'] = Convolution2D(256, (3, 3), activation='relu', padding='same', name='conv3_3')(net['conv3_2']) net['pool3'] = MaxPooling2D((2, 2), strides=(2, 2), padding='same', name='pool3')(net['conv3_3']) # Block 4 net['conv4_1'] = Convolution2D(512, (3, 3), activation='relu', padding='same', name='conv4_1')(net['pool3']) net['conv4_2'] = Convolution2D(512, (3, 3), activation='relu', padding='same', name='conv4_2')(net['conv4_1']) net['conv4_3'] = Convolution2D(512, (3, 3), activation='relu', padding='same', name='conv4_3')(net['conv4_2']) net['pool4'] = MaxPooling2D((2, 2), strides=(2, 2), padding='same', name='pool4')(net['conv4_3']) # Block 5 net['conv5_1'] = Convolution2D(512, (3, 3), activation='relu', padding='same', name='conv5_1')(net['pool4']) net['conv5_2'] = Convolution2D(512, (3, 3), activation='relu', padding='same', name='conv5_2')(net['conv5_1']) net['conv5_3'] = Convolution2D(512, (3, 3), activation='relu', padding='same', name='conv5_3')(net['conv5_2']) net['pool5'] = MaxPooling2D((3, 3), strides=(1, 1), padding='same', name='pool5')(net['conv5_3']) # FC6 net['fc6'] = Convolution2D(1024, (3, 3), dilation_rate=(6, 6), activation='relu', padding='same', name='fc6')(net['pool5']) # x = Dropout(0.5, name='drop6')(x) # FC7 net['fc7'] = Convolution2D(1024, (1, 1), activation='relu', padding='same', name='fc7')(net['fc6']) # x = Dropout(0.5, name='drop7')(x) # Block 6 net['conv6_1'] = Convolution2D(256, (1, 1), activation='relu', padding='same', name='conv6_1')(net['fc7']) net['conv6_2'] = Convolution2D(512, (3, 3), strides=(2, 2), activation='relu', padding='same', name='conv6_2')(net['conv6_1']) # Block 7 net['conv7_1'] = Convolution2D(128, (1, 1), activation='relu', padding='same', name='conv7_1')(net['conv6_2']) net['conv7_2'] = ZeroPadding2D()(net['conv7_1']) net['conv7_2'] = Convolution2D(256, (3, 3), strides=(2, 2), activation='relu', padding='valid', name='conv7_2')(net['conv7_2']) # Block 8 net['conv8_1'] = Convolution2D(128, (1, 1), activation='relu', padding='same', name='conv8_1')(net['conv7_2']) net['conv8_2'] = Convolution2D(256, (3, 3), strides=(2, 2), activation='relu', padding='same', name='conv8_2')(net['conv8_1']) # Last Pool net['pool6'] = GlobalAveragePooling2D(name='pool6')(net['conv8_2']) # Prediction from conv4_3 net['conv4_3_norm'] = Normalize(20, name='conv4_3_norm')(net['conv4_3']) num_priors = 3 x = Convolution2D(num_priors * 4, (3, 3), padding='same', name='conv4_3_norm_mbox_loc')(net['conv4_3_norm']) net['conv4_3_norm_mbox_loc'] = x flatten = Flatten(name='conv4_3_norm_mbox_loc_flat') net['conv4_3_norm_mbox_loc_flat'] = flatten(net['conv4_3_norm_mbox_loc']) name = 'conv4_3_norm_mbox_conf' if num_classes != 21: name += '_{}'.format(num_classes) x = Convolution2D(num_priors * num_classes, (3, 3), padding='same', name=name)(net['conv4_3_norm']) net['conv4_3_norm_mbox_conf'] = x flatten = Flatten(name='conv4_3_norm_mbox_conf_flat') net['conv4_3_norm_mbox_conf_flat'] = flatten(net['conv4_3_norm_mbox_conf']) priorbox = PriorBox(img_size, 30.0, aspect_ratios=[2], variances=[0.1, 0.1, 0.2, 0.2], name='conv4_3_norm_mbox_priorbox') net['conv4_3_norm_mbox_priorbox'] = priorbox(net['conv4_3_norm']) # Prediction from fc7 num_priors = 6 net['fc7_mbox_loc'] = Convolution2D(num_priors * 4, (3, 3), padding='same', name='fc7_mbox_loc')(net['fc7']) flatten = Flatten(name='fc7_mbox_loc_flat') net['fc7_mbox_loc_flat'] = flatten(net['fc7_mbox_loc']) name = 'fc7_mbox_conf' if num_classes != 21: name += '_{}'.format(num_classes) net['fc7_mbox_conf'] = Convolution2D(num_priors * num_classes, (3, 3), padding='same', name=name)(net['fc7']) flatten = Flatten(name='fc7_mbox_conf_flat') net['fc7_mbox_conf_flat'] = flatten(net['fc7_mbox_conf']) priorbox = PriorBox(img_size, 60.0, max_size=114.0, aspect_ratios=[2, 3], variances=[0.1, 0.1, 0.2, 0.2], name='fc7_mbox_priorbox') net['fc7_mbox_priorbox'] = priorbox(net['fc7']) # Prediction from conv6_2 num_priors = 6 x = Convolution2D(num_priors * 4, (3, 3), padding='same', name='conv6_2_mbox_loc')(net['conv6_2']) net['conv6_2_mbox_loc'] = x flatten = Flatten(name='conv6_2_mbox_loc_flat') net['conv6_2_mbox_loc_flat'] = flatten(net['conv6_2_mbox_loc']) name = 'conv6_2_mbox_conf' if num_classes != 21: name += '_{}'.format(num_classes) x = Convolution2D(num_priors * num_classes, (3, 3), padding='same', name=name)(net['conv6_2']) net['conv6_2_mbox_conf'] = x flatten = Flatten(name='conv6_2_mbox_conf_flat') net['conv6_2_mbox_conf_flat'] = flatten(net['conv6_2_mbox_conf']) priorbox = PriorBox(img_size, 114.0, max_size=168.0, aspect_ratios=[2, 3], variances=[0.1, 0.1, 0.2, 0.2], name='conv6_2_mbox_priorbox') net['conv6_2_mbox_priorbox'] = priorbox(net['conv6_2']) # Prediction from conv7_2 num_priors = 6 x = Convolution2D(num_priors * 4, (3, 3), padding='same', name='conv7_2_mbox_loc')(net['conv7_2']) net['conv7_2_mbox_loc'] = x flatten = Flatten(name='conv7_2_mbox_loc_flat') net['conv7_2_mbox_loc_flat'] = flatten(net['conv7_2_mbox_loc']) name = 'conv7_2_mbox_conf' if num_classes != 21: name += '_{}'.format(num_classes) x = Convolution2D(num_priors * num_classes, (3, 3), padding='same', name=name)(net['conv7_2']) net['conv7_2_mbox_conf'] = x flatten = Flatten(name='conv7_2_mbox_conf_flat') net['conv7_2_mbox_conf_flat'] = flatten(net['conv7_2_mbox_conf']) priorbox = PriorBox(img_size, 168.0, max_size=222.0, aspect_ratios=[2, 3], variances=[0.1, 0.1, 0.2, 0.2], name='conv7_2_mbox_priorbox') net['conv7_2_mbox_priorbox'] = priorbox(net['conv7_2']) # Prediction from conv8_2 num_priors = 6 x = Convolution2D(num_priors * 4, (3, 3), padding='same', name='conv8_2_mbox_loc')(net['conv8_2']) net['conv8_2_mbox_loc'] = x flatten = Flatten(name='conv8_2_mbox_loc_flat') net['conv8_2_mbox_loc_flat'] = flatten(net['conv8_2_mbox_loc']) name = 'conv8_2_mbox_conf' if num_classes != 21: name += '_{}'.format(num_classes) x = Convolution2D(num_priors * num_classes, (3, 3), padding='same', name=name)(net['conv8_2']) net['conv8_2_mbox_conf'] = x flatten = Flatten(name='conv8_2_mbox_conf_flat') net['conv8_2_mbox_conf_flat'] = flatten(net['conv8_2_mbox_conf']) priorbox = PriorBox(img_size, 222.0, max_size=276.0, aspect_ratios=[2, 3], variances=[0.1, 0.1, 0.2, 0.2], name='conv8_2_mbox_priorbox') net['conv8_2_mbox_priorbox'] = priorbox(net['conv8_2']) # Prediction from pool6 num_priors = 6 x = Dense(num_priors * 4, name='pool6_mbox_loc_flat')(net['pool6']) net['pool6_mbox_loc_flat'] = x name = 'pool6_mbox_conf_flat' if num_classes != 21: name += '_{}'.format(num_classes) x = Dense(num_priors * num_classes, name=name)(net['pool6']) net['pool6_mbox_conf_flat'] = x priorbox = PriorBox(img_size, 276.0, max_size=330.0, aspect_ratios=[2, 3], variances=[0.1, 0.1, 0.2, 0.2], name='pool6_mbox_priorbox') target_shape = (1, 1, 256) net['pool6_reshaped'] = Reshape(target_shape, name='pool6_reshaped')(net['pool6']) net['pool6_mbox_priorbox'] = priorbox(net['pool6_reshaped']) # Gather all predictions net['mbox_loc'] = concatenate([ net['conv4_3_norm_mbox_loc_flat'], net['fc7_mbox_loc_flat'], net['conv6_2_mbox_loc_flat'], net['conv7_2_mbox_loc_flat'], net['conv8_2_mbox_loc_flat'], net['pool6_mbox_loc_flat'] ], axis=1, name='mbox_loc') net['mbox_conf'] = concatenate([ net['conv4_3_norm_mbox_conf_flat'], net['fc7_mbox_conf_flat'], net['conv6_2_mbox_conf_flat'], net['conv7_2_mbox_conf_flat'], net['conv8_2_mbox_conf_flat'], net['pool6_mbox_conf_flat'] ], axis=1, name='mbox_conf') net['mbox_priorbox'] = concatenate([ net['conv4_3_norm_mbox_priorbox'], net['fc7_mbox_priorbox'], net['conv6_2_mbox_priorbox'], net['conv7_2_mbox_priorbox'], net['conv8_2_mbox_priorbox'], net['pool6_mbox_priorbox'] ], axis=1, name='mbox_priorbox') num_boxes = K.int_shape(net['mbox_loc'])[-1] // 4 net['mbox_loc'] = Reshape((num_boxes, 4), name='mbox_loc_final')(net['mbox_loc']) net['mbox_conf'] = Reshape((num_boxes, num_classes), name='mbox_conf_logits')(net['mbox_conf']) net['mbox_conf'] = Activation('softmax', name='mbox_conf_final')(net['mbox_conf']) net['predictions'] = concatenate( [net['mbox_loc'], net['mbox_conf'], net['mbox_priorbox']], axis=2, #axis = 0, name='predictions') model = Model(net['input'], net['predictions']) return model
def VGG16(include_top=True, weights='imagenet', input_tensor=None, input_shape=None, pooling=None, classes=1000): """Instantiates the VGG16 architecture. Optionally loads weights pre-trained on ImageNet. Note that when using TensorFlow, for best performance you should set `image_data_format="channels_last"` in your Keras config at ~/.keras/keras.json. The model and the weights are compatible with both TensorFlow and Theano. The data format convention used by the model is the one specified in your Keras config file. Arguments: include_top: whether to include the 3 fully-connected layers at the top of the network. weights: one of `None` (random initialization) or "imagenet" (pre-training on ImageNet). input_tensor: optional Keras tensor (i.e. output of `layers.Input()`) to use as image input for the model. input_shape: optional shape tuple, only to be specified if `include_top` is False (otherwise the input shape has to be `(224, 224, 3)` (with `channels_last` data format) or `(3, 224, 224)` (with `channels_first` data format). It should have exactly 3 inputs channels, and width and height should be no smaller than 48. E.g. `(200, 200, 3)` would be one valid value. pooling: Optional pooling mode for feature extraction when `include_top` is `False`. - `None` means that the output of the model will be the 4D tensor output of the last convolutional layer. - `avg` means that global average pooling will be applied to the output of the last convolutional layer, and thus the output of the model will be a 2D tensor. - `max` means that global max pooling will be applied. classes: optional number of classes to classify images into, only to be specified if `include_top` is True, and if no `weights` argument is specified. Returns: A Keras model instance. Raises: ValueError: in case of invalid argument for `weights`, or invalid input shape. """ ### how many weights option can we be allowed if weights not in {'imagenet', None}: raise ValueError('The `weights` argument should be either ' '`None` (random initialization) or `imagenet` ' '(pre-training on ImageNet).') ### if use imagenet weights and add last 3 dense layers, then class should be 1000 if weights == 'imagenet' and include_top and classes != 1000: raise ValueError('If using `weights` as imagenet with `include_top`' ' as true, `classes` should be 1000') ### set input shape : (224, 224, 3) # default input shape for VGG16 model, designed for imagenet dataset input_shape = _obtain_input_shape( input_shape, # if set must be a tuple of 3 integers (50, 50, 3) default_size=224, # if input_shape set, here must be None min_size=48, # 48, but freely change it to your need data_format=K.image_data_format( ), # 'channels_first' or 'channels_last' include_top=include_top ) # True, then must use 224 or False to be other number ### Create input tensor: real tensor or container? if input_tensor is None: # create input tensor placeholder img_input = Input(shape=input_shape) else: img_input = Input(tensor=input_tensor, shape=input_shape) # Block 1 x = Conv2D(64, (3, 3), activation='relu', padding='same', name='block1_conv1')(img_input) ## how to access weights of each layer block1_conv1 = x block1_conv1_bias = block1_conv1.graph._collections['trainable_variables'][ -1] # bias block1_conv1_kernel = block1_conv1.graph._collections[ 'trainable_variables'][-2] # kernel x = Conv2D(64, (3, 3), activation='relu', padding='same', name='block1_conv2')(x) block1_conv2 = x block1_conv2_bias = block1_conv2.graph._collections['trainable_variables'][ -1] # bias block1_conv2_kernel = block1_conv2.graph._collections[ 'trainable_variables'][-2] # kernel x = MaxPooling2D((2, 2), strides=(2, 2), name='block1_pool')(x) block1_pool = x # access trainable_variables or weights with biases block1_pool.graph._collections['variables'][-1] # bias block1_pool.graph._collections['variables'][-2] # kernel # Block 2 x = Conv2D(128, (3, 3), activation='relu', padding='same', name='block2_conv1')(x) block2_conv1 = x x = Conv2D(128, (3, 3), activation='relu', padding='same', name='block2_conv2')(x) block2_conv2 = x x = MaxPooling2D((2, 2), strides=(2, 2), name='block2_pool')(x) block2_pool = x # Block 3 x = Conv2D(256, (3, 3), activation='relu', padding='same', name='block3_conv1')(x) block3_conv1 = x x = Conv2D(256, (3, 3), activation='relu', padding='same', name='block3_conv2')(x) block3_conv2 = x x = Conv2D(256, (3, 3), activation='relu', padding='same', name='block3_conv3')(x) block3_conv3 = x x = MaxPooling2D((2, 2), strides=(2, 2), name='block3_pool')(x) block3_pool = x # Block 4 x = Conv2D(512, (3, 3), activation='relu', padding='same', name='block4_conv1')(x) block4_conv1 = x x = Conv2D(512, (3, 3), activation='relu', padding='same', name='block4_conv2')(x) block4_conv2 = x x = Conv2D(512, (3, 3), activation='relu', padding='same', name='block4_conv3')(x) block4_conv3 = x x = MaxPooling2D((2, 2), strides=(2, 2), name='block4_pool')(x) block4_pool = x # Block 5 x = Conv2D(512, (3, 3), activation='relu', padding='same', name='block5_conv1')(x) block5_conv1 = x x = Conv2D(512, (3, 3), activation='relu', padding='same', name='block5_conv2')(x) block5_conv2 = x x = Conv2D(512, (3, 3), activation='relu', padding='same', name='block5_conv3')(x) block5_conv3 = x x = MaxPooling2D((2, 2), strides=(2, 2), name='block5_pool')(x) block5_pool = x if include_top: # Classification block x = Flatten(name='flatten')(x) flatten = x x = Dense(4096, activation='relu', name='fc1')(x) fc1 = x x = Dense(4096, activation='relu', name='fc2')(x) fc2 = x x = Dense(classes, activation='softmax', name='predictions')(x) predictions = x else: if pooling == 'avg': x = GlobalAveragePooling2D()(x) elif pooling == 'max': x = GlobalMaxPooling2D()(x) # Ensure that the model takes into account # any potential predecessors of `input_tensor`. if input_tensor is not None: inputs = get_source_inputs(input_tensor) else: inputs = img_input # Create model. model = Model(inputs, x, name='vgg16') # load weights if weights == 'imagenet': if include_top: weights_path = get_file( 'vgg16_weights_tf_dim_ordering_tf_kernels.h5', WEIGHTS_PATH, cache_subdir='models') else: weights_path = get_file( 'vgg16_weights_tf_dim_ordering_tf_kernels_notop.h5', WEIGHTS_PATH_NO_TOP, cache_subdir='models') model.load_weights(weights_path) if K.backend() == 'theano': layer_utils.convert_all_kernels_in_model(model) if K.image_data_format() == 'channels_first': if include_top: maxpool = model.get_layer(name='block5_pool') shape = maxpool.output_shape[1:] dense = model.get_layer(name='fc1') layer_utils.convert_dense_weights_data_format( dense, shape, 'channels_first') return model