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doubleunet.py
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doubleunet.py
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import tensorflow as tf
from tensorflow.keras.layers import *
from tensorflow.keras.models import Model
from tensorflow.keras.applications import *
def squeeze_excite_block(inputs, ratio=8):
init = inputs
channel_axis = -1
filters = init.shape[channel_axis]
se_shape = (1, 1, filters)
se = GlobalAveragePooling2D()(init)
se = Reshape(se_shape)(se)
se = Dense(filters // ratio, activation='relu', kernel_initializer='he_normal', use_bias=False)(se)
se = Dense(filters, activation='sigmoid', kernel_initializer='he_normal', use_bias=False)(se)
x = Multiply()([init, se])
return x
def conv_block(inputs, filters):
x = inputs
x = Conv2D(filters, (3, 3), padding="same")(x)
x = BatchNormalization()(x)
x = Activation('relu')(x)
x = Conv2D(filters, (3, 3), padding="same")(x)
x = BatchNormalization()(x)
x = Activation('relu')(x)
x = squeeze_excite_block(x)
return x
def encoder1(inputs):
skip_connections = []
model = VGG19(include_top=False, weights='imagenet', input_tensor=inputs)
names = ["block1_conv2", "block2_conv2", "block3_conv4", "block4_conv4"]
for name in names:
skip_connections.append(model.get_layer(name).output)
output = model.get_layer("block5_conv4").output
return output, skip_connections
def decoder1(inputs, skip_connections):
num_filters = [256, 128, 64, 32]
skip_connections.reverse()
x = inputs
for i, f in enumerate(num_filters):
x = UpSampling2D((2, 2), interpolation='bilinear')(x)
x = Concatenate()([x, skip_connections[i]])
x = conv_block(x, f)
return x
# def encoder2(inputs):
# skip_connections = []
#
# output = DenseNet121(include_top=False, saved_models='imagenet')(inputs)
# model = tf.keras.models.Model(inputs, output)
#
# names = ["input_2", "conv1/relu", "pool2_conv", "pool3_conv"]
# for name in names:
# skip_connections.append(model.get_layer(name).output)
# output = model.get_layer("pool4_conv").output
#
# return output, skip_connections
def encoder2(inputs):
num_filters = [32, 64, 128, 256]
skip_connections = []
x = inputs
for i, f in enumerate(num_filters):
x = conv_block(x, f)
skip_connections.append(x)
x = MaxPool2D((2, 2))(x)
return x, skip_connections
def decoder2(inputs, skip_1, skip_2):
num_filters = [256, 128, 64, 32]
skip_2.reverse()
x = inputs
for i, f in enumerate(num_filters):
x = UpSampling2D((2, 2), interpolation='bilinear')(x)
x = Concatenate()([x, skip_1[i], skip_2[i]])
x = conv_block(x, f)
return x
def output_block(inputs):
x = Conv2D(1, (1, 1), padding="same")(inputs)
x = Activation('sigmoid')(x)
return x
def Upsample(tensor, size):
"""Bilinear upsampling"""
def _upsample(x, size):
return tf.image.resize(images=x, size=size)
return Lambda(lambda x: _upsample(x, size), output_shape=size)(tensor)
def ASPP(x, filter):
shape = x.shape
y1 = AveragePooling2D(pool_size=(shape[1], shape[2]))(x)
y1 = Conv2D(filter, 1, padding="same")(y1)
y1 = BatchNormalization()(y1)
y1 = Activation("relu")(y1)
y1 = UpSampling2D((shape[1], shape[2]), interpolation='bilinear')(y1)
y2 = Conv2D(filter, 1, dilation_rate=1, padding="same", use_bias=False)(x)
y2 = BatchNormalization()(y2)
y2 = Activation("relu")(y2)
y3 = Conv2D(filter, 3, dilation_rate=6, padding="same", use_bias=False)(x)
y3 = BatchNormalization()(y3)
y3 = Activation("relu")(y3)
y4 = Conv2D(filter, 3, dilation_rate=12, padding="same", use_bias=False)(x)
y4 = BatchNormalization()(y4)
y4 = Activation("relu")(y4)
y5 = Conv2D(filter, 3, dilation_rate=18, padding="same", use_bias=False)(x)
y5 = BatchNormalization()(y5)
y5 = Activation("relu")(y5)
y = Concatenate()([y1, y2, y3, y4, y5])
y = Conv2D(filter, 1, dilation_rate=1, padding="same", use_bias=False)(y)
y = BatchNormalization()(y)
y = Activation("relu")(y)
return y
class DoubleUnet:
def __init__(self, img_w=256, img_h=256, img_channels=3, **kwargs):
self.shape = (img_w, img_h, img_channels)
def get_model(self):
inputs = Input(self.shape)
x, skip_1 = encoder1(inputs)
x = ASPP(x, 64)
x = decoder1(x, skip_1)
outputs1 = output_block(x)
x = inputs * outputs1
x, skip_2 = encoder2(x)
x = ASPP(x, 64)
x = decoder2(x, skip_1, skip_2)
outputs2 = output_block(x)
outputs = Concatenate()([outputs1, outputs2])
model = Model(inputs, outputs)
return model