本篇blog的内容基于原始论文InfoGAN: Interpretable Representation Learning by Information Maximizing Generative Adversarial Nets(NPIs2016)和《生成对抗网络入门指南》第六章。完整代码及简析见文章末尾
一、为什么要使用InfoGAN
InfoGAN采用无监督的方式学习,并尝试实现可解释特征。使用了信息论的原理,通过最大化输入噪声和观察值之间的互信息(Mutual Information,MI)来对网络模型进行优化。InfoGAN能适用于各种复杂的数据集,可以同时实现离散特征和连续特征。
二、输入端数据
InfoGAN在输入端把随机输入分为两个部分:
第一部分为z,代表噪声;
第二部分为c,代表隐含编码;
目标是希望在每个维度上都具备可解释型特征。
在同时输入噪声z和隐含编码c后,生成概率 ![P_G(x\mid c)=P_G(x)]()
,为了应对这个问题,在InfoGAN中需要对隐含编码c和生成分布G(z,c)求互信息 ![I(c;\ G(z.c))]()
,并使其最大化
,为了应对这个问题,在InfoGAN中需要对隐含编码c和生成分布G(z,c)求互信息 
,并使其最大化
三、InfoGAN结构
InfoGAN和前面介绍过的GAN区别在于,真实训练数据不有标签数据,二输入数据为隐含编码和随机噪声的组合,最后通过判别器一端和最大化互信息的方式还原隐含编码的信息。也就是说,判别器D最终需要同时具备还原隐含编码和辨别真伪的能力。前者为了生成图像能够很好具备编码中的特性,也就是说隐含编码可以对生网络产生相对显著地成果;后者是要求生成模型在还原信息的同时保证生成的数据与真实数据非常逼近。
1. 互信息
互信息表示两个随机变量之间的依赖程度的度量。对于随机变量X和Y,互信息为I(X;Y),H(X)和H(Y)为边缘熵,H(X|Y)和H(Y|X)为条件熵。
2. 结构
3. 目标函数
当X和Y相互独立时候,互信息为0.给定任意的输入,希望生成器的 
由于概率
由此可以得到互信息的下界值:
![I(c;G(z,c))\geq E_{x\sim G(z.c)} [ E_{C\sim P(c\midx )} [logQ(c^{'} \mid x)] ] +H(c)](https://pic1.xuehuaimg.com/proxy/csdn/https://private.codecogs.com/gif.latex?I%28c%3BG%28z%2Cc%29%29%5Cgeq%20E_%7Bx%5Csim%20G%28z.c%29%7D%20%5B%20E_%7BC%5Csim%20P%28c%5Cmidx%20%29%7D%20%5BlogQ%28c%5E%7B%27%7D%20%5Cmid%20x%29%5D%20%5D%20+H%28c%29)
4. InfoGAN的推导
我们可以重新改写之前不等式,并重新使蒙特卡洛方法逼近
得到我们最终的目标函数
四、实验效果
1.MNIST数据
我们发现通过控制隐含编码中的
2. 3D人脸数据
3. 椅子数据集
4. 门牌号数据集
五、实验代码
1. 导入相关包及超参数
from __future__ import print_function, division
from keras.datasets import mnist
from keras.layers import Input, Dense, Reshape, Flatten, Dropout, multiply, concatenate
from keras.layers import BatchNormalization, Activation, Embedding, ZeroPadding2D, Lambda
from keras.layers.advanced_activations import LeakyReLU
from keras.layers.convolutional import UpSampling2D, Conv2D
from keras.models import Sequential, Model
from keras.optimizers import Adam
from keras.utils import to_categorical
import keras.backend as K
import matplotlib.pyplot as plt
import numpy as np
class INFOGAN():
def __init__(self):
self.img_rows = 28
self.img_cols = 28
self.channels = 1
self.num_classes = 10
self.img_shape = (self.img_rows, self.img_cols, self.channels)
self.latent_dim = 72
optimizer = Adam(0.0002, 0.5)
losses = ['binary_crossentropy', self.mutual_info_loss]
# Build and the discriminator and recognition network
self.discriminator, self.auxilliary = self.build_disk_and_q_net()
self.discriminator.compile(loss=['binary_crossentropy'],
optimizer=optimizer,
metrics=['accuracy'])
# Build and compile the recognition network Q
self.auxilliary.compile(loss=[self.mutual_info_loss],
optimizer=optimizer,
metrics=['accuracy'])
# Build the generator
self.generator = self.build_generator()
# The generator takes noise and the target label as input
# and generates the corresponding digit of that label
gen_input = Input(shape=(self.latent_dim,))
img = self.generator(gen_input)
# For the combined model we will only train the generator
self.discriminator.trainable = False
# The discriminator takes generated image as input and determines validity
valid = self.discriminator(img)
# The recognition network produces the label
target_label = self.auxilliary(img)
# The combined model (stacked generator and discriminator)
self.combined = Model(gen_input, [valid, target_label])
self.combined.compile(loss=losses,
optimizer=optimizer)
2. 构造生成器和判别器
def build_generator(self):
model = Sequential()
model.add(Dense(128 * 7 * 7, activation="relu", input_dim=self.latent_dim))
model.add(Reshape((7, 7, 128)))
model.add(BatchNormalization(momentum=0.8))
model.add(UpSampling2D())
model.add(Conv2D(128, kernel_size=3, padding="same"))
model.add(Activation("relu"))
model.add(BatchNormalization(momentum=0.8))
model.add(UpSampling2D())
model.add(Conv2D(64, kernel_size=3, padding="same"))
model.add(Activation("relu"))
model.add(BatchNormalization(momentum=0.8))
model.add(Conv2D(self.channels, kernel_size=3, padding='same'))
model.add(Activation("tanh"))
gen_input = Input(shape=(self.latent_dim,))
img = model(gen_input)
model.summary()
return Model(gen_input, img)
def build_disk_and_q_net(self):
img = Input(shape=self.img_shape)
# Shared layers between discriminator and recognition network
model = Sequential()
model.add(Conv2D(64, kernel_size=3, strides=2, input_shape=self.img_shape, padding="same"))
model.add(LeakyReLU(alpha=0.2))
model.add(Dropout(0.25))
model.add(Conv2D(128, kernel_size=3, strides=2, padding="same"))
model.add(ZeroPadding2D(padding=((0,1),(0,1))))
model.add(LeakyReLU(alpha=0.2))
model.add(Dropout(0.25))
model.add(BatchNormalization(momentum=0.8))
model.add(Conv2D(256, kernel_size=3, strides=2, padding="same"))
model.add(LeakyReLU(alpha=0.2))
model.add(Dropout(0.25))
model.add(BatchNormalization(momentum=0.8))
model.add(Conv2D(512, kernel_size=3, strides=2, padding="same"))
model.add(LeakyReLU(alpha=0.2))
model.add(Dropout(0.25))
model.add(BatchNormalization(momentum=0.8))
model.add(Flatten())
img_embedding = model(img)
# Discriminator
validity = Dense(1, activation='sigmoid')(img_embedding)
# Recognition
q_net = Dense(128, activation='relu')(img_embedding)
label = Dense(self.num_classes, activation='softmax')(q_net)
# Return discriminator and recognition network
return Model(img, validity), Model(img, label)
3. 构造互信息
def mutual_info_loss(self, c, c_given_x):
"""The mutual information metric we aim to minimize"""
eps = 1e-8
conditional_entropy = K.mean(- K.sum(K.log(c_given_x + eps) * c, axis=1))
entropy = K.mean(- K.sum(K.log(c + eps) * c, axis=1))
return conditional_entropy + entropy
def sample_generator_input(self, batch_size):
# Generator inputs
sampled_noise = np.random.normal(0, 1, (batch_size, 62))
sampled_labels = np.random.randint(0, self.num_classes, batch_size).reshape(-1, 1)
sampled_labels = to_categorical(sampled_labels, num_classes=self.num_classes)
return sampled_noise, sampled_labels
4. 训练
def train(self, epochs, batch_size=128, sample_interval=50):
# Load the dataset
(X_train, y_train), (_, _) = mnist.load_data()
# Rescale -1 to 1
X_train = (X_train.astype(np.float32) - 127.5) / 127.5
X_train = np.expand_dims(X_train, axis=3)
y_train = y_train.reshape(-1, 1)
# Adversarial ground truths
valid = np.ones((batch_size, 1))
fake = np.zeros((batch_size, 1))
for epoch in range(epochs):
# ---------------------
# Train Discriminator
# ---------------------
# Select a random half batch of images
idx = np.random.randint(0, X_train.shape[0], batch_size)
imgs = X_train[idx]
# Sample noise and categorical labels
sampled_noise, sampled_labels = self.sample_generator_input(batch_size)
gen_input = np.concatenate((sampled_noise, sampled_labels), axis=1)
# Generate a half batch of new images
gen_imgs = self.generator.predict(gen_input)
# Train on real and generated data
d_loss_real = self.discriminator.train_on_batch(imgs, valid)
d_loss_fake = self.discriminator.train_on_batch(gen_imgs, fake)
# Avg. loss
d_loss = 0.5 * np.add(d_loss_real, d_loss_fake)
# ---------------------
# Train Generator and Q-network
# ---------------------
g_loss = self.combined.train_on_batch(gen_input, [valid, sampled_labels])
# Plot the progress
print ("%d [D loss: %.2f, acc.: %.2f%%] [Q loss: %.2f] [G loss: %.2f]" % (epoch, d_loss[0], 100*d_loss[1], g_loss[1], g_loss[2]))
# If at save interval => save generated image samples
if epoch % sample_interval == 0:
self.sample_images(epoch)
5. 可视化
def sample_images(self, epoch):
r, c = 10, 10
fig, axs = plt.subplots(r, c)
for i in range(c):
sampled_noise, _ = self.sample_generator_input(c)
label = to_categorical(np.full(fill_value=i, shape=(r,1)), num_classes=self.num_classes)
gen_input = np.concatenate((sampled_noise, label), axis=1)
gen_imgs = self.generator.predict(gen_input)
gen_imgs = 0.5 * gen_imgs + 0.5
for j in range(r):
axs[j,i].imshow(gen_imgs[j,:,:,0], cmap='gray')
axs[j,i].axis('off')
fig.savefig("images/%d.png" % epoch)
plt.close()
def save_model(self):
def save(model, model_name):
model_path = "saved_model/%s.json" % model_name
weights_path = "saved_model/%s_weights.hdf5" % model_name
options = {"file_arch": model_path,
"file_weight": weights_path}
json_string = model.to_json()
open(options['file_arch'], 'w').write(json_string)
model.save_weights(options['file_weight'])
save(self.generator, "generator")
save(self.discriminator, "discriminator")
if __name__ == '__main__':
infogan = INFOGAN()
infogan.train(epochs=50000, batch_size=128, sample_interval=50)
实验结果
完整代码
from __future__ import print_function, division
from keras.datasets import mnist
from keras.layers import Input, Dense, Reshape, Flatten, Dropout, multiply, concatenate
from keras.layers import BatchNormalization, Activation, Embedding, ZeroPadding2D, Lambda
from keras.layers.advanced_activations import LeakyReLU
from keras.layers.convolutional import UpSampling2D, Conv2D
from keras.models import Sequential, Model
from keras.optimizers import Adam
from keras.utils import to_categorical
import keras.backend as K
import matplotlib.pyplot as plt
import numpy as np
class INFOGAN():
def __init__(self):
self.img_rows = 28
self.img_cols = 28
self.channels = 1
self.num_classes = 10
self.img_shape = (self.img_rows, self.img_cols, self.channels)
self.latent_dim = 72
optimizer = Adam(0.0002, 0.5)
losses = ['binary_crossentropy', self.mutual_info_loss]
# Build and the discriminator and recognition network
self.discriminator, self.auxilliary = self.build_disk_and_q_net()
self.discriminator.compile(loss=['binary_crossentropy'],
optimizer=optimizer,
metrics=['accuracy'])
# Build and compile the recognition network Q
self.auxilliary.compile(loss=[self.mutual_info_loss],
optimizer=optimizer,
metrics=['accuracy'])
# Build the generator
self.generator = self.build_generator()
# The generator takes noise and the target label as input
# and generates the corresponding digit of that label
gen_input = Input(shape=(self.latent_dim,))
img = self.generator(gen_input)
# For the combined model we will only train the generator
self.discriminator.trainable = False
# The discriminator takes generated image as input and determines validity
valid = self.discriminator(img)
# The recognition network produces the label
target_label = self.auxilliary(img)
# The combined model (stacked generator and discriminator)
self.combined = Model(gen_input, [valid, target_label])
self.combined.compile(loss=losses,
optimizer=optimizer)
def build_generator(self):
model = Sequential()
model.add(Dense(128 * 7 * 7, activation="relu", input_dim=self.latent_dim))
model.add(Reshape((7, 7, 128)))
model.add(BatchNormalization(momentum=0.8))
model.add(UpSampling2D())
model.add(Conv2D(128, kernel_size=3, padding="same"))
model.add(Activation("relu"))
model.add(BatchNormalization(momentum=0.8))
model.add(UpSampling2D())
model.add(Conv2D(64, kernel_size=3, padding="same"))
model.add(Activation("relu"))
model.add(BatchNormalization(momentum=0.8))
model.add(Conv2D(self.channels, kernel_size=3, padding='same'))
model.add(Activation("tanh"))
gen_input = Input(shape=(self.latent_dim,))
img = model(gen_input)
model.summary()
return Model(gen_input, img)
def build_disk_and_q_net(self):
img = Input(shape=self.img_shape)
# Shared layers between discriminator and recognition network
model = Sequential()
model.add(Conv2D(64, kernel_size=3, strides=2, input_shape=self.img_shape, padding="same"))
model.add(LeakyReLU(alpha=0.2))
model.add(Dropout(0.25))
model.add(Conv2D(128, kernel_size=3, strides=2, padding="same"))
model.add(ZeroPadding2D(padding=((0,1),(0,1))))
model.add(LeakyReLU(alpha=0.2))
model.add(Dropout(0.25))
model.add(BatchNormalization(momentum=0.8))
model.add(Conv2D(256, kernel_size=3, strides=2, padding="same"))
model.add(LeakyReLU(alpha=0.2))
model.add(Dropout(0.25))
model.add(BatchNormalization(momentum=0.8))
model.add(Conv2D(512, kernel_size=3, strides=2, padding="same"))
model.add(LeakyReLU(alpha=0.2))
model.add(Dropout(0.25))
model.add(BatchNormalization(momentum=0.8))
model.add(Flatten())
img_embedding = model(img)
# Discriminator
validity = Dense(1, activation='sigmoid')(img_embedding)
# Recognition
q_net = Dense(128, activation='relu')(img_embedding)
label = Dense(self.num_classes, activation='softmax')(q_net)
# Return discriminator and recognition network
return Model(img, validity), Model(img, label)
def mutual_info_loss(self, c, c_given_x):
"""The mutual information metric we aim to minimize"""
eps = 1e-8
conditional_entropy = K.mean(- K.sum(K.log(c_given_x + eps) * c, axis=1))
entropy = K.mean(- K.sum(K.log(c + eps) * c, axis=1))
return conditional_entropy + entropy
def sample_generator_input(self, batch_size):
# Generator inputs
sampled_noise = np.random.normal(0, 1, (batch_size, 62))
sampled_labels = np.random.randint(0, self.num_classes, batch_size).reshape(-1, 1)
sampled_labels = to_categorical(sampled_labels, num_classes=self.num_classes)
return sampled_noise, sampled_labels
def train(self, epochs, batch_size=128, sample_interval=50):
# Load the dataset
(X_train, y_train), (_, _) = mnist.load_data()
# Rescale -1 to 1
X_train = (X_train.astype(np.float32) - 127.5) / 127.5
X_train = np.expand_dims(X_train, axis=3)
y_train = y_train.reshape(-1, 1)
# Adversarial ground truths
valid = np.ones((batch_size, 1))
fake = np.zeros((batch_size, 1))
for epoch in range(epochs):
# ---------------------
# Train Discriminator
# ---------------------
# Select a random half batch of images
idx = np.random.randint(0, X_train.shape[0], batch_size)
imgs = X_train[idx]
# Sample noise and categorical labels
sampled_noise, sampled_labels = self.sample_generator_input(batch_size)
gen_input = np.concatenate((sampled_noise, sampled_labels), axis=1)
# Generate a half batch of new images
gen_imgs = self.generator.predict(gen_input)
# Train on real and generated data
d_loss_real = self.discriminator.train_on_batch(imgs, valid)
d_loss_fake = self.discriminator.train_on_batch(gen_imgs, fake)
# Avg. loss
d_loss = 0.5 * np.add(d_loss_real, d_loss_fake)
# ---------------------
# Train Generator and Q-network
# ---------------------
g_loss = self.combined.train_on_batch(gen_input, [valid, sampled_labels])
# Plot the progress
print ("%d [D loss: %.2f, acc.: %.2f%%] [Q loss: %.2f] [G loss: %.2f]" % (epoch, d_loss[0], 100*d_loss[1], g_loss[1], g_loss[2]))
# If at save interval => save generated image samples
if epoch % sample_interval == 0:
self.sample_images(epoch)
def sample_images(self, epoch):
r, c = 10, 10
fig, axs = plt.subplots(r, c)
for i in range(c):
sampled_noise, _ = self.sample_generator_input(c)
label = to_categorical(np.full(fill_value=i, shape=(r,1)), num_classes=self.num_classes)
gen_input = np.concatenate((sampled_noise, label), axis=1)
gen_imgs = self.generator.predict(gen_input)
gen_imgs = 0.5 * gen_imgs + 0.5
for j in range(r):
axs[j,i].imshow(gen_imgs[j,:,:,0], cmap='gray')
axs[j,i].axis('off')
fig.savefig("images/%d.png" % epoch)
plt.close()
def save_model(self):
def save(model, model_name):
model_path = "saved_model/%s.json" % model_name
weights_path = "saved_model/%s_weights.hdf5" % model_name
options = {"file_arch": model_path,
"file_weight": weights_path}
json_string = model.to_json()
open(options['file_arch'], 'w').write(json_string)
model.save_weights(options['file_weight'])
save(self.generator, "generator")
save(self.discriminator, "discriminator")
if __name__ == '__main__':
infogan = INFOGAN()
infogan.train(epochs=50000, batch_size=128, sample_interval=50)