This article was published as a part of the Data Science Blogathon
Have you ever visited this website? The name of the website exactly matches what it does. Yes, you’ve heard it right! The person you just saw in an image on the website does not really exist in the world. Again visit the website and keep refreshing the page. You’ll see different people each time who do not really exist. This seems like a MAGIC right (at least at first sight) and the Generative Adversarial Network is the MAGICIAN!
In this article, We’ll be discussing the Generative Adversarial Networks(GAN in short). Ian J. Goodfellow and co-authors have introduced the GAN in the year 2014. Prominent Researcher in the area of Deep Learning – Yann LeCun, described it as:
“the most interesting idea in the last 10 years in Machine Learning”.
You can now guess the importance of the topic we’re talking about! So, let’s get started.
After reading this article, you will know:
Let us take an analogy to understand this concept:
Let’s say you are a cricket player and unfortunately you are not good at facing Yorkers. What would you do to overcome this? You would simply ask bowlers to bowl Yorkers in your net sessions to get better at it. You would also observe the batsmen who are good at facing Yorkers. You probably keep practicing and learning from your mistakes. You would repeat this step until you become good BEST at facing Yorkers. A similar concept can be incorporated in GANs.
The more you face Yorkers, the better you’ll become at facing Yorkers. But wait, to face more Yorkers, you must have the bowlers who can bowl Yorkers more frequently. So, you become good at facing Yorkers indirectly depends on the bowlers you choose.
Simply, for getting a powerful hero (generator), we need a more powerful opponent (discriminator)!
Now, let us understand it technically.
Generative Adversarial Networks(GAN in short) is an advancement in the field of Machine Learning which is capable of generating new data samples including Text, Audio, Images, Videos, etc. using previously available data. GANs consist of two Artificial Neural Networks or Convolution Neural Networks models namely Generator and Discriminator which are trained against each other (and thus Adversarial). We’ll discuss more this in the following section.
As we’ve discussed that GANs consists of two ANN or CNN models:
Let us understand each separately.
Note: For simplicity, we’ll consider the Image Generation application to understand the GANs. Similar concepts can be applied to other applications.
The Generator Model generates new images by taking a fixed size random noise as an input. Generated images are then fed to the Discriminator Model.
The main goal of the Generator is to fool the Discriminator by generating images that look like real images and thus makes it harder for the Discriminator to classify images as real or fake.
The Discriminator Model takes an image as an input (generated and real) and classifies it as real or fake.
Generated images come from the Generator and the real images come from the training data.
The discriminator model is the simple binary classification model.
Now, let us combine both the architectures and understand them in detail.
The Generator Model G takes a random input vector z as an input and generates the images G(z). These generated images along with the real images x from training data are then fed to the Discriminator Model D. The Discriminator Model then classifies the images as real or fake. Then, we have to measure the loss and this loss has to be back propagated to update the weights of the Generator and the Discriminator.
When we are training the Discriminator, we have to freeze the Generator and back propagate errors to only update the Discriminator.
When we are training the Generator, we have to freeze the Discriminator and back propagate errors to only update the Generator.
Thus the Generator Model and the Discriminator Model getting better and better at each epoch.
We have to stop training when it attains the Nash Equilibrium or D(x) = 0.5 for all x. In simple words, when the generated images look almost like real images.
Let us introduce some notations to understand the loss function of the GANs.
G | Generator Model |
D | Discriminator Model |
z | Random Noise (Fixed size input vector) |
x | Real Image |
G(z) | Image generated by Generator (Fake Image) |
pdata(x) | Probability Distribution of Real Images |
pz(z) | Probability Distribution of Fake Images |
D(G(z)) | Discriminator’s output when the generated image is an input |
D(x) | Discriminator’s output when the real image is an input |
The fight between the Generator Model and the Discriminator Model can be expressed mathematically as:
Note: The term Ex~pdata(x) [log D(x)] can be read as E of log(D(x)) when x is sampled from pdata(x) and similar for the second term.
As we can see in the equation, the Generator wants to minimize the V(D, G) whereas the Discriminator wants to maximize the V(D, G). Let us understand both terms:
Let us understand the equation by thinking from the Generator’s and the Discriminator’s perspectives separately.
The Discriminator wants to maximize the loss function V(D, G) by correctly classifying real and fake images.
The first term suggests that the Discriminator wants to make D(x) as close to 1 as possible, i.e. correctly classifying real images as real.
The second term suggests that the Discriminator wants to make D(G(x)) as close to 0 as possible, i.e. correctly classifying fake images as fake and thus maximize the term eventually (1 – smaller number will result in a larger number). Note: Probability lies in the range of 0-1.
Thus, The Discriminator tries to maximize both the terms.
The Generator wants to minimize the loss function V(D, G) by generating images that look like real images and tries to fool the Discriminator.
The second term suggests that the Generator wants to make D(G(z)) as close to 1 (instead of 0) as possible and thus minimize the term eventually (1 – larger number will result in a smaller number). So that the Discriminator fails and misclassifies the images.
Thus, The Generator tries to minimize the second term.
Let us discuss some amazing applications of GANs other than image generation.
Phillip Isola, et al. in this paper demonstrates GANs as many images to image translation tasks.
Scott Reed, et al. in this paper, demonstrates a way to generate images from text.
Yaniv Taigman, et al. in this paper used GANs to translate photos to emojis.
There are many more applications of GAN such as Image Editing, Face Aging, 3D Object Generation, etc.
So, Now we’ve got a clear idea about the GANs. Let’s start implementing it using Tensorflow and Keras.
We’ll begin by Importing Necessary Libraries, considering you’ve installed all the necessary libraries already.
from numpy import zeros, ones, expand_dims, asarray from numpy.random import randn, randint from keras.datasets import fashion_mnist from keras.optimizers import Adam from keras.models import Model, load_model from keras.layers import Input, Dense, Reshape, Flatten from keras.layers import Conv2D, Conv2DTranspose, Concatenate from keras.layers import LeakyReLU, Dropout, Embedding from keras.layers import BatchNormalization, Activation from keras import initializers from keras.initializers import RandomNormal from keras.optimizers import Adam, RMSprop, SGD from matplotlib import pyplot import numpy as np from math import sqrt
(X_train, _), (_, _) = fashion_mnist.load_data() X_train = X_train.astype(np.float32) / 127.5 - 1 X_train = np.expand_dims(X_train, axis=3) print(X_train.shape)
We are only loading the features of train data as we do not require the labels. Then we are dividing each pixel value by 127.5 and subtracting it from 1 to have pixel values in the range of -1 to 1. Finally, the X_train shape is (60000, 28, 28, 1).
def generate_latent_points(latent_dim, n_samples): x_input = randn(latent_dim * n_samples) z_input = x_input.reshape(n_samples, latent_dim) return z_input
We are using the above function to generate latent points of the shape n_samplesxlatent_dim(100 in our case).
def generate_real_samples(X_train, n_samples): ix = randint(0, X_train.shape[0], n_samples) X = X_train[ix] y = ones((n_samples, 1)) return X, y
The above function helps us to generate n real samples with 1 as a label, i.e. real image.
def generate_fake_samples(generator, latent_dim, n_samples): z_input = generate_latent_points(latent_dim, n_samples) images = generator.predict(z_input) y = zeros((n_samples, 1)) return images, y
The above function helps us to generate n fake samples using the generator with 0 as a label, i.e. fake image.
def summarize_performance(step, g_model, latent_dim, n_samples=100): X, _ = generate_fake_samples(g_model, latent_dim, n_samples) X = (X + 1) / 2.0 for i in range(100): pyplot.subplot(10, 10, 1 + i) pyplot.axis('off') pyplot.imshow(X[i, :, :, 0], cmap='gray_r') filename2 = 'model_%04d.h5' % (step+1) g_model.save(filename2) print('>Saved: %s' % (filename2))
This function helps us to summarize the performance. This includes generating a fake sample, plotting it, and finally saving the model.
def save_plot(examples, n_examples): for i in range(n_examples): pyplot.subplot(sqrt(n_examples), sqrt(n_examples), 1 + i) pyplot.axis('off') pyplot.imshow(examples[i, :, :, 0], cmap='gray_r') pyplot.show()
The above function helps us to plot the results. We’ll use this to plot the generated images by the Generator in later stages.
def define_discriminator(in_shape=(28, 28, 1)): init = RandomNormal(stddev=0.02) in_image = Input(shape=in_shape) fe = Flatten()(in_image) fe = Dense(1024)(fe) fe = LeakyReLU(alpha=0.2)(fe) fe = Dropout(0.3)(fe) fe = Dense(512)(fe) fe = LeakyReLU(alpha=0.2)(fe) fe = Dropout(0.3)(fe) fe = Dense(256)(fe) fe = LeakyReLU(alpha=0.2)(fe) fe = Dropout(0.3)(fe) out = Dense(1, activation='sigmoid')(fe) model = Model(in_image, out) opt = Adam(lr=0.0002, beta_1=0.5) model.compile(loss='binary_crossentropy', optimizer=opt, metrics=['accuracy']) return model
discriminator = define_discriminator()
We are using couple of Dense, Flatten and Dropout layers with leaky relu as an activation function in hidden layers and sigmoid in the final layer, adam as an optimizer and binary cross-entropy as a loss function as the discriminator’s task is to perform the binary classification.
def define_generator(latent_dim): init = RandomNormal(stddev=0.02) in_lat = Input(shape=(latent_dim,)) gen = Dense(256, kernel_initializer=init)(in_lat) gen = LeakyReLU(alpha=0.2)(gen) gen = Dense(512, kernel_initializer=init)(gen) gen = LeakyReLU(alpha=0.2)(gen) gen = Dense(1024, kernel_initializer=init)(gen) gen = LeakyReLU(alpha=0.2)(gen) gen = Dense(28 * 28 * 1, kernel_initializer=init)(gen) out_layer = Activation('tanh')(gen) out_layer = Reshape((28, 28, 1))(gen) model = Model(in_lat, out_layer) return model
generator = define_generator(100)
We are using a couple of Dense layers to define the generator model with again leaky relu as an activation function in hidden layers and tanh in the final layer. The generated images G(z) will be of the shape 28x28x1.
def define_gan(g_model, d_model): d_model.trainable = False gan_output = d_model(g_model.output) model = Model(g_model.input, gan_output) opt = Adam(lr=0.0002, beta_1=0.5) model.compile(loss='binary_crossentropy', optimizer=opt, metrics=['accuracy']) return model
gan_model = define_gan(generator, discriminator)
We are freezing the discriminator, providing z as input and D(G(z)) as an output to our model. We are using adam as an optimizer and binary cross-entropy as a loss function.
def train(g_model, d_model, gan_model, X_train, latent_dim, n_epochs=100, n_batch=64): bat_per_epo = int(X_train.shape[0] / n_batch) n_steps = bat_per_epo * n_epochs for i in range(n_steps): X_real, y_real = generate_real_samples(X_train, n_batch) d_loss_r, d_acc_r = d_model.train_on_batch(X_real, y_real) X_fake, y_fake = generate_fake_samples(g_model, latent_dim, n_batch) d_loss_f, d_acc_f = d_model.train_on_batch(X_fake, y_fake) z_input = generate_latent_points(latent_dim, n_batch) y_gan = ones((n_batch, 1)) g_loss, g_acc = gan_model.train_on_batch(z_input, y_gan) print('>%d, dr[%.3f,%.3f], df[%.3f,%.3f], g[%.3f,%.3f]' % (i+1, d_loss_r,d_acc_r, d_loss_f,d_acc_f, g_loss,g_acc)) if (i+1) % (bat_per_epo * 1) == 0: summarize_performance(i, g_model, latent_dim)
This function helps us to train the generator and the discriminator. To train the Discriminator, it first generates real samples, updates the discriminator’s weights, generates fake samples, and then updates the discriminator’s weights again. To train the Generator, it first generates latent points, generates labels as 1 to fool the discriminator, and then updates the generator’s weights. Finally, the function summarizes the performance of the model after some steps.
latent_dim = 100 train(generator, discriminator, gan_model, X_train, latent_dim, n_epochs=20, n_batch=64)
We are finally calling the train function with 100 random samples, 20 epochs, and 64 as batch size.
model = load_model('model_18740.h5') latent_dim = 100 n_examples = 100 latent_points = generate_latent_points(latent_dim, n_examples) X = model.predict(latent_points) X = (X + 1) / 2.0 save_plot(X, n_examples)
We are just loading the latest saved model, generating latent points, using the loaded model for prediction, and plotting the results.
The generated images aren’t quite clear, right? Because we haven’t used Convolution layers in our model. Try it on your own and see the results.
In this post, you have understood the GANs in detail.
Specifically, you learned:
Do you have any questions? Feel free to post your questions in the comments below. I would love to help you.
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