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timegan.py
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timegan.py
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"""Time-series Generative Adversarial Networks (TimeGAN) Codebase.
Reference: Jinsung Yoon, Daniel Jarrett, Mihaela van der Schaar,
"Time-series Generative Adversarial Networks,"
Neural Information Processing Systems (NeurIPS), 2019.
Paper link: https://papers.nips.cc/paper/8789-time-series-generative-adversarial-networks
Last updated Date: April 24th 2020
Code author: Jinsung Yoon ([email protected])
-----------------------------
timegan.py
Note: Use original data as training set to generater synthetic data (time-series)
"""
# Necessary Packages
import tensorflow as tf
import numpy as np
from utils import extract_time, rnn_cell, random_generator, batch_generator
def timegan (ori_data, parameters):
"""TimeGAN function.
Use original data as training set to generater synthetic data (time-series)
Args:
- ori_data: original time-series data
- parameters: TimeGAN network parameters
Returns:
- generated_data: generated time-series data
"""
# Initialization on the Graph
tf.reset_default_graph()
# Basic Parameters
no, seq_len, dim = np.asarray(ori_data).shape
# Maximum sequence length and each sequence length
ori_time, max_seq_len = extract_time(ori_data)
def MinMaxScaler(data):
"""Min-Max Normalizer.
Args:
- data: raw data
Returns:
- norm_data: normalized data
- min_val: minimum values (for renormalization)
- max_val: maximum values (for renormalization)
"""
min_val = np.min(np.min(data, axis = 0), axis = 0)
data = data - min_val
max_val = np.max(np.max(data, axis = 0), axis = 0)
norm_data = data / (max_val + 1e-7)
return norm_data, min_val, max_val
# Normalization
ori_data, min_val, max_val = MinMaxScaler(ori_data)
## Build a RNN networks
# Network Parameters
hidden_dim = parameters['hidden_dim']
num_layers = parameters['num_layer']
iterations = parameters['iterations']
batch_size = parameters['batch_size']
module_name = parameters['module']
z_dim = dim
gamma = 1
# Input place holders
X = tf.placeholder(tf.float32, [None, max_seq_len, dim], name = "myinput_x")
Z = tf.placeholder(tf.float32, [None, max_seq_len, z_dim], name = "myinput_z")
T = tf.placeholder(tf.int32, [None], name = "myinput_t")
def embedder (X, T):
"""Embedding network between original feature space to latent space.
Args:
- X: input time-series features
- T: input time information
Returns:
- H: embeddings
"""
with tf.variable_scope("embedder", reuse = tf.AUTO_REUSE):
e_cell = tf.nn.rnn_cell.MultiRNNCell([rnn_cell(module_name, hidden_dim) for _ in range(num_layers)])
e_outputs, e_last_states = tf.nn.dynamic_rnn(e_cell, X, dtype=tf.float32, sequence_length = T)
H = tf.contrib.layers.fully_connected(e_outputs, hidden_dim, activation_fn=tf.nn.sigmoid)
return H
def recovery (H, T):
"""Recovery network from latent space to original space.
Args:
- H: latent representation
- T: input time information
Returns:
- X_tilde: recovered data
"""
with tf.variable_scope("recovery", reuse = tf.AUTO_REUSE):
r_cell = tf.nn.rnn_cell.MultiRNNCell([rnn_cell(module_name, hidden_dim) for _ in range(num_layers)])
r_outputs, r_last_states = tf.nn.dynamic_rnn(r_cell, H, dtype=tf.float32, sequence_length = T)
X_tilde = tf.contrib.layers.fully_connected(r_outputs, dim, activation_fn=tf.nn.sigmoid)
return X_tilde
def generator (Z, T):
"""Generator function: Generate time-series data in latent space.
Args:
- Z: random variables
- T: input time information
Returns:
- E: generated embedding
"""
with tf.variable_scope("generator", reuse = tf.AUTO_REUSE):
e_cell = tf.nn.rnn_cell.MultiRNNCell([rnn_cell(module_name, hidden_dim) for _ in range(num_layers)])
e_outputs, e_last_states = tf.nn.dynamic_rnn(e_cell, Z, dtype=tf.float32, sequence_length = T)
E = tf.contrib.layers.fully_connected(e_outputs, hidden_dim, activation_fn=tf.nn.sigmoid)
return E
def supervisor (H, T):
"""Generate next sequence using the previous sequence.
Args:
- H: latent representation
- T: input time information
Returns:
- S: generated sequence based on the latent representations generated by the generator
"""
with tf.variable_scope("supervisor", reuse = tf.AUTO_REUSE):
e_cell = tf.nn.rnn_cell.MultiRNNCell([rnn_cell(module_name, hidden_dim) for _ in range(num_layers-1)])
e_outputs, e_last_states = tf.nn.dynamic_rnn(e_cell, H, dtype=tf.float32, sequence_length = T)
S = tf.contrib.layers.fully_connected(e_outputs, hidden_dim, activation_fn=tf.nn.sigmoid)
return S
def discriminator (H, T):
"""Discriminate the original and synthetic time-series data.
Args:
- H: latent representation
- T: input time information
Returns:
- Y_hat: classification results between original and synthetic time-series
"""
with tf.variable_scope("discriminator", reuse = tf.AUTO_REUSE):
d_cell = tf.nn.rnn_cell.MultiRNNCell([rnn_cell(module_name, hidden_dim) for _ in range(num_layers)])
d_outputs, d_last_states = tf.nn.dynamic_rnn(d_cell, H, dtype=tf.float32, sequence_length = T)
Y_hat = tf.contrib.layers.fully_connected(d_outputs, 1, activation_fn=None)
return Y_hat
# Embedder & Recovery
H = embedder(X, T)
X_tilde = recovery(H, T)
# Generator
E_hat = generator(Z, T)
H_hat = supervisor(E_hat, T)
H_hat_supervise = supervisor(H, T)
# Synthetic data
X_hat = recovery(H_hat, T)
# Discriminator
Y_fake = discriminator(H_hat, T)
Y_real = discriminator(H, T)
Y_fake_e = discriminator(E_hat, T)
# Variables
e_vars = [v for v in tf.trainable_variables() if v.name.startswith('embedder')]
r_vars = [v for v in tf.trainable_variables() if v.name.startswith('recovery')]
g_vars = [v for v in tf.trainable_variables() if v.name.startswith('generator')]
s_vars = [v for v in tf.trainable_variables() if v.name.startswith('supervisor')]
d_vars = [v for v in tf.trainable_variables() if v.name.startswith('discriminator')]
# Discriminator loss
D_loss_real = tf.losses.sigmoid_cross_entropy(tf.ones_like(Y_real), Y_real)
D_loss_fake = tf.losses.sigmoid_cross_entropy(tf.zeros_like(Y_fake), Y_fake)
D_loss_fake_e = tf.losses.sigmoid_cross_entropy(tf.zeros_like(Y_fake_e), Y_fake_e)
D_loss = D_loss_real + D_loss_fake + gamma * D_loss_fake_e
# Generator loss
# 1. Adversarial loss
G_loss_U = tf.losses.sigmoid_cross_entropy(tf.ones_like(Y_fake), Y_fake)
G_loss_U_e = tf.losses.sigmoid_cross_entropy(tf.ones_like(Y_fake_e), Y_fake_e)
# 2. Supervised loss
G_loss_S = tf.losses.mean_squared_error(H[:,1:,:], H_hat_supervise[:,:-1,:])
# 3. Two Momments
G_loss_V1 = tf.reduce_mean(tf.abs(tf.sqrt(tf.nn.moments(X_hat,[0])[1] + 1e-6) - tf.sqrt(tf.nn.moments(X,[0])[1] + 1e-6)))
G_loss_V2 = tf.reduce_mean(tf.abs((tf.nn.moments(X_hat,[0])[0]) - (tf.nn.moments(X,[0])[0])))
G_loss_V = G_loss_V1 + G_loss_V2
# 4. Summation
G_loss = G_loss_U + gamma * G_loss_U_e + 100 * tf.sqrt(G_loss_S) + 100*G_loss_V
# Embedder network loss
E_loss_T0 = tf.losses.mean_squared_error(X, X_tilde)
E_loss0 = 10*tf.sqrt(E_loss_T0)
E_loss = E_loss0 + 0.1*G_loss_S
# optimizer
E0_solver = tf.train.AdamOptimizer().minimize(E_loss0, var_list = e_vars + r_vars)
E_solver = tf.train.AdamOptimizer().minimize(E_loss, var_list = e_vars + r_vars)
D_solver = tf.train.AdamOptimizer().minimize(D_loss, var_list = d_vars)
G_solver = tf.train.AdamOptimizer().minimize(G_loss, var_list = g_vars + s_vars)
GS_solver = tf.train.AdamOptimizer().minimize(G_loss_S, var_list = g_vars + s_vars)
## TimeGAN training
sess = tf.Session()
sess.run(tf.global_variables_initializer())
# 1. Embedding network training
print('Start Embedding Network Training')
for itt in range(iterations):
# Set mini-batch
X_mb, T_mb = batch_generator(ori_data, ori_time, batch_size)
# Train embedder
_, step_e_loss = sess.run([E0_solver, E_loss_T0], feed_dict={X: X_mb, T: T_mb})
# Checkpoint
if itt % 1000 == 0:
print('step: '+ str(itt) + '/' + str(iterations) + ', e_loss: ' + str(np.round(np.sqrt(step_e_loss),4)) )
print('Finish Embedding Network Training')
# 2. Training only with supervised loss
print('Start Training with Supervised Loss Only')
for itt in range(iterations):
# Set mini-batch
X_mb, T_mb = batch_generator(ori_data, ori_time, batch_size)
# Random vector generation
Z_mb = random_generator(batch_size, z_dim, T_mb, max_seq_len)
# Train generator
_, step_g_loss_s = sess.run([GS_solver, G_loss_S], feed_dict={Z: Z_mb, X: X_mb, T: T_mb})
# Checkpoint
if itt % 1000 == 0:
print('step: '+ str(itt) + '/' + str(iterations) +', s_loss: ' + str(np.round(np.sqrt(step_g_loss_s),4)) )
print('Finish Training with Supervised Loss Only')
# 3. Joint Training
print('Start Joint Training')
for itt in range(iterations):
# Generator training (twice more than discriminator training)
for kk in range(2):
# Set mini-batch
X_mb, T_mb = batch_generator(ori_data, ori_time, batch_size)
# Random vector generation
Z_mb = random_generator(batch_size, z_dim, T_mb, max_seq_len)
# Train generator
_, step_g_loss_u, step_g_loss_s, step_g_loss_v = sess.run([G_solver, G_loss_U, G_loss_S, G_loss_V], feed_dict={Z: Z_mb, X: X_mb, T: T_mb})
# Train embedder
_, step_e_loss_t0 = sess.run([E_solver, E_loss_T0], feed_dict={Z: Z_mb, X: X_mb, T: T_mb})
# Discriminator training
# Set mini-batch
X_mb, T_mb = batch_generator(ori_data, ori_time, batch_size)
# Random vector generation
Z_mb = random_generator(batch_size, z_dim, T_mb, max_seq_len)
# Check discriminator loss before updating
check_d_loss = sess.run(D_loss, feed_dict={X: X_mb, T: T_mb, Z: Z_mb})
# Train discriminator (only when the discriminator does not work well)
if (check_d_loss > 0.15):
_, step_d_loss = sess.run([D_solver, D_loss], feed_dict={X: X_mb, T: T_mb, Z: Z_mb})
# Print multiple checkpoints
if itt % 1000 == 0:
print('step: '+ str(itt) + '/' + str(iterations) +
', d_loss: ' + str(np.round(step_d_loss,4)) +
', g_loss_u: ' + str(np.round(step_g_loss_u,4)) +
', g_loss_s: ' + str(np.round(np.sqrt(step_g_loss_s),4)) +
', g_loss_v: ' + str(np.round(step_g_loss_v,4)) +
', e_loss_t0: ' + str(np.round(np.sqrt(step_e_loss_t0),4)) )
print('Finish Joint Training')
## Synthetic data generation
Z_mb = random_generator(no, z_dim, ori_time, max_seq_len)
generated_data_curr = sess.run(X_hat, feed_dict={Z: Z_mb, X: ori_data, T: ori_time})
generated_data = list()
for i in range(no):
temp = generated_data_curr[i,:ori_time[i],:]
generated_data.append(temp)
# Renormalization
generated_data = generated_data * max_val
generated_data = generated_data + min_val
return generated_data