def main():
"""Main method"""
misc.to_local_dir(__file__)
misc.gen_dirs([data_dir, processed_dir, plot_dir, model_dir, results_dir])
# data = np.load(f"{processed_dir}/processed_data.npy")
np.set_printoptions(suppress=True)
data = processing(store=True, plot=False)
# Train/test split
# train_data, test_data = train_test_split(data, test_size=test_size, random_state=random_seed)
train_data = np.empty(
(np.shape(data)[0] - len(test_configs), np.shape(data)[1],
np.shape(data)[2]))
test_data = np.empty(
(len(test_configs), np.shape(data)[1], np.shape(data)[2]))
test_idx = 0
train_idx = 0
for config in test_configs:
for scenario in data:
if (scenario[0, 0] == config[0] and scenario[0, 1] == config[1]
and scenario[0, 2] == config[2]):
test_data[test_idx] = scenario
test_idx += 1
for scenario in data:
test_found = False
for config in test_configs:
if (scenario[0, 0] == config[0] and scenario[0, 1] == config[1]
and scenario[0, 2] == config[2]):
test_found = True
if not test_found:
train_data[train_idx] = scenario
train_idx += 1
# Flatten training data by one dimension but keep the shape of the testing data,
# to being able to test different FRFs separately
train_data = np.reshape(train_data, (-1, input_size + output_size))
# Scale data
x_scaler = MinMaxScaler()
train_data[:, :input_size] = x_scaler.fit_transform(
train_data[:, :input_size])
for test_idx, __ in enumerate(test_data):
test_data[test_idx, :, :input_size] = x_scaler.transform(
test_data[test_idx, :, :input_size])
hyperopts = training(train_data)
total_errors = np.empty((len(hyperopts), output_size))
total_variances = np.empty((len(hyperopts), output_size))
for hyper_idx, hyperopt in enumerate(hyperopts):
errors, variances = test_frf(hyperopt, test_data, x_scaler)
total_errors[hyper_idx] = errors
total_variances[hyper_idx] = variances
dump(
hyperopt, '{}/hyperopt_{}.joblib'.format(
model_dir, hyperopt[0].best_estimator_.__class__.__name__))
write_results(hyperopts, total_errors, total_variances)
def main():
"""Main method"""
misc.to_local_dir(__file__)
misc.gen_dirs([data_dir, processed_dir, plot_dir, results_dir])
# Definition of data and learning properties
np.set_printoptions(suppress=True)
# data = np.load(f"{processed_dir}/processed_osc.npy")
n_neighbors = range(10, 21)
if OSC:
train_data, test_data = train_test_osc()
best_score = 0
best_nbrs = 0
for local_nbrs in n_neighbors:
__, __, __, score = interpolate_osc(train_data, test_data,
local_nbrs)
if score > best_score:
best_score = score
best_nbrs = local_nbrs
freq_errors, gamma_errors, mass_errors, __ = interpolate_osc(
train_data, test_data, best_nbrs)
# print("Frequency error: {} +/- {}".format(np.mean(freq_errors), np.std(freq_errors)))
# print("Gamma error: {} +/- {}".format(np.mean(gamma_errors), np.std(gamma_errors)))
# print("Mass error: {} +/- {}".format(np.mean(mass_errors), np.std(mass_errors)))
print(r"{:.2f} \pm {:.2f} & {:.2f} \pm {:.2f} & {:.2f} \pm {:.2f}".
format(np.mean(freq_errors), np.std(freq_errors),
np.mean(gamma_errors), np.std(gamma_errors),
np.mean(mass_errors), np.std(mass_errors)))
else:
train_data, test_data = train_test_frf()
best_score = 0
best_nbrs = 0
for local_nbrs in n_neighbors:
__, __, score = interpolate_frf(train_data, test_data, local_nbrs)
if score > best_score:
best_score = score
best_nbrs = local_nbrs
errors, variances, __ = interpolate_frf(train_data, test_data,
best_nbrs)
print(
r"{:.2f} \pm {:.2f} & {:.2f} \pm {:.2f} & {:.2f} \pm {:.2f} & {:.2f} \pm {:.2f}"
.format(errors[0], variances[0], errors[1], variances[1],
errors[2], variances[2], errors[3], variances[3]))
):
test_found = True
if not test_found:
train_data[train_idx] = scenario
train_idx += 1
# Flatten training data by one dimension but keep the shape of the testing data,
# to being able to test different FRFs separately
train_data = np.reshape(train_data, (-1, input_size + output_size))
# Scale data
x_scaler = MinMaxScaler()
x_scaler.fit(train_data[:, :input_size])
freqs = np.arange(x_range[0], x_range[1], freq_steps_aggreg)
eval_data = np.empty((len(eval_configs), len(freqs), input_size))
for eval_idx, eval_config in enumerate(eval_configs):
eval_scenario = np.empty((len(freqs), input_size))
for freq_idx, freq in enumerate(freqs):
eval_scenario[freq_idx] = eval_config + [freq]
eval_data[eval_idx] = x_scaler.transform(eval_scenario)
model_names = [filename for filename in os.listdir(model_dir) if filename.endswith('.joblib')]
for filename in model_names:
hyperopt = load('{}/{}'.format(model_dir, filename))
eval_frf(hyperopt, eval_data, eval_configs)
if __name__ == '__main__':
misc.to_local_dir(__file__)
main()
def main():
"""Main method"""
misc.to_local_dir(__file__)
misc.gen_dirs([data_dir, plot_dir, model_dir, results_dir])
generate_data()
"""Main script"""
import os
import numpy as np
import misc
from generate_data import generate_data
from properties import (
data_dir,
plot_dir,
results_dir,
model_dir
)
def main():
"""Main method"""
misc.to_local_dir(__file__)
misc.gen_dirs([data_dir, plot_dir, model_dir, results_dir])
generate_data()
if __name__ == '__main__':
misc.to_local_dir('__file__')
main()
def main():
"""Main method"""
misc.to_local_dir(__file__)
misc.gen_dirs([data_dir, processed_dir, plot_dir, model_dir, results_dir])
# Definition of data and learning properties
np.set_printoptions(suppress=True)
# data = np.load(f"{processed_dir}/processed_osc.npy")
data = read_osc(store=True)
# Train/test split
# train_data, test_data = train_test_split(data, test_size=test_size, random_state=random_seed)
train_data = np.empty(
(np.shape(data)[0] - len(test_configs), np.shape(data)[1]))
test_data = np.empty((len(test_configs), np.shape(data)[1]))
test_idx = 0
train_idx = 0
for config in test_configs:
for row in data:
if row[0] == config[0] and row[1] == config[1] and row[
2] == config[2]:
test_data[test_idx] = row
test_idx += 1
for row in data:
test_found = False
for config in test_configs:
if row[0] == config[0] and row[1] == config[1] and row[
2] == config[2]:
test_found = True
if not test_found:
train_data[train_idx] = row
train_idx += 1
# import os
# import math
# from sklearn.metrics import mean_squared_error
# regre = ['ElasticNet', 'RandomForestRegressor', 'XGBRegressor']
# pred_dir = '{}/dmg_hsc75linear/osc_fitting_hypsrch300_predictions_2'.format(results_dir)
# for reg in regre:
# files = [
# filename for filename in os.listdir(pred_dir)
# if filename.startswith(reg)
# ]
# freq_errors = []
# gamma_errors = []
# mass_errors = []
# for config_idx, config in enumerate(test_configs):
# local_test = test_data[config_idx]
# local_pred_file = files[0]
# for idx in range(1, len(files)):
# file_config = os.path.splitext(files[idx])[0].split('_')[2:]
# if np.all([float(file_config[jdx]) == config[jdx] for jdx in range(len(config))]):
# local_pred_file = files[idx]
# local_pred = np.load('{}/{}'.format(pred_dir, local_pred_file))
# local_test = local_test[input_size:]
# freq_error = math.sqrt(mean_squared_error(local_test[::3], local_pred[::3]))
# gamma_error = math.sqrt(mean_squared_error(local_test[1::3], local_pred[1::3]))
# mass_error = math.sqrt(mean_squared_error(local_test[2::3], local_pred[2::3]))
# freq_errors.append(freq_error)
# gamma_errors.append(gamma_error)
# mass_errors.append(mass_error)
# print(reg)
# # print("Frequency error: {} +/- {}".format(np.mean(freq_errors), np.std(freq_errors)))
# # print("Gamma error: {} +/- {}".format(np.mean(gamma_errors), np.std(gamma_errors)))
# # print("Mass error: {} +/- {}".format(np.mean(mass_errors), np.std(mass_errors)))
# print(r"{:.2f} \pm {:.2f} & {:.2f} \pm {:.2f} & {:.2f} \pm {:.2f}".format(
# np.mean(freq_errors), np.std(freq_errors),
# np.mean(gamma_errors), np.std(gamma_errors),
# np.mean(mass_errors), np.std(mass_errors)
# ))
# quit()
# Scale data
x_scaler = MinMaxScaler()
train_data[:, :input_size] = x_scaler.fit_transform(
train_data[:, :input_size])
test_data[:, :input_size] = x_scaler.transform(test_data[:, :input_size])
hyperopts = training(train_data)
total_errors = np.empty((len(hyperopts), output_size))
total_variances = np.empty((len(hyperopts), output_size))
for hyper_idx, hyperopt in enumerate(hyperopts):
errors, variances = test_osc(hyperopt, test_data, test_configs)
total_errors[hyper_idx] = errors
total_variances[hyper_idx] = variances
dump(
hyperopt, '{}/hyperopt_{}.joblib'.format(
model_dir, hyperopt[0].best_estimator_.__class__.__name__))
write_results(hyperopts, total_errors, total_variances)
