Spaces:

aim4composites
/

Injection_Molding_Design

Sleeping

Injection_Molding_Design / main_injection.py

Rui Wan

upload model

6977ea8 3 months ago

9 kB

	import torch
	import numpy as np
	import matplotlib.pyplot as plt
	from Dataset import Dataset
	from model import NeuralNetwork

	DEVICE = torch.device('cuda' if torch.cuda.is_available() else 'cpu')
	# Set global plotting parameters
	plt.rcParams.update({'font.size': 14,
	'figure.figsize': (10, 8),
	'lines.linewidth': 2,
	'lines.markersize': 6,
	'axes.grid': True,
	'axes.labelsize': 16,
	'legend.fontsize': 14,
	'xtick.labelsize': 14,
	'ytick.labelsize': 14,
	'figure.autolayout': True
	})

	def set_seed(seed=42):
	np.random.seed(seed)
	torch.manual_seed(seed)
	if torch.cuda.is_available():
	torch.cuda.manual_seed_all(seed)

	def train_neural_network(model, inputs, outputs, optimizer, epochs=1000, lr_scheduler=None):
	model.train()
	for epoch in range(epochs):
	optimizer.zero_grad()
	predictions = model(inputs)
	loss = torch.mean(torch.square(predictions - outputs))
	loss.backward()
	optimizer.step()

	if lr_scheduler:
	lr_scheduler.step()

	if epoch % 100 == 0:
	print(f'Epoch {epoch}, Loss: {loss.item()}, Learning Rate: {optimizer.param_groups[0]["lr"]}')

	def main():
	set_seed(42)
	dataset = Dataset(mat_name='FRP')
	# Load raw data; normalize using train-only statistics to avoid leakage.
	inputs = dataset.get_input(normalize=False)
	outputs = dataset.get_output(normalize=False)

	# Train/val/test split for early stopping and unbiased test.
	n = len(inputs)
	perm = np.random.permutation(n)
	n_train = int(0.8 * n)
	n_val = int(0.1 * n)
	idx_train = perm[:n_train]
	idx_val = perm[n_train:n_train + n_val]
	idx_test = perm[n_train + n_val:]

	# Fit normalization on train split only.
	input_mean = inputs[idx_train].mean(axis=0)
	input_std = inputs[idx_train].std(axis=0) + 1e-8
	output_mean = outputs[idx_train].mean(axis=0)
	output_std = outputs[idx_train].std(axis=0) + 1e-8

	inputs_norm = (inputs - input_mean) / input_std
	outputs_norm = (outputs - output_mean) / output_std

	inputs_train = torch.tensor(inputs_norm[idx_train], dtype=torch.float32).to(DEVICE)
	outputs_train = torch.tensor(outputs_norm[idx_train], dtype=torch.float32).to(DEVICE)

	inputs_val = torch.tensor(inputs_norm[idx_val], dtype=torch.float32).to(DEVICE)
	outputs_val = torch.tensor(outputs_norm[idx_val], dtype=torch.float32).to(DEVICE)

	inputs_test = torch.tensor(inputs_norm[idx_test], dtype=torch.float32).to(DEVICE)
	outputs_test = torch.tensor(outputs_norm[idx_test], dtype=torch.float32).to(DEVICE)

	# Linear regression baseline on normalized data.
	X_train = np.concatenate([inputs_norm[idx_train], np.ones((len(idx_train), 1), dtype=np.float32)], axis=1)
	Y_train = outputs_norm[idx_train]
	coef, _, _, _ = np.linalg.lstsq(X_train, Y_train, rcond=None)

	def linear_predict(x_norm):
	X = np.concatenate([x_norm, np.ones((len(x_norm), 1), dtype=np.float32)], axis=1)
	return X @ coef

	val_pred_lr = linear_predict(inputs_norm[idx_val])
	test_pred_lr = linear_predict(inputs_norm[idx_test])
	val_mse_lr = np.mean((val_pred_lr - outputs_norm[idx_val]) ** 2)
	test_mse_lr = np.mean((test_pred_lr - outputs_norm[idx_test]) ** 2)
	print(f'Linear baseline - Val Loss: {val_mse_lr:.6f}, Test Loss: {test_mse_lr:.6f}')

	# Smaller model to reduce overfitting on small data.
	layer_sizes = [inputs.shape[1]] + [32] * 2 + [outputs.shape[1]]
	dropout_rate = 0.2
	model = NeuralNetwork(layer_sizes, dropout_rate=dropout_rate, activation=torch.nn.ReLU).to(DEVICE)
	optimizer = torch.optim.Adam(model.parameters(), lr=0.001, weight_decay=1e-4)
	lr_scheduler = torch.optim.lr_scheduler.StepLR(optimizer, step_size=5000, gamma=0.9)

	# Create a proper dataset that keeps input-output pairs together
	train_dataset = torch.utils.data.TensorDataset(inputs_train, outputs_train)
	train_loader = torch.utils.data.DataLoader(train_dataset, batch_size=32, shuffle=True)

	# Train the model
	epochs = 10000
	best_val = float('inf')
	best_state = None
	patience = 800
	patience_left = patience
	for epoch in range(epochs):
	model.train()
	for inputs_batch, outputs_batch in train_loader:
	inputs_batch = inputs_batch.to(DEVICE)
	outputs_batch = outputs_batch.to(DEVICE)
	optimizer.zero_grad()
	predictions = model(inputs_batch)
	loss = torch.mean(torch.square(predictions - outputs_batch))
	loss.backward()
	optimizer.step()

	if lr_scheduler:
	lr_scheduler.step()

	if epoch % 500 == 0:
	model.eval()
	with torch.no_grad():
	train_pred = model(inputs_train)
	train_loss = torch.mean(torch.square(train_pred - outputs_train))
	val_pred = model(inputs_val)
	val_loss = torch.mean(torch.square(val_pred - outputs_val))
	print(f'Epoch {epoch}, Train Loss: {train_loss.item():.6f}, Val Loss: {val_loss.item():.6f}')

	# Early stopping on validation loss (checked every epoch).
	model.eval()
	with torch.no_grad():
	val_pred = model(inputs_val)
	val_loss = torch.mean(torch.square(val_pred - outputs_val))
	if val_loss.item() < best_val - 1e-5:
	best_val = val_loss.item()
	best_state = {k: v.clone() for k, v in model.state_dict().items()}
	patience_left = patience
	else:
	patience_left -= 1
	if patience_left <= 0:
	print(f'Early stopping at epoch {epoch}. Best val loss: {best_val:.6f}')
	break

	if best_state is not None:
	model.load_state_dict(best_state)


	# MC Dropout inference for predictive mean/uncertainty.
	def mc_dropout_predict(model, x, n_samples=50):
	model.train() # keep dropout active
	preds = []
	with torch.no_grad():
	for _ in range(n_samples):
	preds.append(model(x).unsqueeze(0))
	preds = torch.cat(preds, dim=0)
	return preds.mean(dim=0), preds.std(dim=0)

	predictions, pred_std = mc_dropout_predict(model, inputs_test, n_samples=50)
	test_loss = torch.mean(torch.square(predictions - outputs_test))
	print(f'Test Loss: {test_loss.item()}. Samples: {idx_test}')

	x = np.arange(0, len(idx_test))

	outputs_test = outputs_test.cpu().numpy() * output_std + output_mean
	predictions = predictions.cpu().numpy() * output_std + output_mean
	pred_std = pred_std.cpu().numpy() * output_std
	print(f'Predictive STD (A, B, C): {pred_std.mean(axis=0)}')

	plt.figure(figsize=(10, 6))
	plt.plot(x, outputs_test[:, 0], color='b', linestyle='--', label='True A')
	plt.plot(x, predictions[:, 0], color='b', linestyle='-', label='Predicted A')
	plt.plot(x, outputs_test[:, 1], color='r', linestyle='--', label='True B')
	plt.plot(x, predictions[:, 1], color='r', linestyle='-', label='Predicted B')
	plt.plot(x, outputs_test[:, 2], color='g', linestyle='--', label='True C')
	plt.plot(x, predictions[:, 2], color='g', linestyle='-', label='Predicted C')
	plt.gca().xaxis.set_major_locator(plt.MaxNLocator(integer=True))
	plt.xlabel('Sample Index')
	plt.xticks(ticks=range(len(idx_test)),labels=idx_test + 1)
	plt.ylabel('Angle (Degrees)')
	plt.title('Angle Prediction')
	plt.legend(loc='upper right')
	plt.savefig('angle_prediction.png')


	# MSE
	mse = np.mean((predictions - outputs_test) ** 2, axis=0)
	print(f'Mean Squared Error for A: {mse[0]:.6f}, B: {mse[1]:.6f}, C: {mse[2]:.6f}')

	# R 2 score
	ss_ress = np.sum((outputs_test - predictions) ** 2, axis=0)
	ss_tots = np.sum((outputs_test - np.mean(outputs_test, axis=0)) ** 2, axis=0)
	r2_scores = 1 - ss_ress / ss_tots
	print(f'R² Score for A: {r2_scores[0]:.6f}, B: {r2_scores[1]:.6f}, C: {r2_scores[2]:.6f}')

	# Error

	# Save the model
	model_save_path = './model_checkpoint.pth'
	model_config = {'layer_sizes': layer_sizes,
	'dropout_rate': dropout_rate
	}
	checkpoint = {
	'model_state_dict': model.state_dict(),
	'model_config': model_config
	}
	torch.save(checkpoint, model_save_path)

	def load_model(model_path):
	checkpoint = torch.load(model_path)
	model_config = checkpoint['model_config']
	model = NeuralNetwork(model_config['layer_sizes'], dropout_rate=model_config['dropout_rate'], activation=torch.nn.ReLU).to(DEVICE)
	model.load_state_dict(checkpoint['model_state_dict'])
	print(f"Model loaded from {model_path}")
	return model


	if __name__ == "__main__":
	main()

	# model = load_model('./model_checkpoint.pth').to(torch.device('cpu'))