def train(net: NeuralNet,
inputs: Tensor,
targets: Tensor,
num_epochs: int = 5000,
iterator: DataIterator = BatchIterator(),
loss: Loss = MSE(),
optimizer: Optimizer = SGD()) -> None:
for epoch in range(num_epochs):
epoch_loss = 0.0
for batch in iterator(inputs, targets):
predicted = net.forward(batch.inputs)
epoch_loss += loss.loss(predicted, batch.targets)
grad = loss.grad(predicted, batch.targets)
net.backward(grad)
optimizer.step(net)
print(epoch, epoch_loss)
def train(net: NeuralNet,
inputs: Tensor,
targets: Tensor,
num_epochs: int = 5000,
iterator: DataIterator = BatchIterator(),
loss: Loss = MSE(),
optimizer: Optimizer = SGD(0.001),
eps: float = -1) -> [float]:
loss_list = []
eval_list = []
net.n_eval = 0
for epoch in range(num_epochs):
n_iter = 0
epoch_loss = 0.0
print(f'================ EPOCH NUMBER {epoch + 1} ================')
for batch in iterator(inputs, targets):
#print(f'batch: \n{batch}')
net.n_iter = n_iter
net.curr_batch = batch
net.loss_f = loss
predicted = net.forward(batch.inputs)
curr_loss = loss.loss(predicted, batch.targets)
epoch_loss += curr_loss
grad = loss.grad(predicted, batch.targets)
net.backward(grad)
optimizer.step(net)
n_iter = n_iter + 1
eval_list.append(net.n_eval)
#eval_list.append(net.n_eval)
# () / iterator.batch_size
print(epoch, epoch_loss)
loss_list.append(epoch_loss)
if eps > 0 and epoch_loss < eps:
print('precisão atingida')
break
return loss_list, eval_list
net = NeuralNet([
Linear(input_size=1, output_size=2, weights = np.array([[1.0,2.0]]), biases = np.array([0.0, 0.0])),
reLu(),
Linear(input_size=2, output_size=1, weights = np.array([[3.0],[4.0]]), biases = np.array([0.0])),
reLu()
])
n_epochs = 1000
#loss_list = train(net, inputs,targets, optimizer = Adam(lr = 1e-2, gamma1 = 0.3, gamma2 = 0.3),iterator = BatchIterator(batch_size = 5), num_epochs = 1000)
start_time = time.time()
loss_list = train(net, inputs,targets, loss = MSE() ,optimizer = SGD(1e-5), iterator = BatchIterator(batch_size = 5), num_epochs = n_epochs, eps = 2000)
end_time = time.time()
print(f'Tempo gasto no treinamento: {end_time - start_time}s')
# for x, y in zip(inputs, targets)
# predicted = net.forward(x)
# print(x, predicted, y)
#print(f'Levenberg Marquardt com busca linear\nloss = {loss_list[len(loss_list) - 1]:.2f}')
ex = np.linspace(0,20,200)
output_size=1,
weights=np.array([[3.0], [4.0]]),
biases=np.array([0.0]))
])
n_epochs = 2
eps = 1e-4
#loss_list = train(net, inputs,targets, optimizer = Adam(lr = 1e-2, gamma1 = 0.3, gamma2 = 0.3),iterator = BatchIterator(batch_size = 5), num_epochs = 1000)
loss_list, eval_list = train(net,
inputs,
targets,
loss=MSE(),
optimizer=LM_cond(float(sys.argv[1]),
float(sys.argv[2])),
iterator=BatchIterator(batch_size=len(inputs)),
num_epochs=n_epochs,
eps=eps)
# for x, y in zip(inputs, targets)
# predicted = net.forward(x)
# print(x, predicted, y)
ex = np.arange(0, 5, 0.2)
ey = []
test_loss = []
for val in ex:
predicted = net.forward([val])
ey.append(predicted)
#plt.scatter(range(0,len(loss_list)), loss_list)
Linear(input_size=30, output_size=24),
Tanh(),
Linear(input_size=24, output_size=30),
Tanh(),
Linear(input_size=30, output_size=35),
Tanh(),
Linear(input_size=35, output_size=1),
Sigmoid()
])
n_epochs = 200
loss_list = train(net,
inputs,
targets,
optimizer=Adam(lr=1e-2, gamma1=0.3, gamma2=0.4),
iterator=BatchIterator(128),
num_epochs=n_epochs)
y_pred = []
for x in X_test[0:1000]:
y_pred.append(net.forward(x))
y_pred = np.array(y_pred)
aux = X_test[0:1000]
indices_1 = np.where(aux == 0)
print('fraudes:', indices_1[0])
plt.title("Erro quadrático x Tempo")
plt.xlabel("número de iterações")
plt.ylabel("erro quadrático")
plt.scatter(list(range(0, n_epochs)), loss_list)
output_size=1,
weights=np.array([[3.0], [4.0]]),
biases=np.array([0.0]))
])
n_epochs = 1000
eps = 1e-3
#loss_list = train(net, inputs,targets, optimizer = Adam(lr = 1e-2, gamma1 = 0.3, gamma2 = 0.3),iterator = BatchIterator(batch_size = 5), num_epochs = 1000)
loss_list, eval_list = train(net,
inputs,
targets,
loss=MSE(),
optimizer=LM_cond(float(sys.argv[1]),
float(sys.argv[2])),
iterator=BatchIterator(batch_size=2),
num_epochs=n_epochs,
eps=eps)
# for x, y in zip(inputs, targets)
# predicted = net.forward(x)
# print(x, predicted, y)
ex = np.arange(0, 5, 0.2)
ey = []
test_loss = []
for val in ex:
predicted = net.forward([val])
ey.append(predicted)
#plt.scatter(range(0,len(loss_list)), loss_list)
biases=np.array([0.0])),
reLu()
])
n_epochs = 500
print('========= Método LM com busca linear =========')
print('treinando com 500 epochs')
print(f'alpha: {1e3:.1E}')
#loss_list = train(net, inputs,targets, optimizer = Adam(lr = 1e-2, gamma1 = 0.3, gamma2 = 0.3),iterator = BatchIterator(batch_size = 5), num_epochs = 1000)
start_time = time.time()
loss_list = train(net,
inputs,
targets,
loss=MSE(),
optimizer=LM_cond(1e3),
iterator=BatchIterator(batch_size=5),
num_epochs=n_epochs)
end_time = time.time()
print(f'Tempo gasto no treinamento: {end_time - start_time}s')
ex = np.linspace(0, 20, 200)
ey = []
test_loss = []
for val in ex:
predicted = net.forward([val])
ey.append(predicted)
plt.plot(
ex,
ey,
label=f'alpha = {1e3:.1E}\nloss = {loss_list[len(loss_list) - 1]:.02f}')
# net = NeuralNet([
# Linear(input_size=30, output_size=2),
# Tanh(),
# Linear(input_size=2, output_size=1),
# Sigmoid()
# ])
n_epochs = 20
#loss_list = train(net, inputs,targets, loss = MSE() ,optimizer = Adam(lr = 1e-2, gamma1 = 0.3, gamma2 = 0.3), iterator = BatchIterator(1024), num_epochs = n_epochs)
try:
loss_list = train(net,
inputs,
targets,
loss=MSE(),
optimizer=LM_cond(1e4, 1e2),
iterator=BatchIterator(len(inputs)),
num_epochs=n_epochs)
except np.linalg.LinAlgError as err:
print('Interrompido por matriz singular')
y_pred = []
for x in X_test:
y_pred.append(net.forward(x))
y_pred = np.array(y_pred)
plt.title("Erro quadrático x Tempo")
plt.xlabel("número de iterações")
plt.ylabel("erro quadrático")
plt.scatter(list(range(0, n_epochs)), loss_list)
plt.savefig(f'Figuras/Fraud/Adam_IMP.png', format='png')
plt.show()
Sigmoid()
])
# net = NeuralNet([
# Linear(input_size=30, output_size=2),
# Tanh(),
# Linear(input_size=2, output_size=1),
# Sigmoid()
# ])
n_epochs = 10
#loss_list = train(net, inputs,targets, loss = MSE() ,optimizer = Adam(lr = 1e-2, gamma1 = 0.3, gamma2 = 0.3), iterator = BatchIterator(1024), num_epochs = n_epochs)
try:
loss_list = train(net, inputs,targets, loss = MSE() ,optimizer = LM_cond(1e3,1e2), iterator = BatchIterator(len(inputs)), num_epochs = n_epochs)
except np.linalg.LinAlgError as err:
print('Interrompido por matriz singular')
y_pred = []
for x in X_test:
y_pred.append(net.forward(x))
y_pred = np.array(y_pred)
plt.title("Erro quadrático x Tempo")
plt.xlabel("número de iterações")
plt.ylabel("erro quadrático")
#plt.scatter(list(range(0, len(loss_list))),loss_list)
plt.scatter(list(range(0, len(loss_list))),loss_list)
plt.axis([0,len(loss_list),0,len(loss_list)])
targets = np.array([[0], [1], [1], [0]])
net = NeuralNet([
Linear(input_size=2, output_size=4),
Sigmoid(),
Linear(input_size=4, output_size=4),
Sigmoid(),
Linear(input_size=4, output_size=1),
Sigmoid()
])
n_epochs = 10000
loss_list = train(net,
inputs,
targets,
loss=Log_loss(),
optimizer=SGD(lr=1e-5),
iterator=BatchIterator(4),
num_epochs=n_epochs)
for x, y in zip(inputs, targets):
predicted = net.forward(x)
print(x, predicted, y)
plt.title("Erro quadrático x Tempo")
plt.xlabel("número de iterações")
plt.ylabel("erro quadrático")
plt.scatter(list(range(0, n_epochs)), loss_list)
plt.show()
