tomthetrainer/network.py

## network.py
from math import sqrt
from numpy import concatenate
#from matplotlib import pyplot
from pandas import read_csv
from pandas import DataFrame
from pandas import concat
from sklearn.preprocessing import MinMaxScaler
from sklearn.preprocessing import LabelEncoder
from sklearn.metrics import mean_squared_error
from keras.models import Sequential
from keras.layers import Dense
from keras.layers import LSTM

# convert series to supervised learning
def series_to_supervised(data, n_in=1, n_out=1, dropnan=True):
	n_vars = 1 if type(data) is list else data.shape[1]
	df = DataFrame(data)
	cols, names = list(), list()
	# input sequence (t-n, ... t-1)
	for i in range(n_in, 0, -1):
		cols.append(df.shift(i))
		names += [('var%d(t-%d)' % (j+1, i)) for j in range(n_vars)]
	# forecast sequence (t, t+1, ... t+n)
	for i in range(0, n_out):
		cols.append(df.shift(-i))
		if i == 0:
			names += [('var%d(t)' % (j+1)) for j in range(n_vars)]
		else:
			names += [('var%d(t+%d)' % (j+1, i)) for j in range(n_vars)]
	# put it all together
	agg = concat(cols, axis=1)
	agg.columns = names
	# drop rows with NaN values
	if dropnan:
		agg.dropna(inplace=True)
	return agg

# load dataset
dataset = read_csv('pollution.csv', header=0, index_col=0)
values = dataset.values
# integer encode direction
encoder = LabelEncoder()
values[:,4] = encoder.fit_transform(values[:,4])
# ensure all data is float
values = values.astype('float32')
# normalize features
scaler = MinMaxScaler(feature_range=(0, 1))
scaled = scaler.fit_transform(values)
# frame as supervised learning
reframed = series_to_supervised(scaled, 1, 1)
# drop columns we don't want to predict
reframed.drop(reframed.columns[[9,10,11,12,13,14,15]], axis=1, inplace=True)
print(reframed.head())

# split into train and test sets
values = reframed.values
n_train_hours = 365 * 24
train = values[:n_train_hours, :]
test = values[n_train_hours:, :]
# split into input and outputs
train_X, train_y = train[:, :-1], train[:, -1]
test_X, test_y = test[:, :-1], test[:, -1]
# reshape input to be 3D [samples, timesteps, features]
train_X = train_X.reshape((train_X.shape[0], 1, train_X.shape[1]))
test_X = test_X.reshape((test_X.shape[0], 1, test_X.shape[1]))
print(train_X.shape, train_y.shape, test_X.shape, test_y.shape)

# design network
model = Sequential()
model.add(LSTM(50, input_shape=(train_X.shape[1], train_X.shape[2])))
model.add(Dense(1))
model.compile(loss='mae', optimizer='adam')
# fit network
history = model.fit(train_X, train_y, nb_epoch=5, batch_size=72, validation_data=(test_X, test_y), verbose=2, shuffle=False)
# plot history
#pyplot.plot(history.history['loss'], label='train')
#pyplot.plot(history.history['val_loss'], label='test')
#pyplot.legend()
#pyplot.show()

# make a prediction
yhat = model.predict(test_X)
test_X = test_X.reshape((test_X.shape[0], test_X.shape[2]))
# invert scaling for forecast
inv_yhat = concatenate((yhat, test_X[:, 1:]), axis=1)
inv_yhat = scaler.inverse_transform(inv_yhat)
inv_yhat = inv_yhat[:,0]
# invert scaling for actual
test_y = test_y.reshape((len(test_y), 1))
inv_y = concatenate((test_y, test_X[:, 1:]), axis=1)
inv_y = scaler.inverse_transform(inv_y)
inv_y = inv_y[:,0]
# calculate RMSE
rmse = sqrt(mean_squared_error(inv_y, inv_yhat))
print('Test RMSE: %.3f' % rmse)
#model.save('pollution.h5')
print('#####INPUT#######')
print(test_X)
print('#####OUTPUT#######')
print(yhat)
print('#####Scaled Input #######')
print(inv_y)
print('#####Scaled Forecast #######')
print(inv_yhat)
	from math import sqrt
	from numpy import concatenate
	#from matplotlib import pyplot
	from pandas import read_csv
	from pandas import DataFrame
	from pandas import concat
	from sklearn.preprocessing import MinMaxScaler
	from sklearn.preprocessing import LabelEncoder
	from sklearn.metrics import mean_squared_error
	from keras.models import Sequential
	from keras.layers import Dense
	from keras.layers import LSTM

	# convert series to supervised learning
	def series_to_supervised(data, n_in=1, n_out=1, dropnan=True):
	n_vars = 1 if type(data) is list else data.shape[1]
	df = DataFrame(data)
	cols, names = list(), list()
	# input sequence (t-n, ... t-1)
	for i in range(n_in, 0, -1):
	cols.append(df.shift(i))
	names += [('var%d(t-%d)' % (j+1, i)) for j in range(n_vars)]
	# forecast sequence (t, t+1, ... t+n)
	for i in range(0, n_out):
	cols.append(df.shift(-i))
	if i == 0:
	names += [('var%d(t)' % (j+1)) for j in range(n_vars)]
	else:
	names += [('var%d(t+%d)' % (j+1, i)) for j in range(n_vars)]
	# put it all together
	agg = concat(cols, axis=1)
	agg.columns = names
	# drop rows with NaN values
	if dropnan:
	agg.dropna(inplace=True)
	return agg

	# load dataset
	dataset = read_csv('pollution.csv', header=0, index_col=0)
	values = dataset.values
	# integer encode direction
	encoder = LabelEncoder()
	values[:,4] = encoder.fit_transform(values[:,4])
	# ensure all data is float
	values = values.astype('float32')
	# normalize features
	scaler = MinMaxScaler(feature_range=(0, 1))
	scaled = scaler.fit_transform(values)
	# frame as supervised learning
	reframed = series_to_supervised(scaled, 1, 1)
	# drop columns we don't want to predict
	reframed.drop(reframed.columns[[9,10,11,12,13,14,15]], axis=1, inplace=True)
	print(reframed.head())

	# split into train and test sets
	values = reframed.values
	n_train_hours = 365 * 24
	train = values[:n_train_hours, :]
	test = values[n_train_hours:, :]
	# split into input and outputs
	train_X, train_y = train[:, :-1], train[:, -1]
	test_X, test_y = test[:, :-1], test[:, -1]
	# reshape input to be 3D [samples, timesteps, features]
	train_X = train_X.reshape((train_X.shape[0], 1, train_X.shape[1]))
	test_X = test_X.reshape((test_X.shape[0], 1, test_X.shape[1]))
	print(train_X.shape, train_y.shape, test_X.shape, test_y.shape)

	# design network
	model = Sequential()
	model.add(LSTM(50, input_shape=(train_X.shape[1], train_X.shape[2])))
	model.add(Dense(1))
	model.compile(loss='mae', optimizer='adam')
	# fit network
	history = model.fit(train_X, train_y, nb_epoch=5, batch_size=72, validation_data=(test_X, test_y), verbose=2, shuffle=False)
	# plot history
	#pyplot.plot(history.history['loss'], label='train')
	#pyplot.plot(history.history['val_loss'], label='test')
	#pyplot.legend()
	#pyplot.show()

	# make a prediction
	yhat = model.predict(test_X)
	test_X = test_X.reshape((test_X.shape[0], test_X.shape[2]))
	# invert scaling for forecast
	inv_yhat = concatenate((yhat, test_X[:, 1:]), axis=1)
	inv_yhat = scaler.inverse_transform(inv_yhat)
	inv_yhat = inv_yhat[:,0]
	# invert scaling for actual
	test_y = test_y.reshape((len(test_y), 1))
	inv_y = concatenate((test_y, test_X[:, 1:]), axis=1)
	inv_y = scaler.inverse_transform(inv_y)
	inv_y = inv_y[:,0]
	# calculate RMSE
	rmse = sqrt(mean_squared_error(inv_y, inv_yhat))
	print('Test RMSE: %.3f' % rmse)
	#model.save('pollution.h5')
	print('#####INPUT#######')
	print(test_X)
	print('#####OUTPUT#######')
	print(yhat)
	print('#####Scaled Input #######')
	print(inv_y)
	print('#####Scaled Forecast #######')
	print(inv_yhat)