def main(input_train, input_test, correct_train_orig, correct_test_orig,
train_data_name, test_data_name):
# input_train, correct_train: numpy.array
# input_test, correct_test: list 要素はnumpy.arary
n_train = len(input_train) # 学習データの数
n_test = len(input_test[0]) # テストデータの数
# 正解データをone-hot表現に
correct_train = np.zeros((n_train, len(chars))) # 2000x20
correct_test = [
np.zeros((n_test, len(chars))) for i in range(len(input_test))
] # 2000x20がlen(input_test)個
for i in range(n_train):
correct_train[i, correct_train_orig[i]] = 1
for i in range(len(input_test)):
for j in range(n_test):
correct_test[i][j, correct_test_orig[i][j]] = 1
# 各層の初期化
middle_layer = MiddleLayer(n_input, n_middle, eta, alpha)
output_layer = OutputLayer(n_middle, n_output, eta, alpha)
# ネットワークの初期化
net = NeuralNetwork([middle_layer, output_layer])
# 誤差の記録
train_error_x = []
train_error_y = []
test_error_x = []
test_error_y = [[] for i in range(len(input_test))]
n_batch = n_train // batch_size # 1epochあたりのバッチ数
for i in range(epoch):
# 誤差の計算
net.forward_prop(input_train) # 順伝播
error_train = net.cross_entropy(correct_train,
n_train) # クロスエントロピー誤差の計算
error_test = []
for j in range(len(input_test)):
net.forward_prop(input_test[j]) # 順伝播
error_test.append(net.cross_entropy(correct_test[j],
n_test)) # クロスエントロピー誤差の計算
# 誤差の記録
train_error_x.append(i)
train_error_y.append(error_train)
test_error_x.append(i)
for j in range(len(input_test)):
test_error_y[j].append(error_test[j])
# 学習経過
if i % interval == 0:
print("Epoch: {}".format(i))
# クロスエントロピー誤差表示
print("Error_train({}): {}".format(train_data_name, error_train))
for j in range(len(input_test)):
print("Error_test({}): {}".format(test_data_name[j],
error_test[j]))
# 正答率表示
print("Accuracy_train({}): {}".format(
train_data_name, net.accuracy(input_train, correct_train)))
for j in range(len(input_test)):
print("Accuracy_test({}): {}".format(
test_data_name[j],
net.accuracy(input_test[j], correct_test[j])))
print("=" * 50)
# 学習
index_random = np.arange(n_train)
np.random.shuffle(index_random)
for j in range(n_batch):
# ミニバッチ作成
mb_index = index_random[j * batch_size:(j + 1) * batch_size]
input_ = input_train[mb_index, :] # 入力
correct = correct_train[mb_index, :] # 正解
net.forward_prop(input_) # 順伝播
net.back_prop(correct) # 逆伝播
net.update_wb() # 重みとバイアスの更新
# 結果の保存
make_dir(os.getcwd() + os.sep + "result")
graph_name = os.path.join(os.getcwd(), "result", "error.png")
save_error_graph(train_error_x, train_error_y, test_error_x, test_error_y,
train_data_name, test_data_name, graph_name)
# グラフの表示
if show_error_graph:
img = cv2.imread(graph_name)
cv2.imshow(graph_name.split("/")[-1], img)
cv2.waitKey(0)
cv2.destroyAllWindows()
# 正答率をファイルに書き込む
if write_accuracy:
now = datetime.datetime.now()
file_name = "accuracy_" + now.strftime("%Y-%m-%d_%H-%M-%S") + ".txt"
make_dir(os.getcwd() + os.sep + "result")
with open(os.path.join("result", file_name), mode="w") as f:
# 訓練データの正答率書き込み
f.write("{}: {}\n".format(train_data_name,
net.accuracy(input_train,
correct_train)))
# テストデータの正答率書き込み
for j in range(len(input_test)):
f.write("{}: {}\n".format(
test_data_name[j],
net.accuracy(input_test[j], correct_test[j])))
# 任意の文字「あ」を入力した時の出力層の各ユニットの出力値をファイルに書き込む
if write_accuracy:
input_ = input_train[0] # 一番初めの「あ」を取り出す
input_ = input_.reshape((1, input_.shape[0])) # 行列に変換
net.forward_prop(input_)
make_dir(os.getcwd() + os.sep + "result")
# 書き込み
with open(os.path.join("result", "output.txt"), mode="w") as f:
output_result = ""
for i, p in enumerate(net.output[0]):
f.write("{}: {}\n".format(i, p))
if __name__ == "__main__":
camera1 = Camera(plt.figure())
plt.ylim(0, 0.45)
x = np.linspace(-50, 50, 26)
y = x**2
y = y / np.linalg.norm(y)
plt.yticks(y, "")
x = x.reshape((-1, 1))
x = np.c_[x, np.ones(len(x))]
nn = NeuralNetwork(x, y, layer_size=10, layer1='sigmoid', layer2='sigmoid')
print("Training with sigmoid")
for i in range(80001):
nn.feed_forward()
nn.back_prop()
if i % 200 == 0:
points = np.c_[np.linspace(-50, 50, 26), nn.output].T
plt.scatter(*points, c="black")
plt.text(-52.,
0.45,
'Iteration: {} error: {}'.format(i,
error(nn.output, nn.y)),
fontsize=12)
camera1.snap()
print("Ended training, waiting for closing animation")
animation = camera1.animate()
plt.show()
def start(train_data, test_data, resuming=False, testing=True):
nn = NeuralNetwork(train_data[:, :-1],
train_data[:, -1].reshape(-1, 1) / 800)
if resuming:
si, last_lossf, nn.learning_rate = np.load('state/state.npy')
nn.weights0 = np.load('state/weights0.npy')
nn.weights1 = np.load('state/weights1.npy')
nn.weights2 = np.load('state/weights2.npy')
nn.biasw1 = np.load('state/biasw1.npy')
nn.biasw2 = np.load('state/biasw2.npy')
best_test_lossf = np.load('state/best/test_lossf.npy')
else:
if not os.path.exists('state'): os.makedirs('state')
if not os.path.exists('state/best'): os.makedirs('state/best')
best_test_lossf = np.inf
si = 0
out = open('track_info.dat', 'a')
it = 2000
for i in range(int(si), it):
print('\n\niteration %d of %d\n' % (i + 1, it))
print(' layer 1: n = %d' % nn.n1)
print(' layer 2: n = %d' % nn.n2)
t0 = time.time()
print('\nbegin feed_forward() at ' +
datetime.datetime.now().strftime("%H:%M:%S on %d %B %Y"))
nn.feed_forward()
print(
'\n first third '
)
print(
' min quartile median quartile max '
)
print(
' ---------- ---------- ---------- ---------- ---------- '
)
print(' y |%11s %11s %11s %11s %11s' % quartiles(nn.y))
print(' output |%11s %11s %11s %11s %11s' %
quartiles(nn.output))
print('')
print(' weights0 |%11s %11s %11s %11s %11s' %
quartiles(nn.weights0))
print(' weights1 |%11s %11s %11s %11s %11s' %
quartiles(nn.weights1))
print(' weights2 |%11s %11s %11s %11s %11s' %
quartiles(nn.weights2))
print('')
print(' biasw1 |%11s %11s %11s %11s %11s' %
quartiles(nn.biasw1))
print(' biasw2 |%11s %11s %11s %11s %11s' %
quartiles(nn.biasw2))
te = time.time() - t0
print('\nfeed_forward() took %dm %.2fs\n' % (te // 60, te % 60))
lossf = nn.loss_function()
print('\n loss function (training): %.9f\n' % lossf)
out.write(datetime.datetime.now().strftime("%H:%M:%S %D") +
' %2s %6s %e %.6f' % (k, i + 1, nn.learning_rate, lossf))
if i > 10:
if last_lossf > lossf:
nn.save_weights()
np.save('state/state.npy', [i, lossf, nn.learning_rate])
if i < 200: nn.learning_rate *= 1.01
else: nn.learning_rate *= 1.005
else:
nn.learning_rate /= 1.007
tn = TrainedNeuralNetwork(test_data[:, :-1])
tn.load_weights(
(nn.weights0, nn.weights1, nn.weights2, nn.biasw1, nn.biasw2))
tn.feed_forward()
test_lossf = np.mean(
np.square(test_data[:, -1].reshape(-1, 1) - 800 * tn.output))
print(
' loss function (validation): %.3f HKD^2 -> %.3f HKD (rms)\n'
% (test_lossf, np.sqrt(test_lossf)))
out.write(' %.3f' % np.sqrt(test_lossf))
if best_test_lossf > test_lossf:
best_test_lossf = test_lossf
np.save('state/best/test_lossf.npy', best_test_lossf)
nn.save_weights(best=True)
t0 = time.time()
print('\nbegin back_prop() at ' +
datetime.datetime.now().strftime("%H:%M:%S on %d %B %Y"))
print('\n learning rate = %e' % nn.learning_rate)
nn.back_prop(testing)
if testing:
print('\n weights0 |%11s %11s %11s %11s %11s' %
quartiles(nn.weights0))
print(' weights1 |%11s %11s %11s %11s %11s' %
quartiles(nn.weights1))
print(' weights2 |%11s %11s %11s %11s %11s' %
quartiles(nn.weights2))
print(' biasw1 |%11s %11s %11s %11s %11s' %
quartiles(nn.biasw1))
print(' biasw2 |%11s %11s %11s %11s %11s' %
quartiles(nn.biasw2))
te = time.time() - t0
print('\nback_prop() took %dm %.2fs\n' % (te // 60, te % 60))
last_lossf = lossf
out.write('\n')
out.close()
