def gradient_check():
    (x_train, t_train), (x_test, t_test) = load_mnist(
        normalize=True, one_hot_label=True)

    network = TwoLayerNet(28 * 28, 50, 10)

    # sampling data
    x_sample = x_train[:3]
    t_sample = t_train[:3]

    # gradient by numerical gradient
    gradient_numerical = network.numerical_gradient(x_sample, t_sample)
    # gradient by backpropagation
    gradient_backpropagation = network.gradient(x_sample, t_sample)

    # get differences between gradient_numerical and gradient_backpropagation
    for key in gradient_numerical.keys():
        diff = np.average(
            np.abs(gradient_numerical[key] - gradient_backpropagation[key]))
        print('{0}: {1}'.format(key, diff))
def train(batch_size, iterate_num, learning_rate):
    """
    Get the appropriate network parameters (weights, biases) by backpropagation.

    batch_size: data of this number are choosed from training data in each step
    iterate_num: the number of iteration for backpropagation
    learning_rate: learning rate for backpropagation
    """
    # get training data and test data(test data are not used below.)
    (x_train, t_train), (x_test, t_test) = load_mnist(normalize=True,
                                                      one_hot_label=True)

    # initialized TwoLayerNet
    network = TwoLayerNet(28 * 28, 50, 10)  # each image has 28*28 pixels

    # losses in each step
    losses = []

    for i in range(iterate_num):
        # choose the training data for this step
        indices = np.random.choice(len(x_train), batch_size)
        x_train_batch = x_train[indices]
        t_train_batch = t_train[indices]

        # calculate the grad
        # grads = network.numerical_gradient(x_train_batch, t_train_batch)
        grads = network.gradient(x_train_batch, t_train_batch)

        # update the network parameters
        network.params['W1'] -= learning_rate * grads['W1']
        network.params['b1'] -= learning_rate * grads['b1']
        network.params['W2'] -= learning_rate * grads['W2']
        network.params['b2'] -= learning_rate * grads['b2']

        # record loss
        loss = network.loss(x_train_batch, t_train_batch)
        print('loss = {0}'.format(loss))
        losses.append(loss)

        # show accuracy
        if i % (iterate_num / 10) == 0:
            print('train_acc = {0}'.format(network.accuracy(x_train, t_train)))
            print('test_acc = {0}'.format(network.accuracy(x_test, t_test)))

    return network, losses
Esempio n. 3
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# coding: utf-8
import os
import sys

sys.path.append(os.pardir)  # 親ディレクトリのファイルをインポートするための設定
import numpy as np
from dataset.mnist import load_mnist
from ch05.two_layer_net import TwoLayerNet

# データの読み込み
(x_train, t_train), (x_test, t_test) = load_mnist(normalize=True, one_hot_label=True)

network = TwoLayerNet(input_size=784, hidden_size=50, output_size=10)

x_batch = x_train[:3]
t_batch = t_train[:3]

grad_numerical = network.numerical_gradient(x_batch, t_batch)
grad_backprop = network.gradient(x_batch, t_batch)

for key in grad_numerical.keys():
    diff = np.average(np.abs(grad_backprop[key] - grad_numerical[key]))
    print(key + ":" + str(diff))
Esempio n. 4
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import sys, os
sys.path.append(os.pardir)
import numpy as np
from ch05.two_layer_net import TwoLayerNet
from dataset.mnist import load_mnist
from common.functions import *
import pickle

from PIL import Image

network = TwoLayerNet(input_size=784, hidden_size=50, output_size=10)

filedir = os.path.dirname(os.path.realpath(__file__))
try:
    with open(os.path.join(filedir, 'params.pickle'), mode='rb') as f:
        network.refresh(pickle.load(f))
except:
    print('%s does not exist.' % 'params.pickle')


def predict(image):
    return softmax(network.predict(image))


#  return np.around(softmax(network.predict(image)), decimals=3)

# test
#(x_train, t_train), (x_test, t_test) = load_mnist(normalize=True, one_hot_label=True) # t:teacher
#
#one_of_x_test = x_test[20]
#one_of_t_test = t_test[20]
Esempio n. 5
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batch_size = 100  # 小批量数
learning_rate = 0.01

train_loss_list = {}
index_list = []

optimizer_dict = OrderedDict()
optimizer_dict['SGD'] = SGD()
optimizer_dict['Momentum'] = Momentum()
optimizer_dict['AdaGrad'] = AdaGrad()
optimizer_dict['RMSProp'] = RMSprop()
optimizer_dict['Adam'] = Adam()

for key in optimizer_dict.keys():
    train_loss_list[key] = []
    network[key] = TwoLayerNet(input_size=784, hidden_size=50, output_size=10)

iter_per_epoch = max(train_size / batch_size, 1)  # 一个epoch需要遍历的轮数

for i in range(0, iters_num):

    print('这是第%d轮' % i)

    # mini-batch
    batch_mask = np.random.choice(train_size, batch_size)
    x_batch = x_train[batch_mask]
    t_batch = t_train[batch_mask]

    for key, optimizer in optimizer_dict.items():
        grads = network[key].gradient(x_batch, t_batch)
        optimizer.update(network[key].params, grads)
Esempio n. 6
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import sys, os

sys.path.append(os.path.dirname(os.path.abspath(__file__)) + \
                '/deep-learning-from-scratch-master/')
import numpy as np
from dataset.mnist import load_mnist
from ch05.two_layer_net import TwoLayerNet

(x_train, t_train), (x_test, t_test) = \
    load_mnist(normalize=True, one_hot_label=True)

network = TwoLayerNet(input_size=784, hidden_size=50, output_size=10)

iters_num = 10000
train_size = x_train.shape[0]
batch_size = 100
learning_rate = 0.1

train_loss_list = []
train_acc_list = []
test_acc_list = []

iter_per_epoch = max(train_size / batch_size, 1)

for i in range(iters_num):
    batch_mask = np.random.choice(train_size, batch_size)
    x_batch = x_train[batch_mask]
    t_batch = t_train[batch_mask]

    # 誤差逆伝播法による
    grad = network.gradient(x_batch, t_batch)