神经网络模型流程
神经网络模型的搭建流程,整理下自己的思路,这个过程不会细分出来,而是主流程。
在这里我主要是把整个流程分为两个主流程,即预训练与推理。预训练过程主要是生成超参数文件与搭设神经网络结构;而推理过程就是在应用超参数与神经网络。
卷积神经网络的实现
在 聊聊卷积神经网络CNN中,将卷积神经的理论概述了一下,现在要大概的实践了。整个代码不基于pytorch/tensorflow这类大框架,而是基于numpy库原生来实现算法。pytorch/tensorflow中的算子/函数只是由别人已实现了,我们调用而已;而基于numpy要自己实现一遍,虽然并不很严谨,但用于学习足以。
源代码是来自《深度学习入门:基于Python的理论与实现》,可以在 图灵社区 上获取下载
搭建CNN
网络构成如下:
如图所示,网络的构成是"Conv-ReLU-Pooling-Affine-ReLU-Affine-Softmax". 对于卷积层与池化层的计算,由于其是四维数据(数据量,通道,高,长),不太好计算,使用im2col
函数将其展开成二维 2 × 2的数据,最后输出时,利用numpy库的reshape函数转换输出的大小,方便计算。其示意图如下:
这样也满足了矩阵内积计算的要求,即 行列数要对应
CNN程序代码实现如下:
# coding: utf-8
import sys, os
sys.path.append(os.pardir) # 为了导入父目录的文件而进行的设定
import pickle
import numpy as np
from collections import OrderedDict
from DeepLearn_Base.common.layers import *
from DeepLearn_Base.common.gradient import numerical_gradient
class SimpleConvNet:
"""简单的ConvNet
conv - relu - pool - affine - relu - affine - softmax
Parameters
----------
input_dim: 输入数据的维度,通道、高、长
conv_param: 卷积核参数; filter_num:卷积核数量; filter_size:卷积核大小; stride:步幅; pad:填充
input_size : 输入大小(MNIST的情况下为784)
hidden_size_list : 隐藏层的神经元数量的列表(e.g. [100, 100, 100])
output_size : 输出大小(MNIST的情况下为10)
activation : 'relu' or 'sigmoid'
weight_init_std : 指定权重的标准差(e.g. 0.01)
指定'relu'或'he'的情况下设定“He的初始值”
指定'sigmoid'或'xavier'的情况下设定“Xavier的初始值”
"""
def __init__(self, input_dim=(1, 28, 28),
conv_param={'filter_num':30, 'filter_size':5, 'pad':0, 'stride':1},
hidden_size=100, output_size=10, weight_init_std=0.01):
filter_num = conv_param['filter_num']
filter_size = conv_param['filter_size']
filter_pad = conv_param['pad']
filter_stride = conv_param['stride']
input_size = input_dim[1]
conv_output_size = (input_size - filter_size + 2*filter_pad) / filter_stride + 1
pool_output_size = int(filter_num * (conv_output_size/2) * (conv_output_size/2))
# 初始化权重
self.params = {}
self.params['W1'] = weight_init_std * \
np.random.randn(filter_num, input_dim[0], filter_size, filter_size)
self.params['b1'] = np.zeros(filter_num)
self.params['W2'] = weight_init_std * \
np.random.randn(pool_output_size, hidden_size)
self.params['b2'] = np.zeros(hidden_size)
self.params['W3'] = weight_init_std * \
np.random.randn(hidden_size, output_size)
self.params['b3'] = np.zeros(output_size)
# 生成层
self.layers = OrderedDict()
self.layers['Conv1'] = Convolution(self.params['W1'], self.params['b1'],
conv_param['stride'], conv_param['pad'])
self.layers['Relu1'] = Relu()
self.layers['Pool1'] = Pooling(pool_h=2, pool_w=2, stride=2)
self.layers['Affine1'] = Affine(self.params['W2'], self.params['b2'])
self.layers['Relu2'] = Relu()
self.layers['Affine2'] = Affine(self.params['W3'], self.params['b3'])
self.last_layer = SoftmaxWithLoss()
# 需要处理数据,将输入数据的多维与卷积核的多维分别展平后做矩阵运算
# 在神经网络的中间层(conv,relu,pooling,affine等)的forward函数中用到了img2col与reshape结合展平数据,用向量内积运算
def predict(self, x):
for layer in self.layers.values():
x = layer.forward(x)
return x
def loss(self, x, t):
"""求损失函数
参数x是输入数据、t是教师标签
"""
y = self.predict(x)
return self.last_layer.forward(y, t)
# 计算精确度
def accuracy(self, x, t, batch_size=100):
if t.ndim != 1 : t = np.argmax(t, axis=1)
acc = 0.0
for i in range(int(x.shape[0] / batch_size)):
tx = x[i*batch_size:(i+1)*batch_size]
tt = t[i*batch_size:(i+1)*batch_size]
y = self.predict(tx)
y = np.argmax(y, axis=1)
acc += np.sum(y == tt)
return acc / x.shape[0]
def numerical_gradient(self, x, t):
"""求梯度(数值微分)
Parameters
----------
x : 输入数据
t : 教师标签
Returns
-------
具有各层的梯度的字典变量
grads['W1']、grads['W2']、...是各层的权重
grads['b1']、grads['b2']、...是各层的偏置
"""
loss_w = lambda w: self.loss(x, t)
grads = {}
for idx in (1, 2, 3):
grads['W' + str(idx)] = numerical_gradient(loss_w, self.params['W' + str(idx)])
grads['b' + str(idx)] = numerical_gradient(loss_w, self.params['b' + str(idx)])
return grads
def gradient(self, x, t):
"""求梯度(误差反向传播法)
Parameters
----------
x : 输入数据
t : 教师标签
Returns
-------
具有各层的梯度的字典变量
grads['W1']、grads['W2']、...是各层的权重
grads['b1']、grads['b2']、...是各层的偏置
"""
# forward
self.loss(x, t)
# backward
dout = 1
dout = self.last_layer.backward(dout)
layers = list(self.layers.values())
layers.reverse()
for layer in layers:
dout = layer.backward(dout)
# 设定
grads = {}
grads['W1'], grads['b1'] = self.layers['Conv1'].dW, self.layers['Conv1'].db
grads['W2'], grads['b2'] = self.layers['Affine1'].dW, self.layers['Affine1'].db
grads['W3'], grads['b3'] = self.layers['Affine2'].dW, self.layers['Affine2'].db
return grads
def save_params(self, file_name="params.pkl"):
params = {}
for key, val in self.params.items():
params[key] = val
with open(file_name, 'wb') as f:
pickle.dump(params, f)
def load_params(self, file_name="params.pkl"):
with open(file_name, 'rb') as f:
params = pickle.load(f)
for key, val in params.items():
self.params[key] = val
for i, key in enumerate(['Conv1', 'Affine1', 'Affine2']):
self.layers[key].W = self.params['W' + str(i+1)]
self.layers[key].b = self.params['b' + str(i+1)]
激活函数与卷积函数的实现代码没有详细的写出来,可以自己去下载查看
在这整个的过程中,我个人觉得最难的就是神经网络层的搭建与数据的计算。前者决定了神经网络的结构,而后者决定了是否最终结果。通过将数据展平,才能方便,正确的进行向量内积计算。
预训练
trainer.py文件是进行神经网络训练的类,会统计执行完一个epoch后的精确度,过程要选择梯度更新算法,学习率,批大小,epoch次数等参数。
# coding: utf-8
import sys, os
sys.path.append(os.pardir) # 为了导入父目录的文件而进行的设定
import numpy as np
from DeepLearn_Base.common.optimizer import *
class Trainer:
"""进行神经网络的训练的类
epochs: 以所有数据走完前向、后向传播为一次;该数值表示为总次数
mini_batch_size: 100; 每批次迭代多少数据
evaluate_sample_num_per_epoch: 1000;
"""
def __init__(self, network, x_train, t_train, x_test, t_test,
epochs=20, mini_batch_size=100,
optimizer='SGD', optimizer_param={'lr':0.01},
evaluate_sample_num_per_epoch=None, verbose=True):
self.network = network
self.verbose = verbose
self.x_train = x_train
self.t_train = t_train
self.x_test = x_test
self.t_test = t_test
self.epochs = epochs
self.batch_size = mini_batch_size
self.evaluate_sample_num_per_epoch = evaluate_sample_num_per_epoch
# optimzer: 梯度更新优化器; 更新多种梯度更新算法实现梯度更新.
optimizer_class_dict = {'sgd':SGD, 'momentum':Momentum, 'nesterov':Nesterov,
'adagrad':AdaGrad, 'rmsprpo':RMSprop, 'adam':Adam}
self.optimizer = optimizer_class_dict[optimizer.lower()](**optimizer_param)
self.train_size = x_train.shape[0]
self.iter_per_epoch = max(self.train_size / mini_batch_size, 1)
self.max_iter = int(epochs * self.iter_per_epoch)
self.current_iter = 0
self.current_epoch = 0
self.train_loss_list = []
self.train_acc_list = []
self.test_acc_list = []
def train_step(self):
# 随机挑选批次的数据进行梯度更新
batch_mask = np.random.choice(self.train_size, self.batch_size)
x_batch = self.x_train[batch_mask]
t_batch = self.t_train[batch_mask]
# 开始更新梯度
grads = self.network.gradient(x_batch, t_batch)
self.optimizer.update(self.network.params, grads)
# 计算损失
loss = self.network.loss(x_batch, t_batch)
self.train_loss_list.append(loss)
if self.verbose: print("train loss:" + str(loss))
# 计算是否完成了一个epoch的执行
if self.current_iter % self.iter_per_epoch == 0:
self.current_epoch += 1
x_train_sample, t_train_sample = self.x_train, self.t_train
x_test_sample, t_test_sample = self.x_test, self.t_test
if not self.evaluate_sample_num_per_epoch is None:
t = self.evaluate_sample_num_per_epoch
x_train_sample, t_train_sample = self.x_train[:t], self.t_train[:t]
x_test_sample, t_test_sample = self.x_test[:t], self.t_test[:t]
train_acc = self.network.accuracy(x_train_sample, t_train_sample)
test_acc = self.network.accuracy(x_test_sample, t_test_sample)
self.train_acc_list.append(train_acc)
self.test_acc_list.append(test_acc)
if self.verbose: print("=== epoch:" + str(self.current_epoch) + ", train acc:" + str(train_acc) + ", test acc:" + str(test_acc) + " ===")
self.current_iter += 1
def train(self):
for i in range(self.max_iter):
self.train_step()
test_acc = self.network.accuracy(self.x_test, self.t_test)
if self.verbose:
print("=============== Final Test Accuracy ===============")
print("test acc:" + str(test_acc))
在神经网络训练中,epoch参数是指将整个训练集通过模型一次,并更新模型参数的过程。每一次epoch,模型都会将训练集中的所有样本通过一次,并根据这些样本的标签和模型预测的结果计算损失值,然后根据损失值对模型的参数进行更新。这个过程会重复进行,直到达到预设的epoch数。
正式开始预训练,要准备好训练数据集,初始化CNN,梯度优化参数,超参数存储路径等。如下所示:
# coding: utf-8
import sys, os
sys.path.append(os.pardir) # 为了导入父目录的文件而进行的设定
import numpy as np
import matplotlib.pyplot as plt
from DeepLearn_Base.dataset.mnist import load_mnist
from simple_convnet import SimpleConvNet
from DeepLearn_Base.common.trainer import Trainer
# 读入数据
# 输入数据的表现形式,可以是多维的,可以是展平(reshape)为一维的
(x_train, t_train), (x_test, t_test) = load_mnist(flatten=False)
# 处理花费时间较长的情况下减少数据,截取部分数据
# 训练数据截取 5000 条
# 测试数据截取 1000 条
x_train, t_train = x_train[:5000], t_train[:5000]
x_test, t_test = x_test[:1000], t_test[:1000]
# 初始化epoch
max_epochs = 20
# 初始化CNN
# input_dim, 输入数据: channel, height, width
# conv_param, 卷积核参数: filter_num:卷积核数量; filter_size:卷积核大小; stride:步幅; pad:填充; 30个5 × 5,通道为1的卷积核
network = SimpleConvNet(input_dim=(1,28,28),
conv_param = {'filter_num': 30, 'filter_size': 5, 'pad': 0, 'stride': 1},
hidden_size=100, output_size=10, weight_init_std=0.01)
# 初始化预训练
# optimizer: 梯度优化算法; lr表示学习率
trainer = Trainer(network, x_train, t_train, x_test, t_test,
epochs=max_epochs, mini_batch_size=100,
optimizer='Adam', optimizer_param={'lr': 0.001},
evaluate_sample_num_per_epoch=1000)
trainer.train()
# 保存参数
network.save_params("E:\\workcode\\code\\DeepLearn_Base\\ch07\\cnn_params.pkl")
print("Saved Network Parameters!")
# 绘制图形
markers = {'train': 'o', 'test': 's'}
x = np.arange(max_epochs)
plt.plot(x, trainer.train_acc_list, marker='o', label='train', markevery=2)
plt.plot(x, trainer.test_acc_list, marker='s', label='test', markevery=2)
plt.xlabel("epochs")
plt.ylabel("accuracy")
plt.ylim(0, 1.0)
plt.legend(loc='lower right')
plt.show()
预训练好后,查看是否生成超参数文件。
推理
准备好测试数据集,应用已预训练好的神经网络模型与超参数。
# coding: utf-8
import sys, os
# 为了导入父目录的文件而进行的设定
sys.path.append(os.pardir)
import numpy as np
from DeepLearn_Base.dataset.mnist import load_mnist
from DeepLearn_Base.common.functions import sigmoid, softmax
from simple_convnet import SimpleConvNet
def get_data():
(x_train, t_train), (x_test, t_test) = load_mnist(flatten=False)
return x_test, t_test
# 下载mnist数据集
# 分别下载测试图像包、测试标签包、训练图像包、训练标签包
x, t = get_data()
conv = SimpleConvNet()
# 获取预训练好的权重与偏置参数
conv.load_params("E:\\workcode\\code\\DeepLearn_Base\\ch07\\cnn_params.pkl")
# 初始化
batch_size = 100
accuracy_cnt = 0
for i in range(int(x.shape[0] / batch_size)):
# 批次取数据
x_batch = x[i * batch_size : (i+1) * batch_size]
tt = t[i * batch_size : (i+1) * batch_size]
# 执行推理
y_batch = conv.predict(x_batch)
p = np.argmax(y_batch, axis=1)
# 统计预测正确的数据
accuracy_cnt += np.sum(p == tt)
print(f'第 {i} 批次,输入数据量{(i+1) * batch_size}个,准确预测数为 {accuracy_cnt}')
print("Accuracy:" + str(float(accuracy_cnt) / x.shape[0]))
最后的输出如下: