1.一些概念
训练误差(training error)指模型在训练数据集上表现出的误差
泛化误差(generalization error)指模型在任意一个测试数据样本上表现出的误差的期望,并常常通过测试数据集上的误差来近似。
机器学习模型应关注降低泛化误差。
2.多项式拟合实验
# %matplotlib inline
import torch
import numpy as np
import sys
sys.path.append(r"D:\project\fitting学习")
import d2lzh1981 as d2l
print(torch.__version__)初始化模型参数
# n_train, n_test分别指训练样本数和测试样本数
n_train, n_test, true_w, true_b = 100, 100, [1.2, -3.4, 5.6], 5
# features初始化为x
features = torch.randn((n_train + n_test, 1))
# 那么这里poly_features就为x,x^2,x^3
poly_features = torch.cat((features, torch.pow(features, 2), torch.pow(features, 3)), 1)
labels = (true_w[0] * poly_features[:, 0] + true_w[1] * poly_features[:, 1]
+ true_w[2] * poly_features[:, 2] + true_b)
labels += torch.tensor(np.random.normal(0, 0.01, size=labels.size()), dtype=torch.float)features[:2], poly_features[:2], labels[:2]定义、训练和测试模型
首先定义一个画图函数用于观察
def semilogy(x_vals, y_vals, x_label, y_label, x2_vals=None, y2_vals=None,
legend=None, figsize=(3.5, 2.5)):
# d2l.set_figsize(figsize)
d2l.plt.xlabel(x_label)
d2l.plt.ylabel(y_label)
d2l.plt.semilogy(x_vals, y_vals)
if x2_vals and y2_vals:
d2l.plt.semilogy(x2_vals, y2_vals, linestyle=':')
d2l.plt.legend(legend)定义一个可以用来训练并打印训练误差和泛化误差的函数
num_epochs, loss = 100, torch.nn.MSELoss()
def fit_and_plot(train_features, test_features, train_labels, test_labels):
# 初始化网络模型
net = torch.nn.Linear(train_features.shape[-1], 1)
# 通过Linear文档可知,pytorch已经将参数初始化了,所以我们这里就不手动初始化了
# 设置批量大小
batch_size = min(10, train_labels.shape[0])
dataset = torch.utils.data.TensorDataset(train_features, train_labels) # 设置数据集
train_iter = torch.utils.data.DataLoader(dataset, batch_size, shuffle=True) # 设置获取数据方式
optimizer = torch.optim.SGD(net.parameters(), lr=0.01) # 设置优化函数,使用的是随机梯度下降优化
train_ls, test_ls = [], []
for _ in range(num_epochs):
for X, y in train_iter: # 取一个批量的数据
l = loss(net(X), y.view(-1, 1)) # 输入到网络中计算输出,并和标签比较求得损失函数
optimizer.zero_grad() # 梯度清零,防止梯度累加干扰优化
l.backward() # 求梯度
optimizer.step() # 迭代优化函数,进行参数优化
train_labels = train_labels.view(-1, 1)
test_labels = test_labels.view(-1, 1)
train_ls.append(loss(net(train_features), train_labels).item()) # 将训练损失保存到train_ls中
test_ls.append(loss(net(test_features), test_labels).item()) # 将测试损失保存到test_ls中
print('final epoch: train loss', train_ls[-1], 'test loss', test_ls[-1])
semilogy(range(1, num_epochs + 1), train_ls, 'epochs', 'loss',
range(1, num_epochs + 1), test_ls, ['train', 'test'])
print('weight:', net.weight.data,
'\nbias:', net.bias.data)三阶多项式拟合(正常)
fit_and_plot(poly_features[:n_train, :], poly_features[n_train:, :], labels[:n_train], labels[n_train:])
线性函数拟合(欠拟合)
前面输入的是poly_features,而这里我们输入features
fit_and_plot(features[:n_train, :], features[n_train:, :], labels[:n_train], labels[n_train:])来看一下结果
训练样本不足(过拟合)
这里也是输入poly_features,但是只有0和1
fit_and_plot(poly_features[0:2, :], poly_features[n_train:, :], labels[0:2], labels[n_train:])
3.方法
范数正则化(regularization)
高维线性回归实验从零开始的实现
#%matplotlib inline
import torch
import torch.nn as nn
import numpy as np
import sys
sys.path.append(r"D:\project\fitting学习")
import d2lzh1981 as d2l
print(torch.__version__)初始化模型参数
n_train, n_test, num_inputs = 20, 100, 200
true_w, true_b = torch.ones(num_inputs, 1) * 0.01, 0.05
features = torch.randn((n_train + n_test, num_inputs))
labels = torch.matmul(features, true_w) + true_b
labels += torch.tensor(np.random.normal(0, 0.01, size=labels.size()), dtype=torch.float)
train_features, test_features = features[:n_train, :], features[n_train:, :]
train_labels, test_labels = labels[:n_train], labels[n_train:]# 定义参数初始化函数,初始化模型参数并且附上梯度
def init_params():
w = torch.randn((num_inputs, 1), requires_grad=True)
b = torch.zeros(1, requires_grad=True)
return [w, b]定义L2范数惩罚项
将权重的每个元素平方再求和
def l2_penalty(w):
return (w**2).sum() / 2定义训练和测试
batch_size, num_epochs, lr = 1, 100, 0.003
net, loss = d2l.linreg, d2l.squared_loss
dataset = torch.utils.data.TensorDataset(train_features, train_labels)
train_iter = torch.utils.data.DataLoader(dataset, batch_size, shuffle=True)
def fit_and_plot(lambd):# 定义了一个超参数λ,这个就是L2范数中乘的那个正数
w, b = init_params()
train_ls, test_ls = [], []
for _ in range(num_epochs):
for X, y in train_iter:
# 添加了L2范数惩罚项
l = loss(net(X, w, b), y) + lambd * l2_penalty(w)
l = l.sum()
if w.grad is not None:
w.grad.data.zero_()
b.grad.data.zero_()
l.backward()
d2l.sgd([w, b], lr, batch_size)
train_ls.append(loss(net(train_features, w, b), train_labels).mean().item())
test_ls.append(loss(net(test_features, w, b), test_labels).mean().item())
d2l.semilogy(range(1, num_epochs + 1), train_ls, 'epochs', 'loss',
range(1, num_epochs + 1), test_ls, ['train', 'test'])
print('L2 norm of w:', w.norm().item())观察过拟合
fit_and_plot(lambd=0)
使用权重衰减
fit_and_plot(lambd=3)
简洁实现
def fit_and_plot_pytorch(wd):
# 对权重参数衰减。权重名称一般是以weight结尾
net = nn.Linear(num_inputs, 1)
# 参数初始化使用init模块来完成
nn.init.normal_(net.weight, mean=0, std=1)
nn.init.normal_(net.bias, mean=0, std=1)
# 优化函数使用的是optim模块里的随机梯度下降函数
# 这里不需要为L2范数惩罚项单独撰写函数,权重衰减已经封装在SGD函数中了
# weight_decay=wd表示启用权重衰减
optimizer_w = torch.optim.SGD(params=[net.weight], lr=lr, weight_decay=wd) # 对权重参数衰减
optimizer_b = torch.optim.SGD(params=[net.bias], lr=lr) # 不对偏差参数衰减
train_ls, test_ls = [], []
for _ in range(num_epochs):
for X, y in train_iter:
l = loss(net(X), y).mean()
optimizer_w.zero_grad()
optimizer_b.zero_grad()
l.backward()
# 对两个optimizer实例分别调用step函数,从而分别更新权重和偏差
optimizer_w.step()
optimizer_b.step()
train_ls.append(loss(net(train_features), train_labels).mean().item())
test_ls.append(loss(net(test_features), test_labels).mean().item())
d2l.semilogy(range(1, num_epochs + 1), train_ls, 'epochs', 'loss',
range(1, num_epochs + 1), test_ls, ['train', 'test'])
print('L2 norm of w:', net.weight.data.norm().item())fit_and_plot_pytorch(0)
fit_and_plot_pytorch(3)
丢弃法
丢弃法从零开始的实现
%matplotlib inline
import torch
import torch.nn as nn
import numpy as np
import sys
sys.path.append("/home/kesci/input")
import d2lzh1981 as d2l
print(torch.__version__)def dropout(X, drop_prob):
X = X.float()
assert 0 <= drop_prob <= 1 # 判断丢弃率是否在0到1之间,如果不在就会报错
keep_prob = 1 - drop_prob
# 这种情况下把全部元素都丢弃
if keep_prob == 0:# keep_prob是保存率,保存率为0说明元素要被全部丢弃,所以返回一个0化的x就可以了
return torch.zeros_like(X)
mask = (torch.rand(X.shape) < keep_prob).float()# 随机生成一个x形状的矩阵,内容是随机的。将随机生成的矩阵中的每个位置上的元素和保留率进行比较,如果小于保留率,那么这个位置的元素得以保留,该位置赋值为1,如果大于,该位置元素就要被丢弃,赋值为0。这样就得到mask
return mask * X / keep_probX = torch.arange(16).view(2, 8)
dropout(X, 0)# 丢弃率为0,得到的就是原始矩阵x
dropout(X, 0.5)
dropout(X, 1.0)
# 参数的初始化
num_inputs, num_outputs, num_hiddens1, num_hiddens2 = 784, 10, 256, 256
W1 = torch.tensor(np.random.normal(0, 0.01, size=(num_inputs, num_hiddens1)), dtype=torch.float, requires_grad=True)
b1 = torch.zeros(num_hiddens1, requires_grad=True)
W2 = torch.tensor(np.random.normal(0, 0.01, size=(num_hiddens1, num_hiddens2)), dtype=torch.float, requires_grad=True)
b2 = torch.zeros(num_hiddens2, requires_grad=True)
W3 = torch.tensor(np.random.normal(0, 0.01, size=(num_hiddens2, num_outputs)), dtype=torch.float, requires_grad=True)
b3 = torch.zeros(num_outputs, requires_grad=True)
params = [W1, b1, W2, b2, W3, b3]drop_prob1, drop_prob2 = 0.2, 0.5# 隐藏层有两层,所以设置两个丢弃率
def net(X, is_training=True):# 输入参数is_training来区分是否在训练
X = X.view(-1, num_inputs)
H1 = (torch.matmul(X, W1) + b1).relu()
if is_training: # 只在训练模型时使用丢弃法
H1 = dropout(H1, drop_prob1) # 在第一层全连接后添加丢弃层
H2 = (torch.matmul(H1, W2) + b2).relu()
if is_training:
H2 = dropout(H2, drop_prob2) # 在第二层全连接后添加丢弃层
return torch.matmul(H2, W3) + b3def evaluate_accuracy(data_iter, net):
acc_sum, n = 0.0, 0
for X, y in data_iter:
if isinstance(net, torch.nn.Module):# 判断网络模型是不是nn.Module
net.eval() # 是的话使用评估模式, 这会关闭dropout
acc_sum += (net(X).argmax(dim=1) == y).float().sum().item()
net.train() # 改回训练模式
else: # 自定义的模型
if('is_training' in net.__code__.co_varnames): # 如果有is_training这个参数
# 将is_training设置成False
acc_sum += (net(X, is_training=False).argmax(dim=1) == y).float().sum().item()
else:
acc_sum += (net(X).argmax(dim=1) == y).float().sum().item()
n += y.shape[0]
return acc_sum / nnum_epochs, lr, batch_size = 5, 100.0, 256 # 这里的学习率设置的很大,原因与之前相同。
loss = torch.nn.CrossEntropyLoss()
train_iter, test_iter = d2l.load_data_fashion_mnist(batch_size, root='/home/kesci/input/FashionMNIST2065')
d2l.train_ch3(
net,
train_iter,
test_iter,
loss,
num_epochs,
batch_size,
params,
lr)简洁实现
net = nn.Sequential(
d2l.FlattenLayer(),
nn.Linear(num_inputs, num_hiddens1),
nn.ReLU(),
nn.Dropout(drop_prob1),
nn.Linear(num_hiddens1, num_hiddens2),
nn.ReLU(),
nn.Dropout(drop_prob2),
nn.Linear(num_hiddens2, 10)
)
for param in net.parameters():
nn.init.normal_(param, mean=0, std=0.01)
optimizer = torch.optim.SGD(net.parameters(), lr=0.5)
d2l.train_ch3(net, train_iter, test_iter, loss, num_epochs, batch_size, None, None, optimizer)
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