注:书中对代码的讲解并不详细,本文对很多细节做了详细注释。另外,书上的源代码是在Jupyter Notebook上运行的,较为分散,本文将代码集中起来,并加以完善,全部用vscode在python 3.9.18下测试通过,同时对于书上部分章节也做了整合。
Chapter6 Convolutional Neural Network(CNN)
6.3 LeNet
LeNet模型中每个卷积块中的基本单元是一个卷积层、一个sigmoid激活函数和平均汇聚层。虽然ReLU和最大汇聚层更有效,但它们在20世纪90年代还没有出现。每个卷积层使用 5 × 5 5\times 5 5×5卷积核和一个sigmoid激活函数,这些层将输入映射到多个二维特征输出,通常同时增加通道的数量。第一卷积层有6个输出通道,而第二个卷积层有16个输出通道,每个 2 × 2 2\times2 2×2池操作(步幅2)通过空间下采样将维数减少4倍。为了将卷积块的输出传递给稠密块,我们必须在小批量中展平每个样本。换言之,我们将这个四维输入转换成全连接层所期望的二维输入(第一个维度索引小批量中的样本,第二个维度给出每个样本的平面向量表示)。LeNet的稠密块有三个全连接层,分别有120、84和10个输出。因为我们在执行分类任务,所以输出层的10维对应于最后输出结果的数量。
import torch
from torch import nn
from d2l import torch as d2l
import matplotlib.pyplot as plt
net = nn.Sequential(
nn.Conv2d(1, 6, kernel_size=5, padding=2), nn.Sigmoid(),
nn.AvgPool2d(kernel_size=2, stride=2),
nn.Conv2d(6, 16, kernel_size=5), nn.Sigmoid(),
nn.AvgPool2d(kernel_size=2, stride=2),
nn.Flatten(),
nn.Linear(16 * 5 * 5, 120), nn.Sigmoid(),
nn.Linear(120, 84), nn.Sigmoid(),
nn.Linear(84, 10))
X = torch.rand(size=(1, 1, 28, 28), dtype=torch.float32)
for layer in net:
X = layer(X)
print(layer.__class__.__name__,'output shape: \t',X.shape)
batch_size = 256
train_iter, test_iter = d2l.load_data_fashion_mnist(batch_size=batch_size)
def evaluate_accuracy_gpu(net, data_iter, device=None): #@save
"""使用GPU计算模型在数据集上的精度"""
if isinstance(net, nn.Module):
net.eval() # 设置为评估模式
if not device:
device = next(iter(net.parameters())).device
metric = d2l.Accumulator(2)#metric[0]:正确预测的数量,metric[1]:总预测的数量。
with torch.no_grad():
for X, y in data_iter:
if isinstance(X, list):
X = [x.to(device) for x in X]# BERT微调所需,将输入转移到GPU上(之后将介绍)
else:
X = X.to(device)
y = y.to(device)
metric.add(d2l.accuracy(net(X), y), y.numel())
return metric[0] / metric[1]
def train_ch6(net, train_iter, test_iter, num_epochs, lr, device):#@save
"""用GPU训练模型"""
def init_weights(m):
if type(m) == nn.Linear or type(m) == nn.Conv2d:
nn.init.xavier_uniform_(m.weight)
net.apply(init_weights)
print('training on', device)
net.to(device)
optimizer = torch.optim.SGD(net.parameters(), lr=lr)
loss = nn.CrossEntropyLoss()
animator = d2l.Animator(xlabel='epoch', xlim=[1, num_epochs],legend=['train loss', 'train acc', 'test acc'])
timer, num_batches = d2l.Timer(), len(train_iter)
for epoch in range(num_epochs):
metric = d2l.Accumulator(3)#metric[i]分别是训练损失之和,训练准确率之和,样本数
net.train()
for i, (X, y) in enumerate(train_iter):
timer.start()
optimizer.zero_grad()
X, y = X.to(device), y.to(device)
y_hat = net(X)
l = loss(y_hat, y)
l.backward()
optimizer.step()
with torch.no_grad():
metric.add(l * X.shape[0], d2l.accuracy(y_hat, y), X.shape[0])
timer.stop()
train_l = metric[0] / metric[2]
train_acc = metric[1] / metric[2]
if (i + 1) % (num_batches // 5) == 0 or i == num_batches - 1:
animator.add(epoch + (i + 1) / num_batches,(train_l, train_acc, None))
test_acc = evaluate_accuracy_gpu(net, test_iter)
animator.add(epoch + 1, (None, None, test_acc))
print(f'loss {train_l:.3f}, train acc {train_acc:.3f}, test acc {test_acc:.3f}')
print(f'{metric[2] * num_epochs / timer.sum():.1f} examples/sec on {str(device)}')
lr, num_epochs = 0.9, 10
train_ch6(net, train_iter, test_iter, num_epochs, lr, d2l.try_gpu())
plt.show()
训练结果:
