文章目录
9、CNN 卷积神经网络
B站视频教程传送门:PyTorch深度学习实践 - 卷积神经网络(基础篇) PyTorch深度学习实践 - 卷积神经网络(高级篇)
9.1 Revision
全连接神经网络(Fully Connected Neural Network):该网络完全由线形层Linear串行连接起来,即每一个输入节点都要参与到下一层任一输出节点的计算上。
class Net(torch.nn.Module):
def __init__(self):
super(Net, self).__init__()
self.l1 = torch.nn.Linear(784, 512)
self.l2 = torch.nn.Linear(512, 256)
self.l3 = torch.nn.Linear(256, 128)
self.l4 = torch.nn.Linear(128, 64)
self.l5 = torch.nn.Linear(64, 10)
def forward(self, x):
x = x.view(-1, 784)
x = F.relu(self.l1(x))
x = F.relu(self.l2(x))
x = F.relu(self.l3(x))
x = F.relu(self.l4(x))
return self.l5(x)
model = Net()
9.2 Introduction
Convolutional Neural Network
注意:
-
1 × 28 × 28 < = = > C × W × H 1 \times 28 \times 28 <==> C \times W \times H 1×28×28<==>C×W×H
-
Convolution 卷积:保留图像的空间结构信息
-
Subsampling 下采样(主要是 Max Pooling):通道数不变,宽高改变,为了减少图像数据量,进一步降低运算的需求
-
Fully Connected 全连接:将张量展开为一维向量,再进行分类
-
我们将 Convolution 及 Subsampling 等称为特征提取(Feature Extraction),最后的 Fully Connected 称为分类(Classification)。
9.3 Convolution
9.3.1 Channel
- Single Input Channel:
- 3 Input Channels:
其中,C H W 变化如下:
- N Input Channels:
- N Input Channels and M Output Channels
要想输出 M 通道的图像,卷积核也需设置为 M 个:
9.3.2 Layer
当输入为 n × w i d t h i n × h e i g h t i n n \times width_{in} \times height_{in} n×widthin×heightin ,如何得到 m × w i d t h o u t × h e i g h t o u t m \times width_{out} \times height_{out} m×widthout×heightout 的输出:
输出的通道数为 m,所以需要 m 个卷积核,且每个卷积核的尺寸为:
n
×
k
e
r
n
e
l
w
i
d
t
h
×
k
e
r
n
e
l
h
e
i
g
h
t
n \times kernel_{width} \times kernel_{height}
n×kernelwidth×kernelheight ,即四维张量:
m
×
n
×
k
e
r
n
e
l
w
i
d
t
h
×
k
e
r
n
e
l
h
e
i
g
h
t
\Large m \times n \times kernel_{width} \times kernel_{height}
m×n×kernelwidth×kernelheight
import torch
in_channels, out_channels = 5, 10
width, height = 100, 100
kernel_size = 3
batch_size = 1
input = torch.randn(batch_size, in_channels, width, height)
conv_layer = torch.nn.Conv2d(in_channels, out_channels, kernel_size=kernel_size)
output = conv_layer(input)
print(input.shape)
print(conv_layer.weight.shape) # m n w h
print(output.shape)
torch.Size([1, 5, 100, 100])
torch.Size([10, 5, 3, 3])
torch.Size([1, 10, 98, 98])
9.3.3 Padding
如果 i n p u t = 5 × 5 input = 5 \times 5 input=5×5 , k e r n e l = 3 × 3 kernel = 3 \times 3 kernel=3×3 ,并且希望 o u t p u t = 5 × 5 output = 5 \times 5 output=5×5,可以采取什么方法?
可以使用参数 padding=1 ,先将input填充至 7 × 7 7 \times 7 7×7 ,这样卷积之后,output仍为 5 × 5 5 \times 5 5×5 。
import torch
input = [3, 4, 6, 5, 7,
2, 4, 6, 8, 2,
1, 6, 7, 8, 4,
9, 7, 4, 6, 2,
3, 7, 5, 4, 1]
input = torch.Tensor(input).view(1, 1, 5, 5) # B C W H
conv_layer = torch.nn.Conv2d(in_channels=1, out_channels=1, kernel_size=3, padding=1, bias=False) # O I W H
kernel = torch.Tensor([1, 2, 3, 4, 5, 6, 7, 8, 9]).view(1, 1, 3, 3)
conv_layer.weight.data = kernel.data
output = conv_layer(input)
print(output)
tensor([[[[ 91., 168., 224., 215., 127.],
[114., 211., 295., 262., 149.],
[192., 259., 282., 214., 122.],
[194., 251., 253., 169., 86.],
[ 96., 112., 110., 68., 31.]]]], grad_fn=<ConvolutionBackward0>)
9.3.4 Stride
参数 stride 意为步长,假设 s t r i d e = 2 stride = 2 stride=2 时,kernel在向右或向下移动时,一次性移动两格,可以有效的降低图像的宽度和高度。
import torch
input = [3, 4, 6, 5, 7,
2, 4, 6, 8, 2,
1, 6, 7, 8, 4,
9, 7, 4, 6, 2,
3, 7, 5, 4, 1]
input = torch.Tensor(input).view(1, 1, 5, 5) # B C W H
conv_layer = torch.nn.Conv2d(in_channels=1, out_channels=1, kernel_size=3, stride=2, bias=False) # O I W H
kernel = torch.Tensor([1, 2, 3, 4, 5, 6, 7, 8, 9]).view(1, 1, 3, 3)
conv_layer.weight.data = kernel.data
output = conv_layer(input)
print(output)
tensor([[[[211., 262.],
[251., 169.]]]], grad_fn=<ConvolutionBackward0>)
9.4 Max Pooling
Max Pooling:最大池化,默认 s t r i d e = 2 stride = 2 stride=2 ,若 k e r n e l = 2 × 2 kernel = 2 \times 2 kernel=2×2 ,即在该表格中找出最大值:
import torch
input = [3, 4, 6, 5,
2, 4, 6, 8,
1, 6, 7, 8,
9, 7, 4, 6]
input = torch.Tensor(input).view(1, 1, 4, 4)
maxpooling_layer = torch.nn.MaxPool2d(kernel_size=2)
output = maxpooling_layer(input)
print(output)
tensor([[[[4., 8.],
[9., 8.]]]])
9.5 A Simple CNN
下图为一个简单的神经网络:
即:
代码如下:
class Net(torch.nn.Module):
def __init__(self):
super(Net, self).__init__()
self.conv1 = torch.nn.Conv2d(1, 10, kernel_size=5)
self.conv2 = torch.nn.Conv2d(10, 20, kernel_size=5)
self.pooling = torch.nn.MaxPool2d(2)
self.fc = torch.nn.Linear(320, 10)
def forward(self, x):
# Flatten data from (n, 1, 28, 28) to (n, 784)
batch_size = x.size(0)
x = F.relu(self.pooling(self.conv1(x)))
x = F.relu(self.pooling(self.conv2(x)))
x = x.view(batch_size, -1) # flatten
x = self.fc(x)
return x
model = Net()
9.5.1 GPU
使用GPU来跑数据的前提:安装CUDA版PyTorch
- Move Model to GPU :在调用模型后添加以下代码
device = torch.device("cuda:0" if torch.cuda.is_available() else "cpu")
model.to(device)
- Move Tensors to GPU :训练和测试函数添加以下代码
inputs, target = inputs.to(device), target.to(device)
9.5.2 Code 1
import torch
from torchvision import transforms
from torch.utils.data import DataLoader
from torchvision import datasets
import torch.nn.functional as F
import torch.optim as optim
import matplotlib.pyplot as plt
batch_size = 64
transform = transforms.Compose([
transforms.ToTensor(),
transforms.Normalize((0.1307,), (0.3081,))
])
train_dataset = datasets.MNIST(root='../data/mnist', train=True, download=True, transform=transform)
train_loader = DataLoader(train_dataset, shuffle=True, batch_size=batch_size)
test_dataset = datasets.MNIST(root='../data/mnist', train=False, download=True, transform=transform)
test_loader = DataLoader(test_dataset, shuffle=False, batch_size=batch_size)
class Net(torch.nn.Module):
def __init__(self):
super(Net, self).__init__()
self.conv1 = torch.nn.Conv2d(1, 10, kernel_size=5)
self.conv2 = torch.nn.Conv2d(10, 20, kernel_size=5)
self.pooling = torch.nn.MaxPool2d(2)
self.fc = torch.nn.Linear(320, 10)
def forward(self, x):
# Flatten data from (n, 1, 28, 28) to (n, 784)
batch_size = x.size(0)
x = F.relu(self.pooling(self.conv1(x)))
x = F.relu(self.pooling(self.conv2(x)))
x = x.view(batch_size, -1) # flatten
x = self.fc(x)
return x
model = Net()
device = torch.device("cuda:0" if torch.cuda.is_available() else "cpu") # GPU
model.to(device)
criterion = torch.nn.CrossEntropyLoss()
optimizer = optim.SGD(model.parameters(), lr=0.01, momentum=0.5)
def train(epoch):
running_loss = 0.0
for batch_idx, data in enumerate(train_loader, 0):
inputs, target = data
inputs, target = inputs.to(device), target.to(device) # GPU
optimizer.zero_grad()
# forward + backward + update
outputs = model(inputs)
loss = criterion(outputs, target)
loss.backward()
optimizer.step()
running_loss += loss.item()
if batch_idx % 300 == 299:
print('[%d, %3d] loss: %.3f' % (epoch + 1, batch_idx + 1, running_loss / 2000))
running_loss = 0.0
accuracy = []
def test():
correct = 0
total = 0
with torch.no_grad():
for data in test_loader:
inputs, target = data
inputs, target = inputs.to(device), target.to(device) # GPU
outputs = model(inputs)
_, predicted = torch.max(outputs.data, dim=1)
total += target.size(0)
correct += (predicted == target).sum().item()
print('Accuracy on test set: %d %% [%d/%d]' % (100 * correct / total, correct, total))
accuracy.append(100 * correct / total)
if __name__ == '__main__':
for epoch in range(10):
train(epoch)
test()
print(accuracy)
plt.plot(range(10), accuracy)
plt.xlabel("Epoch")
plt.ylabel("Accuracy")
plt.grid()
plt.show()
[1, 300] loss: 0.091
[1, 600] loss: 0.027
[1, 900] loss: 0.020
Accuracy on test set: 97 % [9700/10000]
[2, 300] loss: 0.017
[2, 600] loss: 0.014
[2, 900] loss: 0.013
Accuracy on test set: 97 % [9799/10000]
[3, 300] loss: 0.012
[3, 600] loss: 0.011
[3, 900] loss: 0.011
Accuracy on test set: 98 % [9813/10000]
[4, 300] loss: 0.010
[4, 600] loss: 0.009
[4, 900] loss: 0.009
Accuracy on test set: 98 % [9838/10000]
[5, 300] loss: 0.008
[5, 600] loss: 0.008
[5, 900] loss: 0.008
Accuracy on test set: 98 % [9846/10000]
[6, 300] loss: 0.007
[6, 600] loss: 0.008
[6, 900] loss: 0.007
Accuracy on test set: 98 % [9858/10000]
[7, 300] loss: 0.006
[7, 600] loss: 0.007
[7, 900] loss: 0.007
Accuracy on test set: 98 % [9869/10000]
[8, 300] loss: 0.006
[8, 600] loss: 0.006
[8, 900] loss: 0.006
Accuracy on test set: 98 % [9869/10000]
[9, 300] loss: 0.006
[9, 600] loss: 0.006
[9, 900] loss: 0.006
Accuracy on test set: 98 % [9849/10000]
[10, 300] loss: 0.005
[10, 600] loss: 0.005
[10, 900] loss: 0.005
Accuracy on test set: 98 % [9849/10000]
[97.0, 97.99, 98.13, 98.38, 98.46, 98.58, 98.69, 98.69, 98.49, 98.49]
9.5.3 Exercise
若对该神经网络进行改进:
- Conv2d Layer * 3
- ReLU Layer * 3
- MaxPooling Layer * 3
- Linear Layer * 3
i n p u t : 1 × 28 × 28 c o n v o l u t i o n : 28 − 5 + 1 = 24 , t o : 16 × 24 × 24 p o o l i n g : 16 × 12 × 12 c o n v o l u t i o n : 12 − 5 + 1 = 8 , t o : 32 × 8 × 8 p o o l i n g : 20 × 4 × 4 c o n v o l u t i o n : 4 − 3 + 1 = 2 , t o : 64 × 2 × 2 p o o l i n g : 64 × 1 × 1 f c : 64 − − 32 − − 16 − − 10 input: 1 \times 28 \times 28 \\ convolution: 28 -5 +1 = 24, to: 16 \times 24 \times 24 \\ pooling: 16 \times 12 \times 12 \\ convolution: 12 -5 +1 = 8, to: 32 \times 8 \times 8 \\ pooling: 20 \times 4 \times 4 \\ convolution: 4 -3 +1 = 2, to: 64 \times 2 \times 2 \\ pooling: 64 \times 1 \times 1 \\ fc: 64 -- 32 -- 16 -- 10 input:1×28×28convolution:28−5+1=24,to:16×24×24pooling:16×12×12convolution:12−5+1=8,to:32×8×8pooling:20×4×4convolution:4−3+1=2,to:64×2×2pooling:64×1×1fc:64−−32−−16−−10
9.5.4 Code 2
将神经网络改成如下即可:
def __init__(self):
super(Net, self).__init__()
self.conv1 = torch.nn.Conv2d(1, 16, kernel_size=5)
self.conv2 = torch.nn.Conv2d(16, 32, kernel_size=5)
self.conv3 = torch.nn.Conv2d(32, 64, kernel_size=3)
self.pooling = torch.nn.MaxPool2d(2)
self.fc1 = torch.nn.Linear(64, 32)
self.fc2 = torch.nn.Linear(32, 16)
self.fc3 = torch.nn.Linear(16, 10)
def forward(self, x):
batch_size = x.size(0)
x = self.pooling(F.relu(self.conv1(x)))
x = self.pooling(F.relu(self.conv2(x)))
x = self.pooling(F.relu(self.conv3(x)))
x = x.view(batch_size, -1)
x = F.relu(self.fc1(x))
x = F.relu(self.fc2(x))
x = self.fc3(x)
return x
[1, 300] loss: 0.345
[1, 600] loss: 0.273
[1, 900] loss: 0.069
Accuracy on test set: 91 % [9194/10000]
[2, 300] loss: 0.034
[2, 600] loss: 0.025
[2, 900] loss: 0.020
Accuracy on test set: 96 % [9670/10000]
[3, 300] loss: 0.015
[3, 600] loss: 0.015
[3, 900] loss: 0.014
Accuracy on test set: 97 % [9754/10000]
[4, 300] loss: 0.011
[4, 600] loss: 0.010
[4, 900] loss: 0.011
Accuracy on test set: 98 % [9810/10000]
[5, 300] loss: 0.008
[5, 600] loss: 0.009
[5, 900] loss: 0.009
Accuracy on test set: 98 % [9808/10000]
[6, 300] loss: 0.008
[6, 600] loss: 0.007
[6, 900] loss: 0.008
Accuracy on test set: 98 % [9859/10000]
[7, 300] loss: 0.006
[7, 600] loss: 0.006
[7, 900] loss: 0.007
Accuracy on test set: 98 % [9862/10000]
[8, 300] loss: 0.005
[8, 600] loss: 0.006
[8, 900] loss: 0.006
Accuracy on test set: 97 % [9784/10000]
[9, 300] loss: 0.005
[9, 600] loss: 0.005
[9, 900] loss: 0.006
Accuracy on test set: 98 % [9842/10000]
[10, 300] loss: 0.005
[10, 600] loss: 0.005
[10, 900] loss: 0.004
Accuracy on test set: 98 % [9878/10000]
[91.94, 96.7, 97.54, 98.1, 98.08, 98.59, 98.62, 97.84, 98.42, 98.78]
9.6 GoogLeNet
注意:Convolution 、 Pooling 、 Softmax、 Other
若以上图来编写神经网络,则会有许多重复,为减少代码冗余,可以尽量多使用函数/类。
9.6.1 Inception Module
构造神经网络时,有一些超参数是难以选择的,比如卷积核Kernel,应该选择哪一种卷积核比较好用?
GoogLeNet在一个块中将几种卷积核( 1 × 1 、 3 × 3 、 5 × 5 、 . . . 1 \times 1 、 3 \times 3 、 5 \times 5 、... 1×1、3×3、5×5、...)都使用,然后将其结果罗列到一起,将来通过训练自动找到一种最优的组合。
-
Concatenate:将张量拼接到一块
-
Average Pooling 均值池化:保证输入输出宽高一致(可借助padding和stride)
9.6.2 1 x 1 convolution
为什么要引入 $1 \times 1 $ convolution ?
见上图:若 i n p u t = 192 × 28 × 28 , o u t p u t = 32 × 28 × 28 input = 192 \times 28 \times 28, output = 32 \times 28 \times 28 input=192×28×28,output=32×28×28 ,则计算量 O p e r a t i o n s = 5 2 × 2 8 2 × 192 × 32 = 120 , 422 , 400 Operations = 5^2 \times 28^2 \times 192 \times 32 = 120,422,400 Operations=52×282×192×32=120,422,400
见上图:若在其中间使用 c o n v o l u t i o n : 1 × 1 convolution: 1 \times 1 convolution:1×1 ,则计算量 O p e r a t i o n s = 1 2 × 2 8 2 × 192 × 16 + 5 2 × 2 8 2 × 16 × 32 = 12 , 433 , 648 Operations = 1^2 \times 28^2 \times 192 \times 16 + 5^2 \times 28^2 \times 16 \times 32 = 12,433,648 Operations=12×282×192×16+52×282×16×32=12,433,648
9.6.3 Implementation of Inception Module
计算方向:由下至上
# 第一列
self.branch_pool = nn.Conv2d(in_channels, 24, kernel_size=1)
branch_pool = F.avg_pool2d(x, kernel_size=3, stride=1, padding=1)
branch_pool = self.branch_pool(branch_pool)
# 第二列
self.branch1x1 = nn.Conv2d(in_channels, 16, kernel_size=1)
branch1x1 = self.branch1x1(x)
# 第三列
self.branch5x5_1 = nn.Conv2d(in_channels,16, kernel_size=1)
self.branch5x5_2 = nn.Conv2d(16, 24, kernel_size=5, padding=2)
branch5x5 = self.branch5x5_1(x)
branch5x5 = self.branch5x5_2(branch5x5)
# 第四列
self.branch3x3_1 = nn.Conv2d(in_channels, 16, kernel_size=1)
self.branch3x3_2 = nn.Conv2d(16, 24, kernel_size=3, padding=1)
self.branch3x3_3 = nn.Conv2d(24, 24, kernel_size=3, padding=1)
branch3x3 = self.branch3x3_1(x)
branch3x3 = self.branch3x3_2(branch3x3)
branch3x3 = self.branch3x3_3(branch3x3)
再进行拼接:
outputs = [branch1x1, branch5x5, branch3x3, branch_pool]
return torch.cat(outputs, dim=1)
Using Inception Module:
class InceptionA(nn.Module):
def __init__(self, in_channels):
super(InceptionA, self).__init__()
self.branch1x1 = nn.Conv2d(in_channels, 16, kernel_size=1)
self.branch5x5_1 = nn.Conv2d(in_channels, 16, kernel_size=1)
self.branch5x5_2 = nn.Conv2d(16, 24, kernel_size=5, padding=2)
self.branch3x3_1 = nn.Conv2d(in_channels, 16, kernel_size=1)
self.branch3x3_2 = nn.Conv2d(16, 24, kernel_size=3, padding=1)
self.branch3x3_3 = nn.Conv2d(24, 24, kernel_size=3, padding=1)
self.branch_pool = nn.Conv2d(in_channels, 24, kernel_size=1)
def forward(self, x):
branch1x1 = self.branch1x1(x)
branch5x5 = self.branch5x5_1(x)
branch5x5 = self.branch5x5_2(branch5x5)
branch3x3 = self.branch3x3_1(x)
branch3x3 = self.branch3x3_2(branch3x3)
branch3x3 = self.branch3x3_3(branch3x3)
branch_pool = F.avg_pool2d(x, kernel_size=3, stride=1, padding=1)
branch_pool = self.branch_pool(branch_pool)
outputs = [branch1x1, branch5x5, branch3x3, branch_pool]
return torch.cat(outputs, dim=1)
class Net(nn.Module):
def __init__(self):
super(Net, self).__init__()
self.conv1 = nn.Conv2d(1, 10, kernel_size=5)
self.conv2 = nn.Conv2d(88, 20, kernel_size=5)
self.incep1 = InceptionA(in_channels=10)
self.incep2 = InceptionA(in_channels=20)
self.mp = nn.MaxPool2d(2)
self.fc = nn.Linear(1408, 10)
def forward(self, x):
in_size = x.size(0)
x = F.relu(self.mp(self.conv1(x)))
x = self.incep1(x)
x = F.relu(self.mp(self.conv2(x)))
x = self.incep2(x)
x = x.view(in_size, -1)
x = self.fc(x)
return x
完整代码:
import torch
from torch import nn
from torchvision import transforms
from torchvision import datasets
from torch.utils.data import DataLoader
import torch.nn.functional as F
import torch.optim as optim
import matplotlib.pyplot as plt
# 1、准备数据集
batch_size = 64
transform = transforms.Compose([
transforms.ToTensor(),
transforms.Normalize((0.1307,), (0.3081,))
])
train_dataset = datasets.MNIST(root='../data/mnist', train=True, download=True, transform=transform)
train_loader = DataLoader(train_dataset, shuffle=True, batch_size=batch_size)
test_dataset = datasets.MNIST(root='../data/mnist', train=False, download=True, transform=transform)
test_loader = DataLoader(test_dataset, shuffle=False, batch_size=batch_size)
# 2、建立模型
# 定义一个Inception类
class InceptionA(nn.Module):
def __init__(self, in_channels):
super(InceptionA, self).__init__()
self.branch1X1 = nn.Conv2d(in_channels, 16, kernel_size=1)
# 设置padding保证 宽 高 不变
self.branch5X5_1 = nn.Conv2d(in_channels, 16, kernel_size=1)
self.branch5X5_2 = nn.Conv2d(16, 24, kernel_size=5, padding=2)
self.branch3X3_1 = nn.Conv2d(in_channels, 16, kernel_size=1)
self.branch3X3_2 = nn.Conv2d(16, 24, kernel_size=3, padding=1)
self.branch3X3_3 = nn.Conv2d(24, 24, kernel_size=3, padding=1)
self.branch_pool = nn.Conv2d(in_channels, 24, kernel_size=1)
def forward(self, x):
branch1X1 = self.branch1X1(x)
branch5X5 = self.branch5X5_1(x)
branch5X5 = self.branch5X5_2(branch5X5)
branch3X3 = self.branch3X3_1(x)
branch3X3 = self.branch3X3_2(branch3X3)
branch3X3 = self.branch3X3_3(branch3X3)
branch_pool = F.avg_pool2d(x, kernel_size=3, stride=1, padding=1)
branch_pool = self.branch_pool(branch_pool)
outputs = [branch1X1, branch5X5, branch3X3, branch_pool]
# (b, c, w, h),dim=1 以第一个维度channel来拼接
return torch.cat(outputs, dim=1)
# 定义模型
class Net(nn.Module):
def __init__(self):
super(Net, self).__init__()
self.conv1 = nn.Conv2d(1, 10, kernel_size=5)
# 88 = 24*3 + 16
self.conv2 = nn.Conv2d(88, 20, kernel_size=5)
self.incep1 = InceptionA(in_channels=10)
self.incep2 = InceptionA(in_channels=20)
self.mp = nn.MaxPool2d(2)
# 确定输出张量的尺寸
# 在定义时先不定义fc层,随便选取一个输入,经过模型后查看其尺寸
# 在init函数中把fc层去掉,forward函数中把最后两行去掉,确定输出的尺寸后再定义Lear层的大小
self.fc = nn.Linear(1408, 10)
def forward(self, x):
in_size = x.size(0)
# 1 --> 10
x = F.relu(self.mp(self.conv1(x)))
# 10 --> 88
x = self.incep1(x)
# 88 --> 20
x = F.relu(self.mp(self.conv2(x)))
# 20 --> 88
x = self.incep2(x)
x = x.view(in_size, -1)
x = self.fc(x)
return x
model = Net()
# 将模型迁移到GPU上运行
device = torch.device("cuda:0" if torch.cuda.is_available() else "cpu")
model.to(device)
# 3、建立损失函数和优化器
criterion = torch.nn.CrossEntropyLoss()
optimizer = optim.SGD(model.parameters(), lr=0.01, momentum=0.5)
# 4、定义训练函数
def train(epoch):
running_loss = 0
for batch_idx, data in enumerate(train_loader, 0):
inputs, target = data
# 将计算的张量迁移到GPU上
inputs, target = inputs.to(device), target.to(device)
optimizer.zero_grad()
# 前馈 反馈 更新
outputs = model(inputs)
loss = criterion(outputs, target)
loss.backward()
optimizer.step()
running_loss += loss.item()
if batch_idx % 300 == 299:
print('[%d, %3d] loss: %.3f' % (epoch + 1, batch_idx + 1, running_loss / 300))
running_loss = 0
# 5、定义测试函数
accuracy = []
def test():
correct = 0
total = 0
with torch.no_grad():
for data in test_loader:
images, labels = data
# 将测试中的张量迁移到GPU上
images, labels = images.to(device), labels.to(device)
outputs = model(images)
_, predicted = torch.max(outputs.data, dim=1)
total += labels.size(0)
# 得出其中相等元素的个数
correct += (predicted == labels).sum().item()
print('Accuracy on test set: %d %% [%d/%d]' % (100 * correct / total, correct, total))
accuracy.append(100 * correct / total)
if __name__ == '__main__':
for epoch in range(10):
train(epoch)
test()
print(accuracy)
plt.plot(range(10), accuracy)
plt.xlabel("Epoch")
plt.ylabel("Accuracy")
plt.grid() # 表格
plt.show()
[1, 300] loss: 0.836
[1, 600] loss: 0.196
[1, 900] loss: 0.145
Accuracy on test set: 96 % [9690/10000]
[2, 300] loss: 0.106
[2, 600] loss: 0.099
[2, 900] loss: 0.091
Accuracy on test set: 97 % [9785/10000]
[3, 300] loss: 0.075
[3, 600] loss: 0.078
[3, 900] loss: 0.071
Accuracy on test set: 98 % [9831/10000]
[4, 300] loss: 0.064
[4, 600] loss: 0.067
[4, 900] loss: 0.061
Accuracy on test set: 98 % [9845/10000]
[5, 300] loss: 0.057
[5, 600] loss: 0.058
[5, 900] loss: 0.052
Accuracy on test set: 98 % [9846/10000]
[6, 300] loss: 0.051
[6, 600] loss: 0.049
[6, 900] loss: 0.050
Accuracy on test set: 98 % [9852/10000]
[7, 300] loss: 0.047
[7, 600] loss: 0.043
[7, 900] loss: 0.045
Accuracy on test set: 98 % [9848/10000]
[8, 300] loss: 0.039
[8, 600] loss: 0.044
[8, 900] loss: 0.042
Accuracy on test set: 98 % [9871/10000]
[9, 300] loss: 0.041
[9, 600] loss: 0.034
[9, 900] loss: 0.041
Accuracy on test set: 98 % [9866/10000]
[10, 300] loss: 0.032
[10, 600] loss: 0.038
[10, 900] loss: 0.037
Accuracy on test set: 98 % [9881/10000]
[96.9, 97.85, 98.31, 98.45, 98.46, 98.52, 98.48, 98.71, 98.66, 98.81]
9.7 Residual Net
如果将 3 × 3 3 \times 3 3×3 的卷积一直堆下去,该神经网络的性能会不会更好?
Paper:He K, Zhang X, Ren S, et al. Deep Residual Learning for Image Recognition[C]// IEEE Conference on Computer Vision and Pattern Recognition. IEEE Computer Society, 2016:770-778.
研究发现:20 层的错误率低于56 层的错误率,所以并不是层数越多,性能越好。为解决 梯度消失 的问题,见下图:
多一个 跳连接 :
9.7.1 Residual Network
class Net(nn.Module):
def __init__(self):
super(Net, self).__init__()
self.conv1 = nn.Conv2d(1, 16, kernel_size=5)
self.conv2 = nn.Conv2d(16, 32, kernel_size=5)
self.mp = nn.MaxPool2d(2)
self.rblock1 = ResidualBlock(16)
self.rblock2 = ResidualBlock(32)
self.fc = nn.Linear(512, 10)
def forward(self, x):
in_size = x.size(0)
x = self.mp(F.relu(self.conv1(x)))
x = self.rblock1(x)
x = self.mp(F.relu(self.conv2(x)))
x = self.rblock2(x)
x = x.view(in_size, -1)
x = self.fc(x)
return x
9.7.2 Residual Block
class ResidualBlock(nn.Module):
def __init__(self, channels):
super(ResidualBlock, self).__init__()
self.channels = channels
self.conv1 = nn.Conv2d(channels, channels, kernel_size=3, padding=1)
self.conv2 = nn.Conv2d(channels, channels, kernel_size=3, padding=1)
def forward(self, x):
y = F.relu(self.conv1(x))
y = self.conv2(y)
return F.relu(x + y)
9.7.3 Code 3
import torch
from torch import nn
from torchvision import transforms
from torchvision import datasets
from torch.utils.data import DataLoader
import torch.nn.functional as F
import torch.optim as optim
import matplotlib.pyplot as plt
batch_size = 64
transform = transforms.Compose([
transforms.ToTensor(),
transforms.Normalize((0.1307,), (0.3081,))
])
train_dataset = datasets.MNIST(root='../data/mnist', train=True, download=True, transform=transform)
train_loader = DataLoader(train_dataset, shuffle=True, batch_size=batch_size)
test_dataset = datasets.MNIST(root='../data/mnist', train=False, download=True, transform=transform)
test_loader = DataLoader(test_dataset, shuffle=False, batch_size=batch_size)
class ResidualBlock(nn.Module):
def __init__(self, channels):
super(ResidualBlock, self).__init__()
self.channels = channels
self.conv1 = nn.Conv2d(channels, channels, kernel_size=3, padding=1)
self.conv2 = nn.Conv2d(channels, channels, kernel_size=3, padding=1)
def forward(self, x):
y = F.relu(self.conv1(x))
y = self.conv2(y)
return F.relu(x + y)
class Net(nn.Module):
def __init__(self):
super(Net, self).__init__()
self.conv1 = nn.Conv2d(1, 16, kernel_size=5)
self.conv2 = nn.Conv2d(16, 32, kernel_size=5)
self.mp = nn.MaxPool2d(2)
self.rblock1 = ResidualBlock(16)
self.rblock2 = ResidualBlock(32)
self.fc = nn.Linear(512, 10)
def forward(self, x):
in_size = x.size(0)
x = self.mp(F.relu(self.conv1(x)))
x = self.rblock1(x)
x = self.mp(F.relu(self.conv2(x)))
x = self.rblock2(x)
x = x.view(in_size, -1)
x = self.fc(x)
return x
model = Net()
device = torch.device("cuda:0" if torch.cuda.is_available() else "cpu")
model.to(device)
criterion = torch.nn.CrossEntropyLoss()
optimizer = optim.SGD(model.parameters(), lr=0.01, momentum=0.5)
def train(epoch):
running_loss = 0
for batch_idx, data in enumerate(train_loader, 0):
inputs, target = data
inputs, target = inputs.to(device), target.to(device)
optimizer.zero_grad()
outputs = model(inputs)
loss = criterion(outputs, target)
loss.backward()
optimizer.step()
running_loss += loss.item()
if batch_idx % 300 == 299:
print('[%d, %3d] loss: %.3f' % (epoch + 1, batch_idx + 1, running_loss / 300))
running_loss = 0
accuracy = []
def test():
correct = 0
total = 0
with torch.no_grad():
for data in test_loader:
images, labels = data
images, labels = images.to(device), labels.to(device)
outputs = model(images)
_, predicted = torch.max(outputs.data, dim=1)
total += labels.size(0)
correct += (predicted == labels).sum().item()
print('Accuracy on test set: %d %% [%d/%d]' % (100 * correct / total, correct, total))
accuracy.append(100 * correct / total)
if __name__ == '__main__':
for epoch in range(10):
train(epoch)
test()
print(accuracy)
plt.plot(range(10), accuracy)
plt.xlabel("Epoch")
plt.ylabel("Accuracy")
plt.grid()
plt.show()
[1, 300] loss: 0.563
[1, 600] loss: 0.157
[1, 900] loss: 0.111
Accuracy on test set: 97 % [9721/10000]
[2, 300] loss: 0.085
[2, 600] loss: 0.077
[2, 900] loss: 0.081
Accuracy on test set: 98 % [9831/10000]
[3, 300] loss: 0.063
[3, 600] loss: 0.059
[3, 900] loss: 0.053
Accuracy on test set: 98 % [9841/10000]
[4, 300] loss: 0.047
[4, 600] loss: 0.052
[4, 900] loss: 0.042
Accuracy on test set: 98 % [9877/10000]
[5, 300] loss: 0.039
[5, 600] loss: 0.037
[5, 900] loss: 0.041
Accuracy on test set: 98 % [9871/10000]
[6, 300] loss: 0.035
[6, 600] loss: 0.032
[6, 900] loss: 0.035
Accuracy on test set: 98 % [9895/10000]
[7, 300] loss: 0.029
[7, 600] loss: 0.032
[7, 900] loss: 0.029
Accuracy on test set: 98 % [9899/10000]
[8, 300] loss: 0.026
[8, 600] loss: 0.028
[8, 900] loss: 0.025
Accuracy on test set: 98 % [9892/10000]
[9, 300] loss: 0.021
[9, 600] loss: 0.027
[9, 900] loss: 0.024
Accuracy on test set: 98 % [9886/10000]
[10, 300] loss: 0.019
[10, 600] loss: 0.021
[10, 900] loss: 0.023
Accuracy on test set: 99 % [9902/10000]
[97.21, 98.31, 98.41, 98.77, 98.71, 98.95, 98.99, 98.92, 98.86, 99.02]
9.7.4 Reading Paper
Paper 1:He K, Zhang X, Ren S, et al. Identity Mappings in Deep Residual Networks[C]
constant scaling:
class ResidualBlock(nn.Module):
def __init__(self, channels):
super(ResidualBlock, self).__init__()
self.channels = channels
self.conv1 = nn.Conv2d(channels, channels, kernel_size=3, padding=1)
self.conv2 = nn.Conv2d(channels, channels, kernel_size=3, padding=1)
def forward(self, x):
y = F.relu(self.conv1(x))
y = self.conv2(x)
z = 0.5 * (x + y)
return F.relu(z)
[1, 300] loss: 1.204
[1, 600] loss: 0.243
[1, 900] loss: 0.165
Accuracy on test set: 96 % [9637/10000]
[2, 300] loss: 0.121
[2, 600] loss: 0.105
[2, 900] loss: 0.099
Accuracy on test set: 97 % [9777/10000]
[3, 300] loss: 0.085
[3, 600] loss: 0.076
[3, 900] loss: 0.069
Accuracy on test set: 98 % [9815/10000]
[4, 300] loss: 0.061
[4, 600] loss: 0.063
[4, 900] loss: 0.063
Accuracy on test set: 98 % [9849/10000]
[5, 300] loss: 0.053
[5, 600] loss: 0.052
[5, 900] loss: 0.052
Accuracy on test set: 98 % [9853/10000]
[6, 300] loss: 0.041
[6, 600] loss: 0.051
[6, 900] loss: 0.047
Accuracy on test set: 98 % [9871/10000]
[7, 300] loss: 0.040
[7, 600] loss: 0.044
[7, 900] loss: 0.043
Accuracy on test set: 98 % [9869/10000]
[8, 300] loss: 0.039
[8, 600] loss: 0.038
[8, 900] loss: 0.037
Accuracy on test set: 98 % [9859/10000]
[9, 300] loss: 0.031
[9, 600] loss: 0.039
[9, 900] loss: 0.036
Accuracy on test set: 98 % [9875/10000]
[10, 300] loss: 0.035
[10, 600] loss: 0.031
[10, 900] loss: 0.033
Accuracy on test set: 98 % [9888/10000]
[96.37, 97.77, 98.15, 98.49, 98.53, 98.71, 98.69, 98.59, 98.75, 98.88]
conv shortcut:
class ResidualBlock(nn.Module):
def __init__(self, channels):
super(ResidualBlock, self).__init__()
self.channels = channels
self.conv1 = nn.Conv2d(channels, channels, kernel_size=3, padding=1)
self.conv2 = nn.Conv2d(channels, channels, kernel_size=3, padding=1)
self.conv3 = nn.Conv2d(channels, channels, kernel_size=1)
def forward(self, x):
y = F.relu(self.conv1(x))
y = self.conv2(x)
z = self.conv3(x) + y
return F.relu(z)
[1, 300] loss: 0.760
[1, 600] loss: 0.170
[1, 900] loss: 0.119
Accuracy on test set: 97 % [9717/10000]
[2, 300] loss: 0.092
[2, 600] loss: 0.084
[2, 900] loss: 0.075
Accuracy on test set: 98 % [9826/10000]
[3, 300] loss: 0.064
[3, 600] loss: 0.063
[3, 900] loss: 0.055
Accuracy on test set: 98 % [9817/10000]
[4, 300] loss: 0.048
[4, 600] loss: 0.047
[4, 900] loss: 0.048
Accuracy on test set: 98 % [9851/10000]
[5, 300] loss: 0.039
[5, 600] loss: 0.039
[5, 900] loss: 0.044
Accuracy on test set: 98 % [9864/10000]
[6, 300] loss: 0.035
[6, 600] loss: 0.033
[6, 900] loss: 0.038
Accuracy on test set: 98 % [9890/10000]
[7, 300] loss: 0.030
[7, 600] loss: 0.030
[7, 900] loss: 0.030
Accuracy on test set: 98 % [9881/10000]
[8, 300] loss: 0.027
[8, 600] loss: 0.026
[8, 900] loss: 0.029
Accuracy on test set: 98 % [9884/10000]
[9, 300] loss: 0.021
[9, 600] loss: 0.026
[9, 900] loss: 0.025
Accuracy on test set: 98 % [9894/10000]
[10, 300] loss: 0.019
[10, 600] loss: 0.019
[10, 900] loss: 0.025
Accuracy on test set: 98 % [9897/10000]
[97.17, 98.26, 98.17, 98.51, 98.64, 98.9, 98.81, 98.84, 98.94, 98.97]
Paper 2:Huang G, Liu Z, Laurens V D M, et al. Densely Connected Convolutional Networks[J]. 2016:2261-2269.