轻松学Pytorch-使用卷积神经网络实现图像分类
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本文转自|人工智能与算法学习
大家好,本篇教程的贡献者来自社区投稿作者【陨星落云】,使用CIFAR-10数据集进行图像分类。该数据集中的图像是彩色小图像,其中被分为了十类。一些示例图像,如下图所示:
测试GPU是否可以使用
数据集中的图像大小为32x32x3 。在训练的过程中最好使用GPU来加速。
1import torch
2import numpy as np
3
4# 检查是否可以利用GPU
5train_on_gpu = torch.cuda.is_available()
6
7if not train_on_gpu:
8 print('CUDA is not available.')
9else:
10 print('CUDA is available!')
结果:
CUDA is available!
加载数据
数据下载可能会比较慢。请耐心等待。加载训练和测试数据,将训练数据分为训练集和验证集,然后为每个数据集创建DataLoader。
1from torchvision import datasets
2import torchvision.transforms as transforms
3from torch.utils.data.sampler import SubsetRandomSampler
4
5# number of subprocesses to use for data loading
6num_workers = 0
7# 每批加载16张图片
8batch_size = 16
9# percentage of training set to use as validation
10valid_size = 0.2
11
12# 将数据转换为torch.FloatTensor,并标准化。
13transform = transforms.Compose([
14 transforms.ToTensor(),
15 transforms.Normalize((0.5, 0.5, 0.5), (0.5, 0.5, 0.5))
16 ])
17
18# 选择训练集与测试集的数据
19train_data = datasets.CIFAR10('data', train=True,
20 download=True, transform=transform)
21test_data = datasets.CIFAR10('data', train=False,
22 download=True, transform=transform)
23
24# obtain training indices that will be used for validation
25num_train = len(train_data)
26indices = list(range(num_train))
27np.random.shuffle(indices)
28split = int(np.floor(valid_size * num_train))
29train_idx, valid_idx = indices[split:], indices[:split]
30
31# define samplers for obtaining training and validation batches
32train_sampler = SubsetRandomSampler(train_idx)
33valid_sampler = SubsetRandomSampler(valid_idx)
34
35# prepare data loaders (combine dataset and sampler)
36train_loader = torch.utils.data.DataLoader(train_data, batch_size=batch_size,
37 sampler=train_sampler, num_workers=num_workers)
38valid_loader = torch.utils.data.DataLoader(train_data, batch_size=batch_size,
39 sampler=valid_sampler, num_workers=num_workers)
40test_loader = torch.utils.data.DataLoader(test_data, batch_size=batch_size,
41 num_workers=num_workers)
42
43# 图像分类中10类别
44classes = ['airplane', 'automobile', 'bird', 'cat', 'deer',
45 'dog', 'frog', 'horse', 'ship', 'truck']
查看训练集中的一批样本
1import matplotlib.pyplot as plt
2%matplotlib inline
3
4# helper function to un-normalize and display an image
5def imshow(img):
6 img = img / 2 + 0.5 # unnormalize
7 plt.imshow(np.transpose(img, (1, 2, 0))) # convert from Tensor image
8
9# 获取一批样本
10dataiter = iter(train_loader)
11images, labels = dataiter.next()
12images = images.numpy() # convert images to numpy for display
13
14# 显示图像,标题为类名
15fig = plt.figure(figsize=(25, 4))
16# 显示16张图片
17for idx in np.arange(16):
18 ax = fig.add_subplot(2, 16/2, idx+1, xticks=[], yticks=[])
19 imshow(images[idx])
20 ax.set_title(classes[labels[idx]])
结果:
查看一张图像中的更多细节
在这里,进行了归一化处理。红色、绿色和蓝色(RGB)颜色通道可以被看作三个单独的灰度图像。
1rgb_img = np.squeeze(images[3])
2channels = ['red channel', 'green channel', 'blue channel']
3
4fig = plt.figure(figsize = (36, 36))
5for idx in np.arange(rgb_img.shape[0]):
6 ax = fig.add_subplot(1, 3, idx + 1)
7 img = rgb_img[idx]
8 ax.imshow(img, cmap='gray')
9 ax.set_title(channels[idx])
10 width, height = img.shape
11 thresh = img.max()/2.5
12 for x in range(width):
13 for y in range(height):
14 val = round(img[x][y],2) if img[x][y] !=0 else 0
15 ax.annotate(str(val), xy=(y,x),
16 horizontalalignment='center',
17 verticalalignment='center', size=8,
18 color='white' if img[x][y]结果:
定义卷积神经网络的结构
这里,将定义一个CNN的结构。将包括以下内容:
卷积层:可以认为是利用图像的多个滤波器(经常被称为卷积操作)进行滤波,得到图像的特征。
通常,我们在 PyTorch 中使用
nn.Conv2d定义卷积层,并指定以下参数:1nn.Conv2d(in_channels, out_channels, kernel_size, stride=1, padding=0)
用 3x3 窗口和步长 1 进行卷积运算
-
in_channels是指输入深度。对于灰阶图像来说,深度 = 1out_channels是指输出深度,或你希望获得的过滤图像数量kernel_size是卷积核的大小(通常为 3,表示 3x3 核)stride和padding具有默认值,但是应该根据你希望输出在空间维度 x, y 里具有的大小设置它们的值。
池化层:这里采用的最大池化:对指定大小的窗口里的像素值最大值。
在 2x2 窗口里,取这四个值的最大值。
由于最大池化更适合发现图像边缘等重要特征,适合图像分类任务。
最大池化层通常位于卷积层之后,用于缩小输入的 x-y 维度 。
通常的“线性+dropout”层可避免过拟合,并产生输出10类别。
下图中,可以看到这是一个具有2个卷积层的神经网络。
卷积层的输出大小
要计算给定卷积层的输出大小,我们可以执行以下计算:
这里,假设输入大小为(H,W),滤波器大小为(FH,FW),输出大小为 (OH,OW),填充为P,步幅为S。此时,输出大小可通过下面公式进行计算。
例: 输入大小为(H=7,W=7),滤波器大小为(FH=3,FW=3),填充为P=0,步幅为S=1, 输出大小为 (OH=5,OW=5)。如果用 S=2,将得输出大小为 (OH=3,OW=3)。
1import torch.nn as nn
2import torch.nn.functional as F
3
4# 定义卷积神经网络结构
5class Net(nn.Module):
6 def __init__(self):
7 super(Net, self).__init__()
8 # 卷积层 (32x32x3的图像)
9 self.conv1 = nn.Conv2d(3, 16, 3, padding=1)
10 # 卷积层(16x16x16)
11 self.conv2 = nn.Conv2d(16, 32, 3, padding=1)
12 # 卷积层(8x8x32)
13 self.conv3 = nn.Conv2d(32, 64, 3, padding=1)
14 # 最大池化层
15 self.pool = nn.MaxPool2d(2, 2)
16 # linear layer (64 * 4 * 4 -> 500)
17 self.fc1 = nn.Linear(64 * 4 * 4, 500)
18 # linear layer (500 -> 10)
19 self.fc2 = nn.Linear(500, 10)
20 # dropout层 (p=0.3)
21 self.dropout = nn.Dropout(0.3)
22
23 def forward(self, x):
24 # add sequence of convolutional and max pooling layers
25 x = self.pool(F.relu(self.conv1(x)))
26 x = self.pool(F.relu(self.conv2(x)))
27 x = self.pool(F.relu(self.conv3(x)))
28 # flatten image input
29 x = x.view(-1, 64 * 4 * 4)
30 # add dropout layer
31 x = self.dropout(x)
32 # add 1st hidden layer, with relu activation function
33 x = F.relu(self.fc1(x))
34 # add dropout layer
35 x = self.dropout(x)
36 # add 2nd hidden layer, with relu activation function
37 x = self.fc2(x)
38 return x
39
40# create a complete CNN
41model = Net()
42print(model)
43
44# 使用GPU
45if train_on_gpu:
46 model.cuda()
结果:
1Net(
2 (conv1): Conv2d(3, 16, kernel_size=(3, 3), stride=(1, 1), padding=(1, 1))
3 (conv2): Conv2d(16, 32, kernel_size=(3, 3), stride=(1, 1), padding=(1, 1))
4 (conv3): Conv2d(32, 64, kernel_size=(3, 3), stride=(1, 1), padding=(1, 1))
5 (pool): MaxPool2d(kernel_size=2, stride=2, padding=0, dilation=1, ceil_mode=False)
6 (fc1): Linear(in_features=1024, out_features=500, bias=True)
7 (fc2): Linear(in_features=500, out_features=10, bias=True)
8 (dropout): Dropout(p=0.3, inplace=False)
9)
选择损失函数与优化函数
1import torch.optim as optim
2# 使用交叉熵损失函数
3criterion = nn.CrossEntropyLoss()
4# 使用随机梯度下降,学习率lr=0.01
5optimizer = optim.SGD(model.parameters(), lr=0.01)
训练卷积神经网络模型
注意:训练集和验证集的损失是如何随着时间的推移而减少的;如果验证损失不断增加,则表明可能过拟合现象。(实际上,在下面的例子中,如果n_epochs设置为40,可以发现存在过拟合现象!)
1# 训练模型的次数
2n_epochs = 30
3
4valid_loss_min = np.Inf # track change in validation loss
5
6for epoch in range(1, n_epochs+1):
7
8 # keep track of training and validation loss
9 train_loss = 0.0
10 valid_loss = 0.0
11
12 ###################
13 # 训练集的模型 #
14 ###################
15 model.train()
16 for data, target in train_loader:
17 # move tensors to GPU if CUDA is available
18 if train_on_gpu:
19 data, target = data.cuda(), target.cuda()
20 # clear the gradients of all optimized variables
21 optimizer.zero_grad()
22 # forward pass: compute predicted outputs by passing inputs to the model
23 output = model(data)
24 # calculate the batch loss
25 loss = criterion(output, target)
26 # backward pass: compute gradient of the loss with respect to model parameters
27 loss.backward()
28 # perform a single optimization step (parameter update)
29 optimizer.step()
30 # update training loss
31 train_loss += loss.item()*data.size(0)
32
33 ######################
34 # 验证集的模型#
35 ######################
36 model.eval()
37 for data, target in valid_loader:
38 # move tensors to GPU if CUDA is available
39 if train_on_gpu:
40 data, target = data.cuda(), target.cuda()
41 # forward pass: compute predicted outputs by passing inputs to the model
42 output = model(data)
43 # calculate the batch loss
44 loss = criterion(output, target)
45 # update average validation loss
46 valid_loss += loss.item()*data.size(0)
47
48 # 计算平均损失
49 train_loss = train_loss/len(train_loader.sampler)
50 valid_loss = valid_loss/len(valid_loader.sampler)
51
52 # 显示训练集与验证集的损失函数
53 print('Epoch: {} \tTraining Loss: {:.6f} \tValidation Loss: {:.6f}'.format(
54 epoch, train_loss, valid_loss))
55
56 # 如果验证集损失函数减少,就保存模型。
57 if valid_loss <= valid_loss_min:
58 print('Validation loss decreased ({:.6f} --> {:.6f}). Saving model ...'.format(
59 valid_loss_min,
60 valid_loss))
61 torch.save(model.state_dict(), 'model_cifar.pt')
62 valid_loss_min = valid_loss
结果:
1Epoch: 1 Training Loss: 2.065666 Validation Loss: 1.706993
2Validation loss decreased (inf --> 1.706993). Saving model ...
3Epoch: 2 Training Loss: 1.609919 Validation Loss: 1.451288
4Validation loss decreased (1.706993 --> 1.451288). Saving model ...
5Epoch: 3 Training Loss: 1.426175 Validation Loss: 1.294594
6Validation loss decreased (1.451288 --> 1.294594). Saving model ...
7Epoch: 4 Training Loss: 1.307891 Validation Loss: 1.182497
8Validation loss decreased (1.294594 --> 1.182497). Saving model ...
9Epoch: 5 Training Loss: 1.200655 Validation Loss: 1.118825
10Validation loss decreased (1.182497 --> 1.118825). Saving model ...
11Epoch: 6 Training Loss: 1.115498 Validation Loss: 1.041203
12Validation loss decreased (1.118825 --> 1.041203). Saving model ...
13Epoch: 7 Training Loss: 1.047874 Validation Loss: 1.020686
14Validation loss decreased (1.041203 --> 1.020686). Saving model ...
15Epoch: 8 Training Loss: 0.991542 Validation Loss: 0.936289
16Validation loss decreased (1.020686 --> 0.936289). Saving model ...
17Epoch: 9 Training Loss: 0.942437 Validation Loss: 0.892730
18Validation loss decreased (0.936289 --> 0.892730). Saving model ...
19Epoch: 10 Training Loss: 0.894279 Validation Loss: 0.875833
20Validation loss decreased (0.892730 --> 0.875833). Saving model ...
21Epoch: 11 Training Loss: 0.859178 Validation Loss: 0.838847
22Validation loss decreased (0.875833 --> 0.838847). Saving model ...
23Epoch: 12 Training Loss: 0.822664 Validation Loss: 0.823634
24Validation loss decreased (0.838847 --> 0.823634). Saving model ...
25Epoch: 13 Training Loss: 0.787049 Validation Loss: 0.802566
26Validation loss decreased (0.823634 --> 0.802566). Saving model ...
27Epoch: 14 Training Loss: 0.749585 Validation Loss: 0.785852
28Validation loss decreased (0.802566 --> 0.785852). Saving model ...
29Epoch: 15 Training Loss: 0.721540 Validation Loss: 0.772729
30Validation loss decreased (0.785852 --> 0.772729). Saving model ...
31Epoch: 16 Training Loss: 0.689508 Validation Loss: 0.768470
32Validation loss decreased (0.772729 --> 0.768470). Saving model ...
33Epoch: 17 Training Loss: 0.662432 Validation Loss: 0.758518
34Validation loss decreased (0.768470 --> 0.758518). Saving model ...
35Epoch: 18 Training Loss: 0.632324 Validation Loss: 0.750859
36Validation loss decreased (0.758518 --> 0.750859). Saving model ...
37Epoch: 19 Training Loss: 0.616094 Validation Loss: 0.729692
38Validation loss decreased (0.750859 --> 0.729692). Saving model ...
39Epoch: 20 Training Loss: 0.588593 Validation Loss: 0.729085
40Validation loss decreased (0.729692 --> 0.729085). Saving model ...
41Epoch: 21 Training Loss: 0.571516 Validation Loss: 0.734009
42Epoch: 22 Training Loss: 0.545541 Validation Loss: 0.721433
43Validation loss decreased (0.729085 --> 0.721433). Saving model ...
44Epoch: 23 Training Loss: 0.523696 Validation Loss: 0.720512
45Validation loss decreased (0.721433 --> 0.720512). Saving model ...
46Epoch: 24 Training Loss: 0.508577 Validation Loss: 0.728457
47Epoch: 25 Training Loss: 0.483033 Validation Loss: 0.722556
48Epoch: 26 Training Loss: 0.469563 Validation Loss: 0.742352
49Epoch: 27 Training Loss: 0.449316 Validation Loss: 0.726019
50Epoch: 28 Training Loss: 0.442354 Validation Loss: 0.713364
51Validation loss decreased (0.720512 --> 0.713364). Saving model ...
52Epoch: 29 Training Loss: 0.421807 Validation Loss: 0.718615
53Epoch: 30 Training Loss: 0.404595 Validation Loss: 0.729914
加载模型
1model.load_state_dict(torch.load('model_cifar.pt'))
结果:
1
测试训练好的网络
在测试数据上测试你的训练模型!一个“好”的结果将是CNN得到大约70%,这些测试图像的准确性。
1# track test loss
2test_loss = 0.0
3class_correct = list(0. for i in range(10))
4class_total = list(0. for i in range(10))
5
6model.eval()
7# iterate over test data
8for data, target in test_loader:
9 # move tensors to GPU if CUDA is available
10 if train_on_gpu:
11 data, target = data.cuda(), target.cuda()
12 # forward pass: compute predicted outputs by passing inputs to the model
13 output = model(data)
14 # calculate the batch loss
15 loss = criterion(output, target)
16 # update test loss
17 test_loss += loss.item()*data.size(0)
18 # convert output probabilities to predicted class
19 _, pred = torch.max(output, 1)
20 # compare predictions to true label
21 correct_tensor = pred.eq(target.data.view_as(pred))
22 correct = np.squeeze(correct_tensor.numpy()) if not train_on_gpu else np.squeeze(correct_tensor.cpu().numpy())
23 # calculate test accuracy for each object class
24 for i in range(batch_size):
25 label = target.data[i]
26 class_correct[label] += correct[i].item()
27 class_total[label] += 1
28
29# average test loss
30test_loss = test_loss/len(test_loader.dataset)
31print('Test Loss: {:.6f}\n'.format(test_loss))
32
33for i in range(10):
34 if class_total[i] > 0:
35 print('Test Accuracy of %5s: %2d%% (%2d/%2d)' % (
36 classes[i], 100 * class_correct[i] / class_total[i],
37 np.sum(class_correct[i]), np.sum(class_total[i])))
38 else:
39 print('Test Accuracy of %5s: N/A (no training examples)' % (classes[i]))
40
41print('\nTest Accuracy (Overall): %2d%% (%2d/%2d)' % (
42 100. * np.sum(class_correct) / np.sum(class_total),
43 np.sum(class_correct), np.sum(class_total)))
结果:
1Test Loss: 0.708721
2
3Test Accuracy of airplane: 82% (826/1000)
4Test Accuracy of automobile: 81% (818/1000)
5Test Accuracy of bird: 65% (659/1000)
6Test Accuracy of cat: 59% (590/1000)
7Test Accuracy of deer: 75% (757/1000)
8Test Accuracy of dog: 56% (565/1000)
9Test Accuracy of frog: 81% (812/1000)
10Test Accuracy of horse: 82% (823/1000)
11Test Accuracy of ship: 86% (866/1000)
12Test Accuracy of truck: 84% (848/1000)
13
14Test Accuracy (Overall): 75% (7564/10000)
显示测试样本的结果
1# obtain one batch of test images
2dataiter = iter(test_loader)
3images, labels = dataiter.next()
4images.numpy()
5
6# move model inputs to cuda, if GPU available
7if train_on_gpu:
8 images = images.cuda()
9
10# get sample outputs
11output = model(images)
12# convert output probabilities to predicted class
13_, preds_tensor = torch.max(output, 1)
14preds = np.squeeze(preds_tensor.numpy()) if not train_on_gpu else np.squeeze(preds_tensor.cpu().numpy())
15
16# plot the images in the batch, along with predicted and true labels
17fig = plt.figure(figsize=(25, 4))
18for idx in np.arange(16):
19 ax = fig.add_subplot(2, 16/2, idx+1, xticks=[], yticks=[])
20 imshow(images.cpu()[idx])
21 ax.set_title("{} ({})".format(classes[preds[idx]], classes[labels[idx]]),
22 color=("green" if preds[idx]==labels[idx].item() else "red"))
结果:
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