Pytorch写数字识别LeNet模型

Bonnie ·
更新时间:2024-11-13
· 1857 次阅读

目录

LeNet网络

训练结果

泛化能力测试

LeNet网络

LeNet网络过卷积层时候保持分辨率不变,过池化层时候分辨率变小。实现如下

from PIL import Image import cv2 import matplotlib.pyplot as plt import torchvision from torchvision import transforms import torch from torch.utils.data import DataLoader import torch.nn as nn import numpy as np import tqdm as tqdm class LeNet(nn.Module):     def __init__(self) -> None:         super().__init__()         self.sequential = 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*25,120),nn.Sigmoid(),                                         nn.Linear(120,84),nn.Sigmoid(),                                         nn.Linear(84,10))     def forward(self,x):         return self.sequential(x) class MLP(nn.Module):     def __init__(self) -> None:         super().__init__()         self.sequential = nn.Sequential(nn.Flatten(),                           nn.Linear(28*28,120),nn.Sigmoid(),                           nn.Linear(120,84),nn.Sigmoid(),                           nn.Linear(84,10))     def forward(self,x):         return self.sequential(x) epochs = 15 batch = 32 lr=0.9 loss = nn.CrossEntropyLoss() model = LeNet() optimizer = torch.optim.SGD(model.parameters(),lr) device = torch.device('cuda') root = r"./" trans_compose  = transforms.Compose([transforms.ToTensor(),                     ]) train_data = torchvision.datasets.MNIST(root,train=True,transform=trans_compose,download=True) test_data = torchvision.datasets.MNIST(root,train=False,transform=trans_compose,download=True) train_loader = DataLoader(train_data,batch_size=batch,shuffle=True) test_loader = DataLoader(test_data,batch_size=batch,shuffle=False) model.to(device) loss.to(device) # model.apply(init_weights) for epoch in range(epochs):   train_loss = 0   test_loss = 0   correct_train = 0   correct_test = 0   for index,(x,y) in enumerate(train_loader):     x = x.to(device)     y = y.to(device)     predict = model(x)     L = loss(predict,y)     optimizer.zero_grad()     L.backward()     optimizer.step()     train_loss = train_loss + L     correct_train += (predict.argmax(dim=1)==y).sum()   acc_train = correct_train/(batch*len(train_loader))   with torch.no_grad():     for index,(x,y) in enumerate(test_loader):       [x,y] = [x.to(device),y.to(device)]       predict = model(x)       L1 = loss(predict,y)       test_loss = test_loss + L1       correct_test += (predict.argmax(dim=1)==y).sum()     acc_test = correct_test/(batch*len(test_loader))   print(f'epoch:{epoch},train_loss:{train_loss/batch},test_loss:{test_loss/batch},acc_train:{acc_train},acc_test:{acc_test}') 训练结果

epoch:12,train_loss:2.235553741455078,test_loss:0.3947642743587494,acc_train:0.9879833459854126,acc_test:0.9851238131523132
epoch:13,train_loss:2.028963804244995,test_loss:0.3220392167568207,acc_train:0.9891499876976013,acc_test:0.9875199794769287
epoch:14,train_loss:1.8020273447036743,test_loss:0.34837451577186584,acc_train:0.9901833534240723,acc_test:0.98702073097229

泛化能力测试

找了一张图片,将其分割成只含一个数字的图片进行测试

images_np = cv2.imread("/content/R-C.png",cv2.IMREAD_GRAYSCALE) h,w = images_np.shape images_np = np.array(255*torch.ones(h,w))-images_np#图片反色 images = Image.fromarray(images_np) plt.figure(1) plt.imshow(images) test_images = [] for i in range(10):   for j in range(16):     test_images.append(images_np[h//10*i:h//10+h//10*i,w//16*j:w//16*j+w//16]) sample = test_images[77] sample_tensor = torch.tensor(sample).unsqueeze(0).unsqueeze(0).type(torch.FloatTensor).to(device) sample_tensor = torch.nn.functional.interpolate(sample_tensor,(28,28)) predict = model(sample_tensor) output = predict.argmax() print(output) plt.figure(2) plt.imshow(np.array(sample_tensor.squeeze().to('cpu')))

此时预测结果为4,预测正确。从这段代码中可以看到有一个反色的步骤,若不反色,结果会受到影响,如下图所示,预测为0,错误。
模型用于输入的图片是单通道的黑白图片,这里由于可视化出现了黄色,但实际上是黑白色,反色操作说明了数据的预处理十分的重要,很多数据如果是不清理过是无法直接用于推理的。

将所有用来泛化性测试的图片进行准确率测试:

correct = 0 i = 0 cnt = 1 for sample in test_images:   sample_tensor = torch.tensor(sample).unsqueeze(0).unsqueeze(0).type(torch.FloatTensor).to(device)   sample_tensor = torch.nn.functional.interpolate(sample_tensor,(28,28))   predict = model(sample_tensor)   output = predict.argmax()   if(output==i):     correct+=1   if(cnt%16==0):     i+=1   cnt+=1 acc_g = correct/len(test_images) print(f'acc_g:{acc_g}')

如果不反色,acc_g=0.15

acc_g:0.50625

到此这篇关于Pytorch写数字识别LeNet模型的文章就介绍到这了,更多相关Pytorch写数字识别LeNet模型内容请搜索软件开发网以前的文章或继续浏览下面的相关文章希望大家以后多多支持软件开发网!



pytorch lenet

需要 登录 后方可回复, 如果你还没有账号请 注册新账号
相关文章