用pytorch1.0搭建简单的神经网络:进行多分类分析
import torch
import torch.nn.functional as F # 包含激励函数
import matplotlib.pyplot as plt # 假数据
# make fake data
n_data = torch.ones(100, 2)
x0 = torch.normal(2*n_data, 1) # class0 x data (tensor), shape=(100, 2)
y0 = torch.zeros(100) # class0 y data (tensor), shape=(100, 1)
x1 = torch.normal(-2*n_data, 1) # class1 x data (tensor), shape=(100, 2)
y1 = torch.ones(100) # class1 y data (tensor), shape=(100, 1)
# 注意 x, y 数据的数据形式是一定要像下面一样 (torch.cat 是合并数据)
x = torch.cat((x0, x1), 0).type(torch.FloatTensor) # shape (200, 2) FloatTensor = 32-bit floating
y = torch.cat((y0, y1), ).type(torch.LongTensor) # shape (200,) LongTensor = 64-bit integer # The code below is deprecated in Pytorch 0.4. Now, autograd directly supports tensors
# x, y = Variable(x), Variable(y)
# 画散点图
plt.scatter(x.data.numpy()[:, 0], x.data.numpy()[:, 1], c=y.data.numpy(), s=100, lw=0, cmap='RdYlGn')
plt.show() # 建立神经网络
# 先定义所有的层属性(__init__()), 然后再一层层搭建(forward(x))层于层的关系链接
class Net(torch.nn.Module):
def __init__(self, n_feature, n_hidden, n_output):
super(Net, self).__init__() # 继承 __init__ 功能
# 定义每层用什么样的形式
self.hidden = torch.nn.Linear(n_feature, n_hidden) # hidden layer
self.out = torch.nn.Linear(n_hidden, n_output) # output layer def forward(self, x): # 这同时也是 Module 中的 forward 功能
# 正向传播输入值, 神经网络分析出输出值
x = F.relu(self.hidden(x)) # activation function for hidden layer
x = self.out(x)
return x net = Net(n_feature=2, n_hidden=10, n_output=2) # define the network
print(net) # net architecture == 显示神经网络结构
# Net(
# (hidden): Linear(in_features=2, out_features=10, bias=True)
# (out): Linear(in_features=10, out_features=2, bias=True)
# )
# 搭建完神经网络后,对 神经网路参数(net.parameters()) 进行优化
# (1.选择优化器 optimizer 是训练的工具
optimizer = torch.optim.SGD(net.parameters(), lr=0.02) # 传入 net 的所有参数, 学习率
# (2.选择优化的目标函数
loss_func = torch.nn.CrossEntropyLoss() # the target label is NOT an one-hotted plt.ion() # something about plotting
# (3.开始训练网络
for t in range(100):
out = net(x) # input x and predict based on x # 喂给 net 训练数据 x, 输出预测值
loss = loss_func(out, y) # must be (1. nn output, 2. target), the target label is NOT one-hotted # 计算两者的误差 optimizer.zero_grad() # clear gradients for next train # 清空上一步的残余更新参数值
loss.backward() # backpropagation, compute gradients # 误差反向传播, 计算参数更新值
optimizer.step() # apply gradients # 将参数更新值施加到 net 的 parameters 上 if t % 2 == 0:
# plot and show learning process
plt.cla()
# 过了一道 softmax 的激励函数后的最大概率才是预测值
prediction = torch.max(out, 1)[1]
pred_y = prediction.data.numpy()
target_y = y.data.numpy()
plt.scatter(x.data.numpy()[:, 0], x.data.numpy()[:, 1], c=pred_y, s=100, lw=0, cmap='RdYlGn')
accuracy = float((pred_y == target_y).astype(int).sum()) / float(target_y.size) # 预测中有多少和真实值一样
plt.text(1.5, -4, 'Accuracy=%.2f' % accuracy, fontdict={'size': 20, 'color': 'red'})
plt.pause(0.1) plt.ioff()
plt.show()