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machinelearning_notebook/6_pytorch/fig-res-8.4.py

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  1. import torch

  2. import numpy as np

  3. from torch import nn

  4. from torch.autograd import Variable

  5. import torch.nn.functional as F

  6. import matplotlib.pyplot as plt

  7. 

  8. plt.rcParams['font.sans-serif']=['SimHei']

  9. plt.rcParams['axes.unicode_minus'] = False

  10. #%matplotlib inline

  11. np.random.seed(1)

  12. m = 400 # 样本数量

  13. N = int(m/2) # 每一类的点的个数

  14. D = 2 # 维度

  15. x = np.zeros((m, D))

  16. y = np.zeros((m, 1), dtype='uint8') # label 向量, 0 表示红色, 1 表示蓝色

  17. a = 4

  18. 

  19. # 生成两类数据

  20. for j in range(2):

  21.     ix = range(N*j,N*(j+1))

  22.     t = np.linspace(j*3.12,(j+1)*3.12,N) + np.random.randn(N)*0.2 # theta

  23.     r = a*np.sin(4*t) + np.random.randn(N)*0.2 # radius

  24.     x[ix] = np.c_[r*np.sin(t), r*np.cos(t)]

  25.     y[ix] = j

  26. 

  27. x = torch.from_numpy(x).float()

  28. y = torch.from_numpy(y).float()

  29. 

  30. # 定义两层神经网络的参数

  31. w1 = nn.Parameter(torch.randn(2, 4) * 0.01) # 输入维度为2, 隐藏层神经元个数4

  32. b1 = nn.Parameter(torch.zeros(4))

  33. w2 = nn.Parameter(torch.randn(4, 1) * 0.01) # 隐层神经元为4, 输出单元为1

  34. b2 = nn.Parameter(torch.zeros(1))

  35. 

  36. def mlp_network(x):

  37.     x1 = torch.mm(x, w1) + b1

  38.     x1 = F.tanh(x1) # 使用 PyTorch 自带的 tanh 激活函数

  39.     x2 = torch.mm(x1, w2) + b2

  40.     return x2

  41. 

  42. # 定义优化器和损失函数

  43. optimizer = torch.optim.SGD([w1, w2, b1, b2], 1.)

  44. criterion = nn.BCEWithLogitsLoss()

  45. 

  46. for e in range(10000):

  47.     # 正向计算

  48.     out = mlp_network(Variable(x))

  49.     # 计算误差

  50.     loss = criterion(out, Variable(y))

  51.     # 计算梯度并更新权重

  52.     optimizer.zero_grad()

  53.     loss.backward()

  54.     optimizer.step()

  55.     if (e + 1) % 1000 == 0:

  56.         print('epoch: {}, loss: {}'.format(e+1, loss.item()))

  57. 

  58. def plot_decision_boundary(model, x, y):

  59.     # Set min and max values and give it some padding

  60.     x_min, x_max = x[:, 0].min() - 1, x[:, 0].max() + 1

  61.     y_min, y_max = x[:, 1].min() - 1, x[:, 1].max() + 1 

  62.     h = 0.01

  63.     # Generate a grid of points with distance h between them

  64.     xx, yy = np.meshgrid(np.arange(x_min, x_max, h), np.arange(y_min,y_max, h))    

  65. 

  66.     # Predict the function value for the whole grid .c_ 按行连接两个矩阵,左右相加。

  67.     Z = model(np.c_[xx.ravel(), yy.ravel()])

  68.     Z = Z.reshape(xx.shape)

  69.     # Plot the contour and training examples

  70.     plt.contourf(xx, yy, Z, cmap=plt.cm.Spectral)

  71.     plt.ylabel("x2")

  72.     plt.xlabel("x1")

  73.     for i in range(m):

  74.         if y[i] == 0:

  75.             plt.scatter(x[i, 0], x[i, 1], marker='8',c=0, s=40, cmap=plt.cm.Spectral)

  76.         else:

  77.             plt.scatter(x[i, 0], x[i, 1], marker='^',c=1, s=40)

  78. 

  79. def plot_network(x):

  80.     x = Variable(torch.from_numpy(x).float())

  81.     x1 = torch.mm(x, w1) + b1

  82.     x1 = F.tanh(x1)

  83.     x2 = torch.mm(x1, w2) + b2

  84.     out = F.sigmoid(x2)

  85.     out = (out > 0.5) * 1

  86.     return out.data.numpy()

  87. 

  88. plot_decision_boundary(lambda x: plot_network(x), x.numpy(), y.numpy())

  89. plt.title('2层神经网络')

  90. plt.savefig('fig-res-8.4.pdf')    

  91. plt.show()