news 2026/7/7 20:29:12

DAY36 复习日

作者头像

张小明

前端开发工程师

1.2k 24
文章封面图
DAY36 复习日

我们使用了神经网络的方式,用了pytorch重新对信贷数据集进行处理。

import pandas as pd import numpy as np import torch import torch.nn as nn import torch.optim as optim from torch.utils.data import Dataset, DataLoader from sklearn.model_selection import train_test_split from sklearn.preprocessing import StandardScaler, LabelEncoder from sklearn.metrics import accuracy_score, precision_score, recall_score, roc_auc_score, confusion_matrix import matplotlib.pyplot as plt import seaborn as sns import os # 设置随机种子以保证结果可复现 torch.manual_seed(42) np.random.seed(42) # --- 1. 数据预处理 --- def load_and_preprocess_data(filepath): print("Loading data...") df = pd.read_csv(filepath) # 删除 Id 列 if 'Id' in df.columns: df = df.drop('Id', axis=1) print(f"Original shape: {df.shape}") # 处理 'Current Loan Amount' 异常值 (99999999.0 通常表示无限制或错误) # 替换为 NaN 然后进行插补,或者替换为最大有效值。 # 这里我们替换为 NaN 并使用中位数插补,如果数量太多也可以直接删除。 # 先检查一下数量。 outlier_mask = df['Current Loan Amount'] == 99999999.0 df.loc[outlier_mask, 'Current Loan Amount'] = np.nan # 解析 'Years in current job' # 映射关系: '< 1 year'->0, '1 year'->1, ..., '10+ years'->10 def parse_years(x): if pd.isna(x): return np.nan if '<' in x: return 0 if '+' in x: return 10 return int(x.split()[0]) df['Years in current job'] = df['Years in current job'].apply(parse_years) # 插补缺失值 # 数值列 num_cols = df.select_dtypes(include=[np.number]).columns for col in num_cols: if col != 'Credit Default': # 使用中位数以增强鲁棒性 median_val = df[col].median() df[col].fillna(median_val, inplace=True) # 类别列 cat_cols = df.select_dtypes(include=['object']).columns for col in cat_cols: mode_val = df[col].mode()[0] df[col].fillna(mode_val, inplace=True) # 编码类别变量 (One-Hot 编码) df = pd.get_dummies(df, columns=cat_cols, drop_first=True) print(f"Processed shape: {df.shape}") # 划分数据 X = df.drop('Credit Default', axis=1).values y = df['Credit Default'].values # 70% 训练集, 15% 验证集, 15% 测试集 # 第一次划分: 训练集 (70%) 和 临时集 (30%) X_train, X_temp, y_train, y_temp = train_test_split(X, y, test_size=0.3, random_state=42, stratify=y) # 第二次划分: 验证集 (总量的 15% -> 临时集的 50%) 和 测试集 (总量的 15% -> 临时集的 50%) X_val, X_test, y_val, y_test = train_test_split(X_temp, y_temp, test_size=0.5, random_state=42, stratify=y_temp) # 标准化 scaler = StandardScaler() X_train = scaler.fit_transform(X_train) X_val = scaler.transform(X_val) X_test = scaler.transform(X_test) return X_train, y_train, X_val, y_val, X_test, y_test, df.drop('Credit Default', axis=1).columns # --- 2. PyTorch 数据集 --- class CreditDataset(Dataset): def __init__(self, X, y): self.X = torch.FloatTensor(X) self.y = torch.FloatTensor(y).unsqueeze(1) # 二分类需要 (N, 1) 的形状 def __len__(self): return len(self.X) def __getitem__(self, idx): return self.X[idx], self.y[idx] # --- 3. 神经网络模型 --- class CreditNN(nn.Module): def __init__(self, input_dim): super(CreditNN, self).__init__() # 3 个隐藏层: 128 -> 64 -> 32 self.layer1 = nn.Linear(input_dim, 128) self.relu1 = nn.ReLU() self.dropout1 = nn.Dropout(0.3) self.layer2 = nn.Linear(128, 64) self.relu2 = nn.ReLU() self.dropout2 = nn.Dropout(0.3) self.layer3 = nn.Linear(64, 32) self.relu3 = nn.ReLU() self.output = nn.Linear(32, 1) self.sigmoid = nn.Sigmoid() def forward(self, x): x = self.dropout1(self.relu1(self.layer1(x))) x = self.dropout2(self.relu2(self.layer2(x))) x = self.relu3(self.layer3(x)) x = self.sigmoid(self.output(x)) return x # --- 4. 训练函数 --- def train_model(model, train_loader, val_loader, criterion, optimizer, num_epochs=100, patience=10): train_losses = [] val_losses = [] train_accs = [] val_accs = [] best_val_loss = float('inf') epochs_no_improve = 0 device = torch.device("cuda" if torch.cuda.is_available() else "cpu") model.to(device) print(f"Training on {device}") for epoch in range(num_epochs): model.train() running_loss = 0.0 correct_train = 0 total_train = 0 for X_batch, y_batch in train_loader: X_batch, y_batch = X_batch.to(device), y_batch.to(device) optimizer.zero_grad() outputs = model(X_batch) loss = criterion(outputs, y_batch) loss.backward() optimizer.step() running_loss += loss.item() predicted = (outputs > 0.5).float() total_train += y_batch.size(0) correct_train += (predicted == y_batch).sum().item() epoch_train_loss = running_loss / len(train_loader) epoch_train_acc = correct_train / total_train train_losses.append(epoch_train_loss) train_accs.append(epoch_train_acc) # 验证 model.eval() running_val_loss = 0.0 correct_val = 0 total_val = 0 with torch.no_grad(): for X_batch, y_batch in val_loader: X_batch, y_batch = X_batch.to(device), y_batch.to(device) outputs = model(X_batch) loss = criterion(outputs, y_batch) running_val_loss += loss.item() predicted = (outputs > 0.5).float() total_val += y_batch.size(0) correct_val += (predicted == y_batch).sum().item() epoch_val_loss = running_val_loss / len(val_loader) epoch_val_acc = correct_val / total_val val_losses.append(epoch_val_loss) val_accs.append(epoch_val_acc) print(f"Epoch [{epoch+1}/{num_epochs}] " f"Train Loss: {epoch_train_loss:.4f} Acc: {epoch_train_acc:.4f} | " f"Val Loss: {epoch_val_loss:.4f} Acc: {epoch_val_acc:.4f}") # 早停检查 if epoch_val_loss < best_val_loss: best_val_loss = epoch_val_loss epochs_no_improve = 0 # 保存最佳模型 torch.save(model.state_dict(), 'best_credit_model.pth') else: epochs_no_improve += 1 if epochs_no_improve >= patience: print("Early stopping triggered!") break return train_losses, val_losses, train_accs, val_accs # --- 5. 评估与可视化 --- def evaluate_model(model, test_loader, feature_names): device = torch.device("cuda" if torch.cuda.is_available() else "cpu") model.load_state_dict(torch.load('best_credit_model.pth')) model.to(device) model.eval() y_true = [] y_pred = [] y_scores = [] with torch.no_grad(): for X_batch, y_batch in test_loader: X_batch = X_batch.to(device) outputs = model(X_batch) y_scores.extend(outputs.cpu().numpy()) predicted = (outputs > 0.5).float() y_pred.extend(predicted.cpu().numpy()) y_true.extend(y_batch.numpy()) y_true = np.array(y_true) y_pred = np.array(y_pred) y_scores = np.array(y_scores) # 指标计算 acc = accuracy_score(y_true, y_pred) prec = precision_score(y_true, y_pred) rec = recall_score(y_true, y_pred) auc = roc_auc_score(y_true, y_scores) print("\n--- Test Set Evaluation ---") print(f"Accuracy: {acc:.4f}") print(f"Precision: {prec:.4f}") print(f"Recall: {rec:.4f}") print(f"AUC: {auc:.4f}") # 混淆矩阵 cm = confusion_matrix(y_true, y_pred) plt.figure(figsize=(6, 5)) sns.heatmap(cm, annot=True, fmt='d', cmap='Blues') plt.title('Confusion Matrix') plt.ylabel('True Label') plt.xlabel('Predicted Label') plt.savefig('confusion_matrix.png') print("Saved confusion_matrix.png") # 可视化第一层权重 (特征重要性近似) # 我们取每个输入特征的权重的绝对值均值来观察其贡献 weights = model.layer1.weight.data.cpu().numpy() feature_importance = np.mean(np.abs(weights), axis=0) # 特征排序 sorted_idx = np.argsort(feature_importance)[-10:] # 取前10个 plt.figure(figsize=(10, 6)) plt.barh(range(10), feature_importance[sorted_idx]) plt.yticks(range(10), feature_names[sorted_idx]) plt.xlabel('Mean Absolute Weight') plt.title('Top 10 Feature Importance (Layer 1 Weights)') plt.savefig('feature_importance.png') print("Saved feature_importance.png") # --- 主程序执行 --- if __name__ == "__main__": # 加载数据 data_path = 'e:\\桌面\\Python60DaysChallenge-main\\data.csv' X_train, y_train, X_val, y_val, X_test, y_test, feature_names = load_and_preprocess_data(data_path) # 创建 DataLoader batch_size = 64 train_dataset = CreditDataset(X_train, y_train) val_dataset = CreditDataset(X_val, y_val) test_dataset = CreditDataset(X_test, y_test) train_loader = DataLoader(train_dataset, batch_size=batch_size, shuffle=True) val_loader = DataLoader(val_dataset, batch_size=batch_size) test_loader = DataLoader(test_dataset, batch_size=batch_size) # 初始化模型 input_dim = X_train.shape[1] model = CreditNN(input_dim) print(model) # 损失函数和优化器 criterion = nn.BCELoss() optimizer = optim.Adam(model.parameters(), lr=0.001) # 训练 train_losses, val_losses, train_accs, val_accs = train_model( model, train_loader, val_loader, criterion, optimizer, num_epochs=100, patience=10 ) # 绘制训练历史 plt.figure(figsize=(12, 5)) plt.subplot(1, 2, 1) plt.plot(train_losses, label='Train Loss') plt.plot(val_losses, label='Val Loss') plt.title('Loss Curve') plt.legend() plt.subplot(1, 2, 2) plt.plot(train_accs, label='Train Acc') plt.plot(val_accs, label='Val Acc') plt.title('Accuracy Curve') plt.legend() plt.savefig('training_history.png') print("Saved training_history.png") # 评估 evaluate_model(model, test_loader, feature_names)

结果如下:

版权声明: 本文来自互联网用户投稿,该文观点仅代表作者本人,不代表本站立场。本站仅提供信息存储空间服务,不拥有所有权,不承担相关法律责任。如若内容造成侵权/违法违规/事实不符,请联系邮箱:809451989@qq.com进行投诉反馈,一经查实,立即删除!
网站建设 2026/7/7 10:47:34

中国台湾阳明交大团队让AI帮你实现真正的冻结时光

这项由台湾阳明交大的程浩任、黄奕川、吴重豪&#xff0c;以及美国俄亥俄州立大学魏伦超、台湾阳明交大刘育纶共同完成的研究&#xff0c;发表于2025年12月4日的计算机视觉顶会。有兴趣深入了解的读者可以通过论文编号arXiv:2512.05113查询完整论文。还记得几年前风靡全网的曼尼…

作者头像 李华
网站建设 2026/7/7 16:01:02

DefaultCPUAllocator: can‘t allocate memory

深度学习训练过程出现如下错误&#xff1a; RuntimeError: [enforce fail at CPUAllocator.cpp:68] . DefaultCPUAllocator: can’t allocate memory: you tried to allocate 10526388877312 bytes. Error code 12 (Cannot allocate memory) 常见原因及解决方案&#xff1a; 张…

作者头像 李华
网站建设 2026/7/7 8:54:35

错过再等一年!Dify最新支持的10种闭源模型适配清单泄露

第一章&#xff1a;Dify私有化部署的模型适配概述 在企业级AI应用中&#xff0c;Dify的私有化部署支持将大语言模型&#xff08;LLM&#xff09;深度集成至内部系统&#xff0c;实现数据安全与业务闭环。模型适配是私有化部署的核心环节&#xff0c;涉及模型格式兼容、接口协议…

作者头像 李华
网站建设 2026/7/7 16:19:01

Java 字节码工具 ASM,实现类的动态增强

一、什么是 ASM&#xff1f; ASM 是一个轻量级、高性能的 Java 字节码操控框架&#xff0c;它基于字节码指令集操作&#xff0c;能够直接读取、修改和生成 Java 字节码文件&#xff08;.class文件&#xff09;&#xff0c;是 Java 字节码操作领域的核心工具之一。常见的开源框架…

作者头像 李华
网站建设 2026/7/7 16:02:04

HCNP学习第五天打卡

RIP定义&#xff1a;最经典的距离矢量路由协议。面向对象&#xff1a;IPV4------RIPV1&RIPV2IPV6------RIPV2更新与接受&#xff1a;周期性发送本地设备路由表&#xff0c;其他设备进行接受对比后&#xff0c;实现实时适配网络中的拓扑更新。路由更新步骤&#xff1a;路由器…

作者头像 李华