添加td3模型作为基线模型

pyproject.toml

@@ -1,3 +1,6 @@
+[[tool.uv.index]]
+url = "https://pypi.tuna.tsinghua.edu.cn/simple"
+default = true
 [project]
 name = "ctm"
 version = "0.1.0"
@@ -5,15 +8,24 @@ description = "DQN-based Dynamic Speed Limit Control with Cell Transmission Mode
 readme = "README.md"
 requires-python = ">=3.12"
 dependencies = [
-    "torch>=2.0.0",
-    "numpy>=1.24.0",
-    "matplotlib>=3.7.0",
     "pyyaml>=6.0",
     "tqdm>=4.65.0",
-    "pandas>=2.3.3",
     "eclipse-sumo>=1.20.0",
+    "torch==2.4.1+cu124",
+    "numpy>=2.4.3",
+    "matplotlib>=3.10.8",
+    "stable-baselines3>=2.7.1",
 ]
 
 [[tool.uv.index]]
-url = "https://pypi.org/simple"
+name = "tuna"
+url = "https://pypi.mirrors.ustc.edu.cn/simple/"
 default = true
+
+[[tool.uv.index]]
+name = "pytorch-cu124"
+url = "https://mirrors.nju.edu.cn/pytorch/whl/cu124"
+explicit = true
+
+[tool.uv.sources]
+torch = { index = "pytorch-cu124" }

td3_agent.py

@@ -0,0 +1,120 @@
+"""
+TD3 Agent using Stable-Baselines3
+适配 MultiDiscrete 动作空间的 VSL 控制
+"""
+import numpy as np
+from stable_baselines3 import TD3
+from stable_baselines3.common.noise import NormalActionNoise
+import gymnasium as gym
+from gymnasium import spaces
+
+
+class MultiDiscreteWrapper(gym.Env):
+    """将MultiDiscrete动作空间包装为连续空间供TD3使用"""
+
+    def __init__(self, state_dim, action_dims):
+        super().__init__()
+        self.state_dim = state_dim
+        self.action_dims = action_dims
+        self.num_zones = len(action_dims)
+
+        self.observation_space = spaces.Box(
+            low=-np.inf, high=np.inf, shape=(state_dim,), dtype=np.float32
+        )
+        self.action_space = spaces.Box(
+            low=0.0, high=1.0, shape=(self.num_zones,), dtype=np.float32
+        )
+
+    def reset(self, seed=None, options=None):
+        return np.zeros(self.state_dim, dtype=np.float32), {}
+
+    def step(self, action):
+        return np.zeros(self.state_dim, dtype=np.float32), 0.0, False, False, {}
+
+
+class TD3Agent:
+    """TD3智能体包装器"""
+
+    def __init__(
+        self,
+        state_dim: int,
+        action_dims: list,
+        learning_rate: float = 3e-4,
+        buffer_size: int = 100000,
+        learning_starts: int = 1000,
+        batch_size: int = 256,
+        tau: float = 0.005,
+        gamma: float = 0.99,
+        policy_delay: int = 2,
+        device: str = "cuda",
+    ):
+        self.state_dim = state_dim
+        self.action_dims = action_dims
+        self.num_zones = len(action_dims)
+        self.device = device
+        self.learning_starts = learning_starts
+
+        # 创建虚拟环境
+        dummy_env = MultiDiscreteWrapper(state_dim, action_dims)
+
+        # 动作噪声
+        action_noise = NormalActionNoise(
+            mean=np.zeros(self.num_zones),
+            sigma=0.1 * np.ones(self.num_zones)
+        )
+
+        # 创建TD3模型
+        self.model = TD3(
+            "MlpPolicy",
+            env=dummy_env,
+            learning_rate=learning_rate,
+            buffer_size=buffer_size,
+            learning_starts=learning_starts,
+            batch_size=batch_size,
+            tau=tau,
+            gamma=gamma,
+            policy_delay=policy_delay,
+            action_noise=action_noise,
+            device=device,
+            verbose=0,
+        )
+
+    def select_action(self, state: np.ndarray, deterministic: bool = False):
+        """选择动作并转换为离散动作"""
+        continuous_action, _ = self.model.predict(state, deterministic=deterministic)
+
+        # 映射到离散动作
+        discrete_action = np.array([
+            int(cont * (self.action_dims[i] - 1) + 0.5)
+            for i, cont in enumerate(continuous_action)
+        ])
+        discrete_action = np.clip(discrete_action, 0, [d-1 for d in self.action_dims])
+
+        return discrete_action, 0.0, 0.0
+
+    def store_transition(self, state, action, reward, next_state, done):
+        """存储经验到replay buffer"""
+        continuous_action = np.array([
+            action[i] / (self.action_dims[i] - 1)
+            for i in range(self.num_zones)
+        ], dtype=np.float32)
+
+        self.model.replay_buffer.add(
+            state, next_state, continuous_action, reward, done, [{}]
+        )
+
+    def update(self):
+        """更新策略"""
+        if self.model.replay_buffer.size() < self.learning_starts:
+            return {}
+
+        self.model.train(gradient_steps=1)
+        return {"actor_loss": 0.0, "critic_loss": 0.0}
+
+    def save(self, path: str):
+        """保存模型"""
+        self.model.save(path)
+
+    def load(self, path: str):
+        """加载模型"""
+        self.model = TD3.load(path, device=self.device)

train_sumo_td3.py

@@ -0,0 +1,209 @@
+"""
+基于 SUMO+TraCI 的 TD3 训练脚本
+使用 Stable-Baselines3 的 TD3 算法
+"""
+import os
+import yaml
+import numpy as np
+import matplotlib
+matplotlib.use("Agg")
+import matplotlib.pyplot as plt
+from datetime import datetime
+from tqdm import tqdm
+
+from sumo_edge_vsl_environment import SUMOEdgeVSLEnvironment
+from td3_agent import TD3Agent
+from training_logger import TrainingLogger
+
+
+def train_sumo_td3():
+    """SUMO 环境下的 TD3 训练主函数"""
+    with open("config_sumo_vsl.yaml", "r", encoding="utf-8") as f:
+        config = yaml.safe_load(f)
+
+    agent_config = config.get("agent", {})
+    train_config = config["training"]
+
+    timestamp = datetime.now().strftime("%Y%m%d_%H%M%S")
+    checkpoint_dir = os.path.join("checkpoints_sumo_td3", timestamp)
+    log_dir = os.path.join("logs_sumo_td3", timestamp)
+    os.makedirs(checkpoint_dir, exist_ok=True)
+    os.makedirs(log_dir, exist_ok=True)
+    with open(os.path.join(checkpoint_dir, "config.yaml"), "w", encoding="utf-8") as f:
+        yaml.dump(config, f)
+
+    logger = TrainingLogger(log_dir, "td3")
+    env = SUMOEdgeVSLEnvironment(config)
+
+    state_dim = env.state_dim
+    action_dims = [env.action_dim] * env.num_edges
+
+    print("=" * 70)
+    print("TD3训练 - SUMO+TraCI VSL 环境")
+    print("=" * 70)
+    print(f"  状态维度: {state_dim}")
+    print(f"  动作空间: {action_dims}")
+    print(f"  Episode 步数: {env.episode_length}")
+    print(f"  控制间隔: {env.control_interval}s")
+    print(f"  学习率: {agent_config.get('learning_rate', 3e-4)}")
+    print(f"  设备: {agent_config.get('device', 'cuda')}")
+    print()
+
+    agent = TD3Agent(
+        state_dim=state_dim,
+        action_dims=action_dims,
+        learning_rate=agent_config.get("learning_rate", 3e-4),
+        buffer_size=agent_config.get("buffer_size", 100000),
+        learning_starts=agent_config.get("learning_starts", 1000),
+        batch_size=agent_config.get("batch_size", 256),
+        tau=agent_config.get("tau", 0.005),
+        gamma=agent_config.get("gamma", 0.99),
+        policy_delay=agent_config.get("policy_delay", 2),
+        device=agent_config.get("device", "cuda"),
+    )
+
+    num_episodes = train_config["num_episodes"]
+    save_freq = train_config.get("save_freq", 50)
+    log_freq = train_config.get("log_freq", 10)
+    base_seed = train_config.get("random_seed", 42)
+
+    episode_rewards = []
+    episode_throughputs = []
+    episode_mean_speeds = []
+    episode_hard_brakes = []
+    best_reward = -float("inf")
+
+    print("开始训练...\n")
+
+    try:
+        for episode in range(1, num_episodes + 1):
+            seed = base_seed + episode
+            state = env.reset(seed=seed)
+            episode_reward = 0
+            episode_throughput = 0
+            episode_speed = 0
+            episode_brakes = 0
+            done = False
+            step = 0
+
+            pbar = tqdm(
+                total=env.episode_length,
+                desc=f"Ep {episode}/{num_episodes}",
+                leave=False,
+            )
+
+            while not done:
+                action, _, _ = agent.select_action(state, deterministic=False)
+                next_state, reward, done, info = env.step(action)
+
+                agent.store_transition(state, action, reward, next_state, done)
+                agent.update()
+
+                episode_reward += reward
+                episode_throughput += info["throughput"]
+                episode_speed += info["mean_speed_kmh"]
+                episode_brakes += info["num_hard_brakes"]
+                state = next_state
+                step += 1
+
+                pbar.set_postfix(
+                    r=f"{episode_reward:.1f}",
+                    tp=f"{info['throughput']:.0f}",
+                    v=f"{info['mean_speed_kmh']:.1f}",
+                )
+                pbar.update(1)
+
+            pbar.close()
+
+            avg_tp = episode_throughput / max(step, 1)
+            avg_speed = episode_speed / max(step, 1)
+            episode_rewards.append(episode_reward)
+            episode_throughputs.append(avg_tp)
+            episode_mean_speeds.append(avg_speed)
+            episode_hard_brakes.append(episode_brakes)
+
+            logger.log(episode, episode_reward, avg_tp, avg_speed, episode_brakes)
+
+            if episode_reward > best_reward:
+                best_reward = episode_reward
+                agent.save(os.path.join(checkpoint_dir, "model_best"))
+
+            if episode % log_freq == 0:
+                recent_rewards = episode_rewards[-log_freq:]
+                print(f"\nEpisode {episode}/{num_episodes}")
+                print(f"  Reward: {episode_reward:.2f} (Avg: {np.mean(recent_rewards):.2f})")
+                print(f"  Throughput: {avg_tp:.1f} veh/h")
+                print(f"  Mean Speed: {avg_speed:.1f} km/h")
+
+            if episode % save_freq == 0:
+                agent.save(os.path.join(checkpoint_dir, f"model_ep{episode}"))
+
+    except KeyboardInterrupt:
+        print("\n训练被中断，保存当前模型...")
+        agent.save(os.path.join(checkpoint_dir, "model_interrupted"))
+    finally:
+        env.close()
+
+    agent.save(os.path.join(checkpoint_dir, f"model_ep{num_episodes}"))
+
+    _plot_training_curves(
+        episode_rewards, episode_throughputs, episode_mean_speeds, episode_hard_brakes,
+        save_path=os.path.join(log_dir, "training_curves.png"),
+    )
+
+    print("=" * 70)
+    print("训练完成！")
+    print(f"  最佳奖励: {best_reward:.2f}")
+    print(f"  模型目录: {checkpoint_dir}")
+    print(f"  日志目录: {log_dir}")
+    print("=" * 70)
+
+
+def _plot_training_curves(rewards, throughputs, mean_speeds, hard_brakes, save_path: str):
+    """绘制训练曲线"""
+    fig, axes = plt.subplots(2, 2, figsize=(15, 10))
+    window = 20
+
+    axes[0, 0].plot(rewards, alpha=0.4, color="blue")
+    if len(rewards) > window:
+        ma = np.convolve(rewards, np.ones(window) / window, mode="valid")
+        axes[0, 0].plot(range(window - 1, len(rewards)), ma, "r-", linewidth=2)
+    axes[0, 0].set_xlabel("Episode")
+    axes[0, 0].set_ylabel("Total Reward")
+    axes[0, 0].set_title("Episode Reward")
+    axes[0, 0].grid(True, alpha=0.3)
+
+    axes[0, 1].plot(throughputs, alpha=0.4, color="green")
+    if len(throughputs) > window:
+        ma = np.convolve(throughputs, np.ones(window) / window, mode="valid")
+        axes[0, 1].plot(range(window - 1, len(throughputs)), ma, "r-", linewidth=2)
+    axes[0, 1].set_xlabel("Episode")
+    axes[0, 1].set_ylabel("Avg Throughput (veh/h)")
+    axes[0, 1].set_title("Throughput")
+    axes[0, 1].grid(True, alpha=0.3)
+
+    axes[1, 0].plot(mean_speeds, alpha=0.4, color="orange")
+    if len(mean_speeds) > window:
+        ma = np.convolve(mean_speeds, np.ones(window) / window, mode="valid")
+        axes[1, 0].plot(range(window - 1, len(mean_speeds)), ma, "r-", linewidth=2)
+    axes[1, 0].set_xlabel("Episode")
+    axes[1, 0].set_ylabel("Mean Speed (km/h)")
+    axes[1, 0].set_title("Mean Speed")
+    axes[1, 0].grid(True, alpha=0.3)
+
+    axes[1, 1].plot(hard_brakes, alpha=0.4, color="red")
+    if len(hard_brakes) > window:
+        ma = np.convolve(hard_brakes, np.ones(window) / window, mode="valid")
+        axes[1, 1].plot(range(window - 1, len(hard_brakes)), ma, "r-", linewidth=2)
+    axes[1, 1].set_xlabel("Episode")
+    axes[1, 1].set_ylabel("Hard Brakes Count")
+    axes[1, 1].set_title("Hard Brakes")
+    axes[1, 1].grid(True, alpha=0.3)
+
+    plt.tight_layout()
+    plt.savefig(save_path, dpi=150, bbox_inches="tight")
+    print(f"训练曲线已保存: {save_path}")
+
+
+if __name__ == "__main__":
+    train_sumo_td3()