afem/asmr++_architecture.md

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# ASMR++ 网络架构与数据流 (默认配置)
> 基于 `configs/asmr_pp/asmr_default.yaml` — `value_function_aggr: spatial`, `projection_type: sum`
## 架构总览
```mermaid
flowchart TD
subgraph ENV["♻️ 环境: MeshRefinement"]
A1["FEMProblemCircularQueue<br/>随机采样 PDE 问题"]
A2["生成初始粗网格<br/>(meshpy, 2D 三角剖分)"]
A3["FEM 求解器<br/>计算 PDE 解和逐单元误差"]
A4["构建观测图<br/>(节点=单元, 边=邻接关系)"]
A1 --> A2 --> A3 --> A4
end
subgraph GRAPH["📊 观测图 (torch_geometric Data)"]
B1["<b>节点特征 (x)</b><br/>━━━━━━━━━━━━━━━━<br/>solution_mean / solution_std<br/>volume / timestep<br/>element_penalty<br/>source_term (PDE 特征)<br/>共 ~10-15 维"]
B2["<b>边特征 (edge_attr)</b><br/>━━━━━━━━━━━━━━━━<br/>euclidean_distance<br/>共 1 维"]
B3["<b>边索引 (edge_index)</b><br/>━━━━━━━━━━━━━━━━<br/>双向邻接 + 自环"]
end
subgraph NORM["📏 观测归一化器"]
C1["node.x: running mean/std"]
C2["edge_attr: running mean/std"]
end
subgraph HMPN["🧠 HMPN 基础网络 (HomogeneousMessagePassingBase)"]
subgraph EMBED["输入嵌入"]
D1["节点嵌入: Linear(in→64)"]
D2["边嵌入: Linear(in→64)"]
end
subgraph STACK["消息传递堆栈 (num_steps=2, residual=inner, layernorm=inner)"]
subgraph STEP1["Step 1/2"]
E1["<b>边更新</b> HomogeneousEdgeModule<br/>concat[src(64), dst(64), edge(64)]<br/>→ LatentMLP(192→64, 2层, LeakyReLU)<br/>→ LayerNorm → +inner residual"]
E2["<b>节点更新</b> HomogeneousMessagePassingNodeModule<br/>scatter_mean(edge→dest) → concat[node(64), agg(64)]<br/>→ LatentMLP(128→64, 2层, LeakyReLU)<br/>→ LayerNorm → +inner residual"]
E1 --> E2
end
subgraph STEP2["Step 2/2"]
F1["边更新 (同上)"]
F2["节点更新 (同上)"]
F1 --> F2
end
STEP1 --> STEP2
end
D1 --> STEP1
D2 --> STEP1
STEP2 --> G["输出: 节点潜在特征 (num_nodes, 64)"]
end
subgraph HEADS["🎯 策略与价值头 (share_base=False, 各自独立 GNN)"]
subgraph ACTOR["Actor 头"]
H1["Policy MLP<br/>2层, Tanh<br/>64→64→64"]
H2["Linear(64→action_dim)"]
H3["log_std (可学习)"]
H4["DiagGaussian(μ, σ)<br/>每节点输出独立动作"]
H1 --> H2 --> H4
H3 --> H4
end
subgraph CRITIC["Critic 头 — 逐节点价值,不做 scatter 聚合"]
I1["Value MLP<br/>2层, Tanh<br/>64→64→1"]
I2["输出形状: (num_agents, 1)<br/>每个 agent 独立 V_i(s)<br/><b>value_function_aggr=spatial<br/>→ 不聚合,保持逐节点</b>"]
I1 --> I2
end
G --> H1
G --> I1
end
subgraph BUFFER["🗃️ MixedOnPolicyBuffer (global_weight=0.5)"]
J1["<b>局部 GAE (逐节点)</b><br/>δ_i = r_i + γ·Σ_j φ_ij·V_j(s') - V_i(s)<br/>projection_type='sum': Σ 通过 agent_mapping 反投影"]
J2["<b>全局 GAE (图级别)</b><br/>δ_global = r_global + γ·V_mean(s') - V_mean(s)"]
J3["<b>混合 Advantage</b><br/>A_i = (1-0.5)·A_i_local + 0.5·A_global"]
J1 --> J3
J2 --> J3
end
subgraph PPO["🔄 PPO 训练"]
K1["256 步 Rollout"]
K2["5 Epochs, batch_size=32"]
K3["policy_loss + 0.5·value_loss<br/>clip_range=0.2"]
K4["梯度裁剪 0.5, Adam lr=3e-4"]
K1 --> K2 --> K3 --> K4
end
ENV --> GRAPH --> NORM --> HMPN
HMPN --> HEADS
ACTOR -->|动作| ENV
CRITIC -->|"V_i(s) 逐节点"| BUFFER
ENV -->|"r_i, agent_mapping φ"| BUFFER
BUFFER --> PPO
PPO -->|更新参数| HMPN
PPO -->|更新参数| HEADS
```
## 核心纠正: projection_type 的真实作用
**之前的错误理解**:
- ~~Critic 输出 scatter_sum → 图级别价值~~ ❌
**正确理解**:
- `value_function_aggr: "spatial"` → Critic **不做任何聚合**,输出 `(num_agents, 1)` 逐节点价值 ✅
- `projection_type: "sum"` → 在 **Buffer** 中通过 `agent_mapping` 反投影下一步价值时使用 ✅
两个参数作用于完全不同的位置:
| 参数 | 作用位置 | 作用 |
|------|----------|------|
| `value_function_aggr: "spatial"` | `SwarmPPOActorCritic._get_values_and_distribution()` | 控制 Critic 输出是否聚合: `"spatial"` → 保持逐节点 |
| `projection_type: "sum"` | `SpatialOnPolicyBuffer._project_to_previous_step()` | 控制 agent_mapping 反投影方式: sum→子元素价值求和回父元素 |
## 详细数据流 (序列图)
```mermaid
sequenceDiagram
actor Trainer
participant Env as MeshRefinement
participant Norm as Normalizer
participant GNN as HMPN Base
participant Actor as Policy Head
participant Critic as Value Head
participant Buffer as MixedOnPolicyBuffer
Note over Trainer,Buffer: === Rollout (256 步) ===
Trainer->>Env: reset()
Env->>Env: 随机 Poisson PDE + 随机域 + GMM 负载
Env->>Env: 初始粗网格 → FEM 求解 → 构建观测图
loop 256 步
Env-->>Norm: 观测图 (原始 node.x, edge_attr)
Norm-->>GNN: 归一化后图
GNN->>GNN: Edge Dropout (0.1, 仅训练)
GNN->>GNN: 嵌入 → MP Step1 → MP Step2
GNN-->>Actor: node_features (num_nodes, 64)
GNN-->>Critic: node_features (num_nodes, 64)
Actor->>Actor: MLP → μ, σ → 采样动作
Critic->>Critic: MLP(64→1) → <b>V_i(s): (num_agents, 1) 逐节点</b>
Actor-->>Env: actions (num_agents, 1)
Env->>Env: 元素选择 → 网格细分
Env->>Env: FEM 求解 → 计算空间奖励 r_i
Env-->>Buffer: (obs, a, r_i, V_i, log_prob, agent_mapping φ)
end
Note over Buffer: === GAE 计算 (逐节点 + 混合奖励) ===
Buffer->>Buffer: <b>局部 δ_i(t) = r_i + γ·Σ_j φ_ij·V_j(t+1) - V_i(t)</b>
Buffer->>Buffer: projection_type='sum': Σ_j 通过 agent_mapping 反投影
Buffer->>Buffer: 局部 GAE → A_local_i (逐节点)
Buffer->>Buffer: 全局 GAE → A_global (图级, 用 mean(V_i) 算)
Buffer->>Buffer: <b>A_i = 0.5·A_local_i + 0.5·A_global</b>
Buffer->>Buffer: R_i = A_i + V_i(s)
Note over Trainer,Buffer: === 训练 (5 Epochs × batch 32) ===
loop 5 Epochs
Buffer-->>Trainer: (obs, a, old_log_prob, old_V_i, A_i, R_i)
Trainer->>GNN: 重新前向传播
GNN-->>Actor: node_features
GNN-->>Critic: node_features
Actor->>Actor: 新 log_prob
Critic->>Critic: 新 V_i (逐节点)
Trainer->>Trainer: ratio = exp(log_prob_new - log_prob_old)
Trainer->>Trainer: policy_loss = -min(ratio·A_i, clip(ratio,0.8,1.2)·A_i)
Trainer->>Trainer: value_loss = 0.5·clip(V_new, V_old±0.2) vs R_i
Trainer->>Trainer: backward() + grad_clip(0.5) + Adam.step()
end
```
## 论文公式 (3) 与代码对应
论文中的 TD 误差公式:
$$\delta^t_i = r(s^t, a^t)_i + \gamma \sum_j \phi_{ij}^t V_j(s^{t+1}) - V_i(s^t)$$
在代码中的实现路径 (`spatial_on_policy_buffer.py:174-178`):
```python
# _get_agent_wise_advantages_and_returns()
for step in range(self.buffer_size):
if self.dones[step]:
delta = self.rewards[step] - self.values[step] # r_i - V_i(s)
else:
delta = self.rewards[step] \
+ self.discount_factor * projected_next_values[step] \ # + γ·Σ_j φ_ij·V_j(s')
- self.values[step] # - V_i(s)
```
其中 `projected_next_values[step]``_project_to_previous_step()` 产生:
```python
# projection_type='sum'
projected_value = scatter_sum(values[step], index=agent_mappings[step], dim=0)
# ^^^^^^^^^^ ^^^^^^^^^^^^^^^^^^^^^
# V_j(s_{t+1}) φ_ij: 新agent j → 旧agent i
```
## 关键默认参数
| 参数 | 值 | 代码位置 |
|------|-----|----------|
| **算法** | PPO | `config["algorithm"]["name"]` |
| **网络骨架** | Homogeneous MPN | `config["network"]["type_of_base"]` |
| **GNN 架构** | mpn (message passing) | `config["network"]["base"]["architecture"]` |
| **潜在维度** | 64 | `config["network"]["latent_dimension"]` |
| **MP 步数** | 2 | `config["network"]["base"]["stack"]["num_steps"]` |
| **残差** | inner | `config["network"]["base"]["stack"]["residual_connections"]` |
| **层归一化** | inner | `config["network"]["base"]["stack"]["layer_norm"]` |
| **边→节点聚合** | mean | `config["network"]["base"]["scatter_reduce"]` |
| **Base MLP** | 2层, LeakyReLU | `config["network"]["base"]["stack"]["mlp"]` |
| **Actor MLP** | 2层, Tanh | `config["network"]["actor"]["mlp"]` |
| **Critic MLP** | 2层, Tanh | `config["network"]["critic"]["mlp"]` |
| **价值函数范围** | **spatial** (逐节点, 不聚合) | `config["algorithm"]["ppo"]["value_function_aggr"]` |
| **价值投影方式** | **sum** (agent_mapping 反投影用) | `config["algorithm"]["ppo"]["projection_type"]` |
| **混合奖励权重** | 0.5 | `config["algorithm"]["mixed_return"]["global_weight"]` |
| **共享 Base** | False (Actor/Critic 各自独立 GNN) | `config["network"]["share_base"]` |
| **动作分布** | DiagGaussian (连续) | 动作空间为 `gym.spaces.Box` |
| **Rollout 步数** | 256 | `config["algorithm"]["ppo"]["num_rollout_steps"]` |
| **训练轮次** | 5 | `config["algorithm"]["ppo"]["epochs_per_iteration"]` |
| **Batch 大小** | 32 | `config["algorithm"]["batch_size"]` |
| **GAE λ** | 0.95 | `config["algorithm"]["ppo"]["gae_lambda"]` |
| **折现 γ** | 1.0 | `config["algorithm"]["discount_factor"]` |
| **PPO clip** | 0.2 | `config["algorithm"]["ppo"]["clip_range"]` |
| **梯度裁剪** | 0.5 | `config["algorithm"]["ppo"]["max_grad_norm"]` |
| **学习率** | 3e-4 | `config["network"]["training"]["learning_rate"]` |
| **边 Dropout** | 0.1 | `config["network"]["base"]["edge_dropout"]` |
| **Episode 步数** | 6 | `config["environment"]["mesh_refinement"]["num_timesteps"]` |
| **PDE** | Poisson (GMM 负载, zero Dirichlet) | `config["environment"]["mesh_refinement"]["fem"]["pde_type"]` |
## projection_type 的两种职责
`projection_type` 在 Buffer 中有**两处**使用,都是通过 `agent_mapping` 做跨时间步的 agent 反投影:
### 1. 价值反投影 — 公式 (3) 的 Σ 项
```python
# _project_to_previous_step() — spatial_on_policy_buffer.py:33
projected_value = scatter_sum(values[step], index=agent_mappings[step], dim=0)
# 下一步的 V_j(s_{t+1}) 按 agent_mapping φ_ij 求和回当前步的 agent i
```
### 2. GAE 时间差分反投影 — 动态规划递推
```python
# _get_agent_wise_advantages_and_returns() — spatial_on_policy_buffer.py:169
projected_last_gae = scatter_sum(last_gae, index=self._agent_mappings[step], dim=0)
# 上一步累积的 GAE 按 agent_mapping 反投影
```
## 核心创新点
1. **Swarm 视角 + 变长 Agent**: 每个网格元素是一个 agent元素分裂后 agent 数量动态增长
2. **空间奖励 + agent_mapping**: 通过 `agent_mapping φ_ij` 追踪父→子关系,支持逐节点的 TD 误差计算(公式 3
3. **混合奖励学习**: 局部逐节点 Advantage + 全局图级 Advantage 加权混合 (0.5:0.5)
4. **MPN 通信**: 边更新 + 节点更新的消息传递,元素通过共享三角形边交换 PDE 解信息
5. **自适应细化**: 连续动作 → 概率性元素选择 → 非均匀网格,资源集中在误差大的区域