.claude/skills/01_CHEATSHEET.md

# Atomizer Quick Reference Cheatsheet

**Version**: 1.0
**Purpose**: Rapid lookup for common operations. "I want X → Use Y"

---

## Task → Protocol Quick Lookup

| I want to... | Use Protocol | Key Command/Action |
|--------------|--------------|-------------------|
| Create a new optimization study | OP_01 | Generate `optimization_config.json` + `run_optimization.py` |
| Run an optimization | OP_02 | `conda activate atomizer && python run_optimization.py` |
| Check optimization progress | OP_03 | Query `study.db` or check dashboard at `localhost:3000` |
| See best results | OP_04 | `optuna-dashboard sqlite:///study.db` or dashboard |
| Export neural training data | OP_05 | `python run_optimization.py --export-training` |
| Fix an error | OP_06 | Read error log → follow diagnostic tree |
| Add custom physics extractor | EXT_01 | Create in `optimization_engine/extractors/` |
| Add lifecycle hook | EXT_02 | Create in `optimization_engine/plugins/` |

---

## Extractor Quick Reference

| Physics | Extractor | Function Call |
|---------|-----------|---------------|
| Max displacement | E1 | `extract_displacement(op2_file, subcase=1)` |
| Natural frequency | E2 | `extract_frequency(op2_file, subcase=1, mode_number=1)` |
| Von Mises stress | E3 | `extract_solid_stress(op2_file, subcase=1, element_type='cquad4')` |
| BDF mass | E4 | `extract_mass_from_bdf(bdf_file)` |
| CAD expression mass | E5 | `extract_mass_from_expression(prt_file, expression_name='p173')` |
| Field data | E6 | `FieldDataExtractor(field_file, result_column, aggregation)` |
| Stiffness (k=F/δ) | E7 | `StiffnessCalculator(...)` |
| Zernike WFE | E8 | `extract_zernike_from_op2(op2_file, bdf_file, subcase)` |
| Zernike relative | E9 | `extract_zernike_relative_rms(op2_file, bdf_file, target, ref)` |
| Zernike builder | E10 | `ZernikeObjectiveBuilder(op2_finder)` |
| Part mass + material | E11 | `extract_part_mass_material(prt_file)` → mass, volume, material |

**Full details**: See `SYS_12_EXTRACTOR_LIBRARY.md` or `modules/extractors-catalog.md`

---

## Protocol Selection Guide

### Single Objective Optimization
```
Question: Do you have ONE goal to minimize/maximize?
├─ Yes, simple problem (smooth, <10 params)
│   └─► Protocol 10 + CMA-ES or GP-BO sampler
│
├─ Yes, complex problem (noisy, many params)
│   └─► Protocol 10 + TPE sampler
│
└─ Not sure about problem characteristics?
    └─► Protocol 10 with adaptive characterization (default)
```

### Multi-Objective Optimization
```
Question: Do you have 2-3 competing goals?
├─ Yes (e.g., minimize mass AND minimize stress)
│   └─► Protocol 11 + NSGA-II sampler
│
└─ Pareto front needed?
    └─► Protocol 11 (returns best_trials, not best_trial)
```

### Neural Network Acceleration
```
Question: Do you need >50 trials OR surrogate model?
├─ Yes
│   └─► Protocol 14 (configure surrogate_settings in config)
│
└─ Training data export needed?
    └─► OP_05_EXPORT_TRAINING_DATA.md
```

---

## Configuration Quick Reference

### optimization_config.json Structure
```json
{
  "study_name": "my_study",
  "design_variables": [
    {"name": "thickness", "min": 1.0, "max": 10.0, "unit": "mm"}
  ],
  "objectives": [
    {"name": "mass", "goal": "minimize", "unit": "kg"}
  ],
  "constraints": [
    {"name": "max_stress", "type": "<=", "threshold": 250, "unit": "MPa"}
  ],
  "optimization_settings": {
    "protocol": "protocol_10_single_objective",
    "sampler": "TPESampler",
    "n_trials": 50
  },
  "simulation": {
    "model_file": "model.prt",
    "sim_file": "model.sim",
    "solver": "nastran"
  }
}
```

### Sampler Quick Selection
| Sampler | Use When | Protocol |
|---------|----------|----------|
| `TPESampler` | Default, robust to noise | P10 |
| `CMAESSampler` | Smooth, unimodal problems | P10 |
| `GPSampler` | Expensive FEA, few trials | P10 |
| `NSGAIISampler` | Multi-objective (2-3 goals) | P11 |
| `RandomSampler` | Characterization phase only | P10 |

---

## Study File Structure

```
studies/{study_name}/
├── 1_setup/
│   ├── model/              # NX files (.prt, .sim, .fem)
│   └── optimization_config.json
├── 2_results/
│   ├── study.db            # Optuna SQLite database
│   ├── optimizer_state.json # Real-time state (P13)
│   └── trial_logs/
├── README.md               # MANDATORY: Engineering blueprint
├── STUDY_REPORT.md         # MANDATORY: Results tracking
└── run_optimization.py     # Entrypoint script
```

---

## Common Commands

```bash
# Activate environment (ALWAYS FIRST)
conda activate atomizer

# Run optimization
python run_optimization.py

# Run with specific trial count
python run_optimization.py --n-trials 100

# Resume interrupted optimization
python run_optimization.py --resume

# Export training data for neural network
python run_optimization.py --export-training

# View results in Optuna dashboard
optuna-dashboard sqlite:///2_results/study.db

# Check study status
python -c "import optuna; s=optuna.load_study('my_study', 'sqlite:///2_results/study.db'); print(f'Trials: {len(s.trials)}')"
```

---

## Error Quick Fixes

| Error | Likely Cause | Quick Fix |
|-------|--------------|-----------|
| "No module named optuna" | Wrong environment | `conda activate atomizer` |
| "NX session timeout" | Model too complex | Increase `timeout` in config |
| "OP2 file not found" | Solve failed | Check NX log for errors |
| "No feasible solutions" | Constraints too tight | Relax constraint thresholds |
| "NSGA-II requires >1 objective" | Wrong protocol | Use P10 for single-objective |
| "Expression not found" | Wrong parameter name | Verify expression names in NX |
| **All trials identical results** | **Missing `*_i.prt`** | **Copy idealized part to study folder!** |

**Full troubleshooting**: See `OP_06_TROUBLESHOOT.md`

---

## CRITICAL: NX FEM Mesh Update

**If all optimization trials produce identical results, the mesh is NOT updating!**

### Required Files for Mesh Updates
```
studies/{study}/1_setup/model/
├── Model.prt           # Geometry
├── Model_fem1_i.prt    # Idealized part ← MUST EXIST!
├── Model_fem1.fem      # FEM
└── Model_sim1.sim      # Simulation
```

### Why It Matters
The `*_i.prt` (idealized part) MUST be:
1. **Present** in the study folder
2. **Loaded** before `UpdateFemodel()` (already implemented in `solve_simulation.py`)

Without it, `UpdateFemodel()` runs but the mesh doesn't change!

---

## Privilege Levels

| Level | Can Create Studies | Can Add Extractors | Can Add Protocols |
|-------|-------------------|-------------------|------------------|
| user | ✓ | ✗ | ✗ |
| power_user | ✓ | ✓ | ✗ |
| admin | ✓ | ✓ | ✓ |

---

## Dashboard URLs

| Service | URL | Purpose |
|---------|-----|---------|
| Atomizer Dashboard | `http://localhost:3000` | Real-time optimization monitoring |
| Optuna Dashboard | `http://localhost:8080` | Trial history, parameter importance |
| API Backend | `http://localhost:5000` | REST API for dashboard |

---

## Protocol Numbers Reference

| # | Name | Purpose |
|---|------|---------|
| 10 | IMSO | Intelligent Multi-Strategy Optimization (adaptive) |
| 11 | Multi-Objective | NSGA-II for Pareto optimization |
| 12 | - | (Reserved) |
| 13 | Dashboard | Real-time tracking and visualization |
| 14 | Neural | Surrogate model acceleration |
feat: Add MLP surrogate with Turbo Mode for 100x faster optimization Neural Acceleration (MLP Surrogate): - Add run_nn_optimization.py with hybrid FEA/NN workflow - MLP architecture: 4-layer (64->128->128->64) with BatchNorm/Dropout - Three workflow modes: - --all: Sequential export->train->optimize->validate - --hybrid-loop: Iterative Train->NN->Validate->Retrain cycle - --turbo: Aggressive single-best validation (RECOMMENDED) - Turbo mode: 5000 NN trials + 50 FEA validations in ~12 minutes - Separate nn_study.db to avoid overloading dashboard Performance Results (bracket_pareto_3obj study): - NN prediction errors: mass 1-5%, stress 1-4%, stiffness 5-15% - Found minimum mass designs at boundary (angle~30deg, thick~30mm) - 100x speedup vs pure FEA exploration Protocol Operating System: - Add .claude/skills/ with Bootstrap, Cheatsheet, Context Loader - Add docs/protocols/ with operations (OP_01-06) and system (SYS_10-14) - Update SYS_14_NEURAL_ACCELERATION.md with MLP Turbo Mode docs NX Automation: - Add optimization_engine/hooks/ for NX CAD/CAE automation - Add study_wizard.py for guided study creation - Fix FEM mesh update: load idealized part before UpdateFemodel() New Study: - bracket_pareto_3obj: 3-objective Pareto (mass, stress, stiffness) - 167 FEA trials + 5000 NN trials completed - Demonstrates full hybrid workflow 🤖 Generated with [Claude Code](https://claude.com/claude-code) Co-Authored-By: Claude Opus 4.5 <noreply@anthropic.com> 2025-12-06 20:01:59 -05:00			`# Atomizer Quick Reference Cheatsheet`

			`Version: 1.0`
			`Purpose: Rapid lookup for common operations. "I want X → Use Y"`

			`---`

			`## Task → Protocol Quick Lookup`

			`\| I want to... \| Use Protocol \| Key Command/Action \|`
			`\|--------------\|--------------\|-------------------\|`
			\| Create a new optimization study \| OP_01 \| Generate `optimization_config.json` + `run_optimization.py` \|
			\| Run an optimization \| OP_02 \| `conda activate atomizer && python run_optimization.py` \|
			\| Check optimization progress \| OP_03 \| Query `study.db` or check dashboard at `localhost:3000` \|
			\| See best results \| OP_04 \| `optuna-dashboard sqlite:///study.db` or dashboard \|
			\| Export neural training data \| OP_05 \| `python run_optimization.py --export-training` \|
			`\| Fix an error \| OP_06 \| Read error log → follow diagnostic tree \|`
			\| Add custom physics extractor \| EXT_01 \| Create in `optimization_engine/extractors/` \|
			\| Add lifecycle hook \| EXT_02 \| Create in `optimization_engine/plugins/` \|

			`---`

			`## Extractor Quick Reference`

			`\| Physics \| Extractor \| Function Call \|`
			`\|---------\|-----------\|---------------\|`
			\| Max displacement \| E1 \| `extract_displacement(op2_file, subcase=1)` \|
			\| Natural frequency \| E2 \| `extract_frequency(op2_file, subcase=1, mode_number=1)` \|
			\| Von Mises stress \| E3 \| `extract_solid_stress(op2_file, subcase=1, element_type='cquad4')` \|
			\| BDF mass \| E4 \| `extract_mass_from_bdf(bdf_file)` \|
			\| CAD expression mass \| E5 \| `extract_mass_from_expression(prt_file, expression_name='p173')` \|
			\| Field data \| E6 \| `FieldDataExtractor(field_file, result_column, aggregation)` \|
			\| Stiffness (k=F/δ) \| E7 \| `StiffnessCalculator(...)` \|
			\| Zernike WFE \| E8 \| `extract_zernike_from_op2(op2_file, bdf_file, subcase)` \|
			\| Zernike relative \| E9 \| `extract_zernike_relative_rms(op2_file, bdf_file, target, ref)` \|
			\| Zernike builder \| E10 \| `ZernikeObjectiveBuilder(op2_finder)` \|
			\| Part mass + material \| E11 \| `extract_part_mass_material(prt_file)` → mass, volume, material \|

			Full details: See `SYS_12_EXTRACTOR_LIBRARY.md` or `modules/extractors-catalog.md`

			`---`

			`## Protocol Selection Guide`

			`### Single Objective Optimization`
			```
			`Question: Do you have ONE goal to minimize/maximize?`
			`├─ Yes, simple problem (smooth, <10 params)`
			`│ └─► Protocol 10 + CMA-ES or GP-BO sampler`
			`│`
			`├─ Yes, complex problem (noisy, many params)`
			`│ └─► Protocol 10 + TPE sampler`
			`│`
			`└─ Not sure about problem characteristics?`
			`└─► Protocol 10 with adaptive characterization (default)`
			```

			`### Multi-Objective Optimization`
			```
			`Question: Do you have 2-3 competing goals?`
			`├─ Yes (e.g., minimize mass AND minimize stress)`
			`│ └─► Protocol 11 + NSGA-II sampler`
			`│`
			`└─ Pareto front needed?`
			`└─► Protocol 11 (returns best_trials, not best_trial)`
			```

			`### Neural Network Acceleration`
			```
			`Question: Do you need >50 trials OR surrogate model?`
			`├─ Yes`
			`│ └─► Protocol 14 (configure surrogate_settings in config)`
			`│`
			`└─ Training data export needed?`
			`└─► OP_05_EXPORT_TRAINING_DATA.md`
			```

			`---`

			`## Configuration Quick Reference`

			`### optimization_config.json Structure`
			```json
			`{`
			`"study_name": "my_study",`
			`"design_variables": [`
			`{"name": "thickness", "min": 1.0, "max": 10.0, "unit": "mm"}`
			`],`
			`"objectives": [`
			`{"name": "mass", "goal": "minimize", "unit": "kg"}`
			`],`
			`"constraints": [`
			`{"name": "max_stress", "type": "<=", "threshold": 250, "unit": "MPa"}`
			`],`
			`"optimization_settings": {`
			`"protocol": "protocol_10_single_objective",`
			`"sampler": "TPESampler",`
			`"n_trials": 50`
			`},`
			`"simulation": {`
			`"model_file": "model.prt",`
			`"sim_file": "model.sim",`
			`"solver": "nastran"`
			`}`
			`}`
			```

			`### Sampler Quick Selection`
			`\| Sampler \| Use When \| Protocol \|`
			`\|---------\|----------\|----------\|`
			\| `TPESampler` \| Default, robust to noise \| P10 \|
			\| `CMAESSampler` \| Smooth, unimodal problems \| P10 \|
			\| `GPSampler` \| Expensive FEA, few trials \| P10 \|
			\| `NSGAIISampler` \| Multi-objective (2-3 goals) \| P11 \|
			\| `RandomSampler` \| Characterization phase only \| P10 \|

			`---`

			`## Study File Structure`

			```
			`studies/{study_name}/`
			`├── 1_setup/`
			`│ ├── model/ # NX files (.prt, .sim, .fem)`
			`│ └── optimization_config.json`
			`├── 2_results/`
			`│ ├── study.db # Optuna SQLite database`
			`│ ├── optimizer_state.json # Real-time state (P13)`
			`│ └── trial_logs/`
			`├── README.md # MANDATORY: Engineering blueprint`
			`├── STUDY_REPORT.md # MANDATORY: Results tracking`
			`└── run_optimization.py # Entrypoint script`
			```

			`---`

			`## Common Commands`

			```bash
			`# Activate environment (ALWAYS FIRST)`
			`conda activate atomizer`

			`# Run optimization`
			`python run_optimization.py`

			`# Run with specific trial count`
			`python run_optimization.py --n-trials 100`

			`# Resume interrupted optimization`
			`python run_optimization.py --resume`

			`# Export training data for neural network`
			`python run_optimization.py --export-training`

			`# View results in Optuna dashboard`
			`optuna-dashboard sqlite:///2_results/study.db`

			`# Check study status`
			`python -c "import optuna; s=optuna.load_study('my_study', 'sqlite:///2_results/study.db'); print(f'Trials: {len(s.trials)}')"`
			```

			`---`

			`## Error Quick Fixes`

			`\| Error \| Likely Cause \| Quick Fix \|`
			`\|-------\|--------------\|-----------\|`
			\| "No module named optuna" \| Wrong environment \| `conda activate atomizer` \|
			\| "NX session timeout" \| Model too complex \| Increase `timeout` in config \|
			`\| "OP2 file not found" \| Solve failed \| Check NX log for errors \|`
			`\| "No feasible solutions" \| Constraints too tight \| Relax constraint thresholds \|`
			`\| "NSGA-II requires >1 objective" \| Wrong protocol \| Use P10 for single-objective \|`
			`\| "Expression not found" \| Wrong parameter name \| Verify expression names in NX \|`
			\| All trials identical results \| *Missing `_i.prt` \| Copy idealized part to study folder!** \|

			Full troubleshooting: See `OP_06_TROUBLESHOOT.md`

			`---`

			`## CRITICAL: NX FEM Mesh Update`

			`If all optimization trials produce identical results, the mesh is NOT updating!`

			`### Required Files for Mesh Updates`
			```
			`studies/{study}/1_setup/model/`
			`├── Model.prt # Geometry`
			`├── Model_fem1_i.prt # Idealized part ← MUST EXIST!`
			`├── Model_fem1.fem # FEM`
			`└── Model_sim1.sim # Simulation`
			```

			`### Why It Matters`
			The `*_i.prt` (idealized part) MUST be:
			`1. Present in the study folder`
			2. Loaded before `UpdateFemodel()` (already implemented in `solve_simulation.py`)

			Without it, `UpdateFemodel()` runs but the mesh doesn't change!

			`---`

			`## Privilege Levels`

			`\| Level \| Can Create Studies \| Can Add Extractors \| Can Add Protocols \|`
			`\|-------\|-------------------\|-------------------\|------------------\|`
			`\| user \| ✓ \| ✗ \| ✗ \|`
			`\| power_user \| ✓ \| ✓ \| ✗ \|`
			`\| admin \| ✓ \| ✓ \| ✓ \|`

			`---`

			`## Dashboard URLs`

			`\| Service \| URL \| Purpose \|`
			`\|---------\|-----\|---------\|`
			\| Atomizer Dashboard \| `http://localhost:3000` \| Real-time optimization monitoring \|
			\| Optuna Dashboard \| `http://localhost:8080` \| Trial history, parameter importance \|
			\| API Backend \| `http://localhost:5000` \| REST API for dashboard \|

			`---`

			`## Protocol Numbers Reference`

			`\| # \| Name \| Purpose \|`
			`\|---\|------\|---------\|`
			`\| 10 \| IMSO \| Intelligent Multi-Strategy Optimization (adaptive) \|`
			`\| 11 \| Multi-Objective \| NSGA-II for Pareto optimization \|`
			`\| 12 \| - \| (Reserved) \|`
			`\| 13 \| Dashboard \| Real-time tracking and visualization \|`
			`\| 14 \| Neural \| Surrogate model acceleration \|`