6.8 KiB
Zernike Trajectory Method for Elevation-Dependent Optimization
Document Version: 1.0
Created: 2026-01-29
Author: Mario (Clawdbot) + Antoine Letarte
Status: Validated ✅
Executive Summary
The Zernike Trajectory Method provides mode-specific optimization objectives for telescope mirrors operating across multiple elevation angles. Instead of optimizing a weighted sum of discrete WFE values, this method:
- Tracks how each Zernike mode evolves with elevation angle
- Fits a physics-based linear model to the trajectory
- Provides integrated RMS metrics for each aberration type
- Reveals which modes respond to axial vs lateral gravity loads
Key result: For a well-designed support system, the linear model achieves R² ≈ 1.0, meaning deformation is entirely predictable from the gravity load decomposition.
1. Physics Background
1.1 Gravity Load Decomposition
At elevation angle θ from horizontal:
Axial load (along optical axis): F_axial ∝ sin(θ)
Lateral load (perpendicular): F_lateral ∝ cos(θ)
For a linear elastic structure, surface deformation is linear in these load components.
1.2 Zernike Coefficient Evolution
Each Zernike coefficient c_j follows:
c_j(θ) = a_j · (sin(θ) - sin(θ_ref)) + b_j · (cos(θ) - cos(θ_ref))
Where:
θ_ref= reference angle (typically 20° for polishing/measurement)a_j= sensitivity of mode j to axial load changeb_j= sensitivity of mode j to lateral load change
1.3 The Sensitivity Matrix
Define trajectory parameters:
τ(θ) = [sin(θ) - sin(θ_ref), cos(θ) - cos(θ_ref)]ᵀ
The full coefficient vector evolves as:
c⃗(θ) = S · τ(θ)
Where S is the sensitivity matrix (N_modes × 2).
2. Implementation
2.1 Extractor Location
optimization_engine/extractors/extract_zernike_trajectory.py
2.2 Basic Usage
from optimization_engine.extractors.extract_zernike_trajectory import extract_zernike_trajectory
result = extract_zernike_trajectory(
'path/to/solution.op2',
reference_angle=20.0, # Reference elevation (degrees)
)
# Mode-specific integrated RMS (nm)
print(result['coma_rms_nm'])
print(result['astigmatism_rms_nm'])
print(result['trefoil_rms_nm'])
print(result['spherical_rms_nm'])
# Total filtered RMS across all angles
print(result['total_filtered_rms_nm'])
# Linear model fit quality (should be > 0.95)
print(result['linear_fit_r2'])
# Sensitivity analysis
print(result['sensitivity_matrix'])
# {'coma': {'axial': 0.63, 'lateral': 36.04, 'total': 36.05}, ...}
2.3 Auto-Detection Features
The extractor automatically:
- Reads subcase labels from OP2 metadata (e.g., "20", "40", "60")
- Excludes manufacturing angle (90°) by default
- Sorts angles for proper trajectory fitting
2.4 Output Dictionary
{
# Mode-specific integrated RMS (nm)
'coma_rms_nm': float,
'astigmatism_rms_nm': float,
'trefoil_rms_nm': float,
'spherical_rms_nm': float,
'secondary_astig_rms_nm': float,
'secondary_coma_rms_nm': float,
'quadrafoil_rms_nm': float,
# Total filtered RMS (all modes, integrated)
'total_filtered_rms_nm': float,
# Model quality
'linear_fit_r2': float, # Should be > 0.95
# Sensitivity analysis
'sensitivity_matrix': {
'coma': {'axial': float, 'lateral': float, 'total': float},
'astigmatism': {...},
...
},
# Mode ranking (by sensitivity)
'mode_ranking': ['spherical', 'coma', 'astigmatism', ...],
'dominant_mode': str,
# Metadata
'angles_deg': [20.0, 30.0, 40.0, 50.0, 60.0],
'reference_angle': 20.0,
}
3. Optimization Integration
3.1 AtomizerSpec Configuration
extractors:
- id: ext_trajectory
name: "Zernike Trajectory"
type: zernike_trajectory
config:
reference_angle: 20.0
# Subcases auto-detected from OP2 labels
objectives:
# Option A: Single combined objective
- id: obj_total
name: "Total Integrated RMS"
source:
extractor_id: ext_trajectory
output_name: total_filtered_rms_nm
direction: minimize
weight: 1.0
# Option B: Mode-specific objectives (multi-objective)
- id: obj_coma
name: "Coma RMS"
source:
extractor_id: ext_trajectory
output_name: coma_rms_nm
direction: minimize
weight: 1.0
- id: obj_astig
name: "Astigmatism RMS"
source:
extractor_id: ext_trajectory
output_name: astigmatism_rms_nm
direction: minimize
weight: 0.8
3.2 Recommended Optimization Strategy
For SAT (Surrogate-Assisted Tuning):
- Use
total_filtered_rms_nmas primary objective - Add mode-specific objectives as secondary for Pareto analysis
- SAT handles the expensive FEA evaluations efficiently
For TPE (Tree-Parzen Estimator):
- Good for single-objective optimization
- Use weighted combination if needed:
J = w_coma * coma_rms + w_astig * astig_rms + w_total * total_rms
4. Validation Results (M1 Mirror, 2026-01-29)
4.1 Test Configuration
- Model: M1 GigaBIT mirror (1.2m Zerodur)
- Angles: 20°, 30°, 40°, 50°, 60° (5 subcases)
- Reference: 20° (polishing/measurement)
4.2 Linear Fit Quality
R² = 1.0000 ← PERFECT FIT
The physics model is exactly correct for this mirror design.
4.3 Mode-Specific Results
| Mode | Integrated RMS (nm) | Axial Sensitivity | Lateral Sensitivity |
|---|---|---|---|
| Secondary Astig | 12.95 | 1.93 | 48.91 |
| Spherical | 10.57 | 19.84 | 68.08 |
| Coma | 9.14 | 0.63 | 36.04 |
| Trefoil | 6.83 | — | — |
| Astigmatism | 6.80 | — | — |
Key insight: Coma is almost entirely driven by lateral loads (axial/lateral ratio = 0.02). Optimizing lateral support locations will have the biggest impact on coma.
5. Troubleshooting
5.1 Low R² Value
If R² < 0.9:
- Check for contact nonlinearity (supports lifting off)
- Check for material nonlinearity
- Verify subcases have consistent boundary conditions
5.2 Missing Subcases
Ensure your FEA includes all required angles. Minimum recommended:
- 20° (reference)
- 40° (primary operational)
- 60° (secondary operational)
Adding 30° and 50° improves trajectory fit quality.
5.3 Subcase Label Detection
If auto-detection fails, specify manually:
result = extract_zernike_trajectory(
'solution.op2',
subcases=[2, 5, 3, 6, 4], # Subcase IDs
angles=[20.0, 30.0, 40.0, 50.0, 60.0], # Corresponding angles
)
6. References
- ZERNIKE_OPD_METHOD.md — OPD correction for lateral displacement
- ZERNIKE_FUNDAMENTALS.md — Zernike polynomial basics
- AtomizerSpec v2.0 — Objective/extractor configuration
Document maintained by Atomizer Framework. Last updated: 2026-01-29