Analyze and enforce numerical stability for time-dependent PDE simulations. Use when selecting time steps, choosing explicit/implicit schemes, diagnosing numerical blow-up, checking CFL/Fourier criteria, von Neumann analysis, matrix conditioning, or detecting stiffness in advection/diffusion/reaction problems.
Install with the open skills CLI (global, non-interactive — available in every Claude Code session):
npx skills add FreedomIntelligence/OpenClaw-Medical-Skills --skill "numerical-stability" -g -a claude-code -yOr manually — clone and copy the skill directory (SKILL.md + companion files):
git clone --depth 1 https://github.com/FreedomIntelligence/OpenClaw-Medical-Skills /tmp/OpenClaw-Medical-Skills && cp -r /tmp/OpenClaw-Medical-Skills/skills/numerical-stability ~/.claude/skills/numerical-stabilityThis skill is a directory: SKILL.md is the entry point; the files below ship with it.
---
name: numerical-stability
description: Analyze and enforce numerical stability for time-dependent PDE simulations. Use when selecting time steps, choosing explicit/implicit schemes, diagnosing numerical blow-up, checking CFL/Fourier criteria, von Neumann analysis, matrix conditioning, or detecting stiffness in advection/diffusion/reaction problems.
allowed-tools: Read, Bash, Write, Grep, Glob
---
# Numerical Stability
## Goal
Provide a repeatable checklist and script-driven checks to keep time-dependent simulations stable and defensible.
## Requirements
- Python 3.8+
- NumPy (for matrix_condition.py and von_neumann_analyzer.py)
- See `scripts/requirements.txt` for dependencies
## Inputs to Gather
| Input | Description | Example |
|-------|-------------|---------|
| Grid spacing `dx` | Spatial discretization | `0.01 m` |
| Time step `dt` | Temporal discretization | `1e-4 s` |
| Velocity `v` | Advection speed | `1.0 m/s` |
| Diffusivity `D` | Thermal/mass diffusivity | `1e-5 m²/s` |
| Reaction rate `k` | First-order rate constant | `100 s⁻¹` |
| Dimensions | 1D, 2D, or 3D | `2` |
| Scheme type | Explicit or implicit | `explicit` |
## Decision Guidance
### Choosing Explicit vs Implicit
```
Is the problem stiff (fast + slow dynamics)?
├── YES → Use implicit or IMEX scheme
│ └── Check conditioning with matrix_condition.py
└── NO → Is CFL/Fourier satisfied with reasonable dt?
├── YES → Use explicit scheme (cheaper per step)
└── NO → Consider implicit or reduce dx
```
### Stability Limit Quick Reference
| Physics | Number | Explicit Limit (1D) | Formula |
|---------|--------|---------------------|---------|
| Advection | CFL | C ≤ 1 | `C = v·dt/dx` |
| Diffusion | Fourier | Fo ≤ 0.5 | `Fo = D·dt/dx²` |
| Reaction | Reaction | R ≤ 1 | `R = k·dt` |
**Multi-dimensional correction**: For d dimensions, diffusion limit is `Fo ≤ 1/(2d)`.
## Script Outputs (JSON Fields)
| Script | Key Outputs |
|--------|-------------|
| `scripts/cfl_checker.py` | `metrics.cfl`, `metrics.fourier`, `recommended_dt`, `stable` |
| `scripts/von_neumann_analyzer.py` | `results.max_amplification`, `results.stable` |
| `scripts/matrix_condition.py` | `results.condition_number`, `results.is_symmetric` |
| `scripts/stiffness_detector.py` | `results.stiffness_ratio`, `results.stiff`, `results.recommendation` |
## Workflow
1. **Identify dominant physics** (advection vs diffusion vs reaction)
2. **Run CFL checker** with `scripts/cfl_checker.py`
3. **Compare to limits** and adjust `dt` if needed
4. **Check stiffness** with `scripts/stiffness_detector.py` if multiple scales
5. **Analyze custom schemes** with `scripts/von_neumann_analyzer.py`
6. **Check conditioning** with `scripts/matrix_condition.py` for implicit solves
7. **Document** the stability verdict and recommended time step
## Conversational Workflow Example
**User**: My phase-field simulation is blowing up after 100 steps. I'm using explicit Euler with dx=0.01, dt=1e-4, and diffusivity D=1e-3.
**Agent workflow**:
1. Check stability criteria:
```bash
python3 scripts/cfl_checker.py --dx 0.01 --dt 1e-4 --diffusivity 1e-3 --dimensions 2 --json
```
2. Interpret results:
- Fourier number: `Fo = 1e-3 × 1e-4 / (0.01)² = 1.0`
- 2D limit: `Fo ≤ 0.25`
- **Violation**: Fo = 1.0 > 0.25, unstable!
3. Recommend fix:
- Reduce dt to `2.5e-5` (to get Fo = 0.25)
- Or increase dx, or switch to implicit
## Pre-Simulation Stability Checklist
- [ ] Identify dominant physics and nondimensional groups
- [ ] Compute CFL/Fourier/Reaction numbers with `cfl_checker.py`
- [ ] If explicit and limit violated, reduce `dt` or change scheme
- [ ] If stiffness ratio > 1000, select implicit/stiff integrator
- [ ] For custom schemes, verify amplification factor ≤ 1
- [ ] Document stability reasoning with inputs and outputs
## CLI Examples
```bash
# Check CFL/Fourier for 2D diffusion-advection
python3 scripts/cfl_checker.py --dx 0.1 --dt 0.01 --velocity 1.0 --diffusivity 0.1 --dimensions 2 --json
# Von Neumann analysis for custom 3-point stencil
python3 scripts/von_neumann_analyzer.py --coeffs 0.2,0.6,0.2 --dx 1.0 --nk 128 --json
# Detect stiffness from eigenvalue estimates
python3 scripts/stiffness_detector.py --eigs=-1,-1000 --json
# Check matrix conditioning for implicit system
python3 scripts/matrix_condition.py --matrix A.npy --norm 2 --json
```
## Error Handling
| Error | Cause | Resolution |
|-------|-------|------------|
| `dx and dt must be positive` | Zero or negative values | Provide valid positive numbers |
| `No stability criteria applied` | Missing velocity/diffusivity | Provide at least one physics parameter |
| `Matrix file not found` | Invalid path | Check matrix file exists |
| `Could not compute eigenvalues` | Singular or ill-formed matrix | Check matrix validity |
## Interpretation Guidance
| Scenario | Meaning | Action |
|----------|---------|--------|
| `stable: true` | All checked criteria satisfied | Proceed with simulation |
| `stable: false` | At least one limit violated | Reduce dt or change scheme |
| `stable: null` | No criteria could be applied | Provide more physics inputs |
| Stiffness ratio > 1000 | Problem is stiff | Use implicit integrator |
| Condition number > 10⁶ | Ill-conditioned | Use scaling/preconditioning |
## Limitations
- **Explicit schemes only** for CFL/Fourier checks (implicit is unconditionally stable)
- **Von Neumann analysis** assumes linear, constant-coefficient, periodic BCs
- **Stiffness detection** requires eigenvalue estimates from user
## References
- `references/stability_criteria.md` - Decision thresholds and formulas
- `references/common_pitfalls.md` - Frequent failure modes and fixes
- `references/scheme_catalog.md` - Stability properties of common schemes
## Version History
- **v1.1.0** (2024-12-24): Enhanced documentation, decision guidance, examples
- **v1.0.0**: Initial release with 4 stability analysis scripts
Use when facing 2+ independent tasks that can be worked on without shared state or sequential dependencies
Use when encountering any bug, test failure, or unexpected behavior, before proposing fixes
Use when implementing any feature or bugfix, before writing implementation code