fluidsim

Framework for computational fluid dynamics simulations using Python. Use when running fluid dynamics simulations including Navier-Stokes equations (2D/3D), shallow water equations, stratified flows, or when analyzing turbulence, vortex dynamics, or geophysical flows. Provides pseudospectral methods with FFT, HPC support, and comprehensive output analysis.

153 stars

byMicrock

View on GitHub Installation ↓

Best use case

fluidsim is best used when you need a repeatable AI agent workflow instead of a one-off prompt.

Teams using fluidsim should expect a more consistent output, faster repeated execution, less prompt rewriting.

When to use this skill

You want a reusable workflow that can be run more than once with consistent structure.

When not to use this skill

You only need a quick one-off answer and do not need a reusable workflow.
You cannot install or maintain the underlying files, dependencies, or repository context.

Installation

Claude Code / Cursor / Codex

$curl -o ~/.claude/skills/fluidsim/SKILL.md --create-dirs "https://raw.githubusercontent.com/Microck/ordinary-claude-skills/main/skills_all/claude-scientific-skills/scientific-skills/fluidsim/SKILL.md"

Manual Installation

Download SKILL.md from GitHub
Place it in .claude/skills/fluidsim/SKILL.md inside your project
Restart your AI agent — it will auto-discover the skill

How fluidsim Compares

Feature / Agent	fluidsim	Standard Approach
Platform Support	Not specified	Limited / Varies
Context Awareness	High	Baseline
Installation Complexity	Unknown	N/A

Frequently Asked Questions

What does this skill do?

Where can I find the source code?

You can find the source code on GitHub using the link provided at the top of the page.

SKILL.md Source

# FluidSim

## Overview

FluidSim is an object-oriented Python framework for high-performance computational fluid dynamics (CFD) simulations. It provides solvers for periodic-domain equations using pseudospectral methods with FFT, delivering performance comparable to Fortran/C++ while maintaining Python's ease of use.

**Key strengths**:
- Multiple solvers: 2D/3D Navier-Stokes, shallow water, stratified flows
- High performance: Pythran/Transonic compilation, MPI parallelization
- Complete workflow: Parameter configuration, simulation execution, output analysis
- Interactive analysis: Python-based post-processing and visualization

## Core Capabilities

### 1. Installation and Setup

Install fluidsim using uv with appropriate feature flags:

```bash
# Basic installation
uv uv pip install fluidsim

# With FFT support (required for most solvers)
uv uv pip install "fluidsim[fft]"

# With MPI for parallel computing
uv uv pip install "fluidsim[fft,mpi]"
```

Set environment variables for output directories (optional):

```bash
export FLUIDSIM_PATH=/path/to/simulation/outputs
export FLUIDDYN_PATH_SCRATCH=/path/to/working/directory
```

No API keys or authentication required.

See `references/installation.md` for complete installation instructions and environment configuration.

### 2. Running Simulations

Standard workflow consists of five steps:

**Step 1**: Import solver
```python
from fluidsim.solvers.ns2d.solver import Simul
```

**Step 2**: Create and configure parameters
```python
params = Simul.create_default_params()
params.oper.nx = params.oper.ny = 256
params.oper.Lx = params.oper.Ly = 2 * 3.14159
params.nu_2 = 1e-3
params.time_stepping.t_end = 10.0
params.init_fields.type = "noise"
```

**Step 3**: Instantiate simulation
```python
sim = Simul(params)
```

**Step 4**: Execute
```python
sim.time_stepping.start()
```

**Step 5**: Analyze results
```python
sim.output.phys_fields.plot("vorticity")
sim.output.spatial_means.plot()
```

See `references/simulation_workflow.md` for complete examples, restarting simulations, and cluster deployment.

### 3. Available Solvers

Choose solver based on physical problem:

**2D Navier-Stokes** (`ns2d`): 2D turbulence, vortex dynamics
```python
from fluidsim.solvers.ns2d.solver import Simul
```

**3D Navier-Stokes** (`ns3d`): 3D turbulence, realistic flows
```python
from fluidsim.solvers.ns3d.solver import Simul
```

**Stratified flows** (`ns2d.strat`, `ns3d.strat`): Oceanic/atmospheric flows
```python
from fluidsim.solvers.ns2d.strat.solver import Simul
params.N = 1.0  # Brunt-Väisälä frequency
```

**Shallow water** (`sw1l`): Geophysical flows, rotating systems
```python
from fluidsim.solvers.sw1l.solver import Simul
params.f = 1.0  # Coriolis parameter
```

See `references/solvers.md` for complete solver list and selection guidance.

### 4. Parameter Configuration

Parameters are organized hierarchically and accessed via dot notation:

**Domain and resolution**:
```python
params.oper.nx = 256  # grid points
params.oper.Lx = 2 * pi  # domain size
```

**Physical parameters**:
```python
params.nu_2 = 1e-3  # viscosity
params.nu_4 = 0     # hyperviscosity (optional)
```

**Time stepping**:
```python
params.time_stepping.t_end = 10.0
params.time_stepping.USE_CFL = True  # adaptive time step
params.time_stepping.CFL = 0.5
```

**Initial conditions**:
```python
params.init_fields.type = "noise"  # or "dipole", "vortex", "from_file", "in_script"
```

**Output settings**:
```python
params.output.periods_save.phys_fields = 1.0  # save every 1.0 time units
params.output.periods_save.spectra = 0.5
params.output.periods_save.spatial_means = 0.1
```

The Parameters object raises `AttributeError` for typos, preventing silent configuration errors.

See `references/parameters.md` for comprehensive parameter documentation.

### 5. Output and Analysis

FluidSim produces multiple output types automatically saved during simulation:

**Physical fields**: Velocity, vorticity in HDF5 format
```python
sim.output.phys_fields.plot("vorticity")
sim.output.phys_fields.plot("vx")
```

**Spatial means**: Time series of volume-averaged quantities
```python
sim.output.spatial_means.plot()
```

**Spectra**: Energy and enstrophy spectra
```python
sim.output.spectra.plot1d()
sim.output.spectra.plot2d()
```

**Load previous simulations**:
```python
from fluidsim import load_sim_for_plot
sim = load_sim_for_plot("simulation_dir")
sim.output.phys_fields.plot()
```

**Advanced visualization**: Open `.h5` files in ParaView or VisIt for 3D visualization.

See `references/output_analysis.md` for detailed analysis workflows, parametric study analysis, and data export.

### 6. Advanced Features

**Custom forcing**: Maintain turbulence or drive specific dynamics
```python
params.forcing.enable = True
params.forcing.type = "tcrandom"  # time-correlated random forcing
params.forcing.forcing_rate = 1.0
```

**Custom initial conditions**: Define fields in script
```python
params.init_fields.type = "in_script"
sim = Simul(params)
X, Y = sim.oper.get_XY_loc()
vx = sim.state.state_phys.get_var("vx")
vx[:] = sin(X) * cos(Y)
sim.time_stepping.start()
```

**MPI parallelization**: Run on multiple processors
```bash
mpirun -np 8 python simulation_script.py
```

**Parametric studies**: Run multiple simulations with different parameters
```python
for nu in [1e-3, 5e-4, 1e-4]:
    params = Simul.create_default_params()
    params.nu_2 = nu
    params.output.sub_directory = f"nu{nu}"
    sim = Simul(params)
    sim.time_stepping.start()
```

See `references/advanced_features.md` for forcing types, custom solvers, cluster submission, and performance optimization.

## Common Use Cases

### 2D Turbulence Study

```python
from fluidsim.solvers.ns2d.solver import Simul
from math import pi

params = Simul.create_default_params()
params.oper.nx = params.oper.ny = 512
params.oper.Lx = params.oper.Ly = 2 * pi
params.nu_2 = 1e-4
params.time_stepping.t_end = 50.0
params.time_stepping.USE_CFL = True
params.init_fields.type = "noise"
params.output.periods_save.phys_fields = 5.0
params.output.periods_save.spectra = 1.0

sim = Simul(params)
sim.time_stepping.start()

# Analyze energy cascade
sim.output.spectra.plot1d(tmin=30.0, tmax=50.0)
```

### Stratified Flow Simulation

```python
from fluidsim.solvers.ns2d.strat.solver import Simul

params = Simul.create_default_params()
params.oper.nx = params.oper.ny = 256
params.N = 2.0  # stratification strength
params.nu_2 = 5e-4
params.time_stepping.t_end = 20.0

# Initialize with dense layer
params.init_fields.type = "in_script"
sim = Simul(params)
X, Y = sim.oper.get_XY_loc()
b = sim.state.state_phys.get_var("b")
b[:] = exp(-((X - 3.14)**2 + (Y - 3.14)**2) / 0.5)
sim.state.statephys_from_statespect()

sim.time_stepping.start()
sim.output.phys_fields.plot("b")
```

### High-Resolution 3D Simulation with MPI

```python
from fluidsim.solvers.ns3d.solver import Simul

params = Simul.create_default_params()
params.oper.nx = params.oper.ny = params.oper.nz = 512
params.nu_2 = 1e-5
params.time_stepping.t_end = 10.0
params.init_fields.type = "noise"

sim = Simul(params)
sim.time_stepping.start()
```

Run with:
```bash
mpirun -np 64 python script.py
```

### Taylor-Green Vortex Validation

```python
from fluidsim.solvers.ns2d.solver import Simul
import numpy as np
from math import pi

params = Simul.create_default_params()
params.oper.nx = params.oper.ny = 128
params.oper.Lx = params.oper.Ly = 2 * pi
params.nu_2 = 1e-3
params.time_stepping.t_end = 10.0
params.init_fields.type = "in_script"

sim = Simul(params)
X, Y = sim.oper.get_XY_loc()
vx = sim.state.state_phys.get_var("vx")
vy = sim.state.state_phys.get_var("vy")
vx[:] = np.sin(X) * np.cos(Y)
vy[:] = -np.cos(X) * np.sin(Y)
sim.state.statephys_from_statespect()

sim.time_stepping.start()

# Validate energy decay
df = sim.output.spatial_means.load()
# Compare with analytical solution
```

## Quick Reference

**Import solver**: `from fluidsim.solvers.ns2d.solver import Simul`

**Create parameters**: `params = Simul.create_default_params()`

**Set resolution**: `params.oper.nx = params.oper.ny = 256`

**Set viscosity**: `params.nu_2 = 1e-3`

**Set end time**: `params.time_stepping.t_end = 10.0`

**Run simulation**: `sim = Simul(params); sim.time_stepping.start()`

**Plot results**: `sim.output.phys_fields.plot("vorticity")`

**Load simulation**: `sim = load_sim_for_plot("path/to/sim")`

## Resources

**Documentation**: https://fluidsim.readthedocs.io/

**Reference files**:
- `references/installation.md`: Complete installation instructions
- `references/solvers.md`: Available solvers and selection guide
- `references/simulation_workflow.md`: Detailed workflow examples
- `references/parameters.md`: Comprehensive parameter documentation
- `references/output_analysis.md`: Output types and analysis methods
- `references/advanced_features.md`: Forcing, MPI, parametric studies, custom solvers

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