Metadata-Version: 2.1
Name: hw2d
Version: 1.0.0
Summary: Reference HW2D Implementation in Python
Author-email: Robin Greif <rccgreif@gmail.com>
License: MIT
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Keywords: Plasma Physics,Simulation,Turbulence
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# The Hasegawa-Wakatani model of plasma turbulence

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This repository contains a reference implementations for the Hasegawa-Wakatani model in two dimensions using Python.
The purpose is to provide a playground for education and scientific purposes: be it testing numerical or machine learning methods, or building related models quicker, while improving the comparability of results.

Stable, verified parameters and values are published along with this repository.

### Installation 

Install a pure NumPy version via
```pip install hw2d```
and to include accelerators (currently supporting: numba), use the following:
```pip install hw2d[accelerators]```

### Usage

Running `python -m hw2d` will let you run a hw2d simulation. It exposes the CLI Interface of the code located in src/hw2d/run.py with all parameters available there. Simply run `python -m hw2d --help` to get a full rundown of all available parameters along with their explanations.

If accelerators like numba are installed, these will be used automatically. To manually decide which function should be run with which accelerator, simply change the imports in srd/hw2d/model.py to select the appropriate function. Default uses Numba for periodic gradients and the arakawa scheme, and to be extended in the future.

### Example Usage 

Example of running a fully converged turbulent simulation:
```python
python -m hw2d --step_size=0.025 --end_time=1000 --grid_pts=512 --c1=1.0 --k0=0.15 --N=3 --nu=5.0e-08 --snaps=1 --buffer_size=100 --output_path="test.h5" --movie=1 --min_fps=10 --speed=5 --debug=0
```
The code will run a grid of `512x512` in steps of `0.025` from 0 to `1000` for an adiabatic coefficient of `1.0` and hyperdiffusion of order `3` with a coefficient of `5.0e-08`. The resulting data will be saved after every `1` frame and written in batches of `100` into file `test.h5`. This file will then be turned into a movie with at least `10` frames per second, running at `5`t per second. The entire process will use no debugging. 

Full documentation is available at: https://the-rccg.github.io/hw2d/

### Reference Methods

The implementation presented here is by no means meant to be the optimal, but an easy to understand starting point to build bigger things upon and serve as a reference for other work.
This reference implementation uses:

- Gradients $\left(\partial_x, \partial_y, \nabla \right)$: Central finite difference schemes (2nd order accurate)
- Poisson Bracket $\left([\cdot, \cdot]\right)$: Arakawa Scheme (2nd order accurate, higher order preserving)
- Poisson Solver $\left(\nabla^{-2}\cdot\right)$: Fourier based solver
- Time Integration $\left(\partial_t\right)$: Explicit Runge Kutte (4th order accurate)

The framework presented here can be easily extended to use alternative implementations.

### Contributions encouraged

Pull requests are strongly encouraged. 

The simplest way to contribute is running simulations and committing the results to the historical runs archive. This helps in exploring the hyper-parameter space and improving statistical reference values for all.

If you don't know where to start in contributing code, implementing new numerical methods or alternative accelerators make for good first projects!

### Code guidelines

All commits are auto-formatted using `Black` to keep a uniform presentation.


## The Hasegawa-Wakatani Model

The HW model describes drift-wave turbulence using two physical fields: the density $n$ and the potential $\phi$ using various gradients on these.

$$
\begin{align}
    \partial_t n &= c_1 \left( \phi - n \right)
                     - \left[ \phi, n \right]
                     - \kappa_n \partial_y \phi
                     - \nu \nabla^{2N} n 
    \\\
    \partial_t \Omega &= c_1 \left( \phi - n \right)
                                      - \left[ \phi, \Omega \right]
                                      - \nu \nabla^{2N} \Omega 
    \\\
    \Omega &= \nabla^2 \phi
\end{align}
$$



https://github.com/the-rccg/hw2d/assets/28964733/30d40e53-72a9-49b5-9bc5-87dc3f10a076




## Dynamics of the different phases

The model produces self-organizing turbulent structures in a three distinct stages: initial self-organization, linear drift waves, and a stable turbulent phase.

For the interesting intermediary phase for the adiabatic coefficient, `c1=1`, the initial perturbation will start organizing to produce linear drift waves through the $\partial_t \phi$ component. 
The system transitions into this first linear phase at roughly t=15, saturates at around t=45, and breaks down to transition into the turbulent phase at about t=80.
The turbulent phase is visually saturated at around t=125, but physical parameters overshoot and only fall into the long term stable phase at aroung t=200. 


## Physical Properties

### Numerical values for each frame

The reason why the Hasegawa-Wakatani Model has been the de-facto testing bed for new methods are its statistically stationary properties of the complex turbulent system.
The moduel includes all code needed to generate these values.
It goes further, however, and provides reference values along with statistical bounds for the first time for a vast range of values.
This allows simple comparison, as well es evalutaion of new methods to one reference community built resource.

$$
\begin{align}
    \Gamma^n &= -     \iint{ \mathrm{d}^2x \space \left( n \space \partial_y \phi \right) }  \\\
    \Gamma^c &= c_1   \iint{ \mathrm{d}^2x \space \left(n - \phi \right)^2}  \\\
    E        &= \small \frac{1}{2} \normalsize \iint{\mathrm{d}^2 x \space \left(n^2 - \left|\nabla_\bot \phi \right|^2 \right)}  \\\
    U        &= \small \frac{1}{2} \normalsize \iint{\mathrm{d}^2 x \space \left(n-\nabla_\bot^2  \phi\right)^2} = \small \frac{1}{2} \normalsize \iint{\mathrm{d}^2 x \space \left(n-\Omega\right)^2}    
\end{align}
$$


### Spectral values for each frame

Additionally, some spectral properties are included for more detailed analysis beyond the scalar factors, among these are:

$$
\begin{align}
  \Gamma^n \small (k_y) \normalsize  &= - i k_y  \space n \small (k_y) \normalsize \space \phi^* \small (k_y) \normalsize  \\\
  \delta \small (k_y) \normalsize    &= - \mathrm{Im}\left( \mathrm{log} \left( n^* \small (k_y) \normalsize \space \phi \small (k_y) \normalsize \right) \right)   \\\
  E^N \small (k_y) \normalsize       &= \small \frac{1}{2}\normalsize \big| n \small (k_y) \normalsize \big|^2   \\\
  E^V \small (k_y) \normalsize       &= \small \frac{1}{2}\normalsize \big| k_y \space \phi \small (k_y) \normalsize \big|^2     
\end{align}
$$


### Predictable in- and outflows over time

Finally, due to the definition of the fields as perturbation fields with background desnity gradients, the system gains and loses energy and enstrophy in a predictable manner over time.
The conservation of these are also tested within the continuous integration pipeline.
The definitions are given by:

$$
\begin{align}
    \partial_t E   &= \Gamma^N - \Gamma ^c - \mathfrak{D}^E  \\\
    \partial_t U   &= \Gamma^N - \mathfrak{D}^U   \\\
    \mathfrak{D}^E &= \quad \iint{ \mathrm{d}^2x \space (n \mathfrak{D^n} - \phi \mathfrak{D}^\phi)}  \\\
    \mathfrak{D}^U &= -     \iint{ \mathrm{d}^2x \space (n - \Omega)(\mathfrak{D}^n - \mathfrak{D}^\phi)}  \\\
    with \quad \mathfrak{D}^n \small (x,y) \normalsize &= \nu \nabla^{2N} n \quad and \quad 
    \mathfrak{D}^\phi \small (x,y) \normalsize = \nu \nabla^{2N} \phi  
\end{align}
$$

### General notes

It is the common practice across all reference texts to calculate $\int\cdot$ as $\langle \cdot \rangle$ for a unitless box of size one in order to get comparable values for all properties.


## Common Issues in Simulating HW2D

### Crashing/NaN encountered 

#### within < 10 timesteps

The simulation has exploded in one direction. Most commonly this means that the hyper-diffusion components are too large. 
- reduce the hyper diffusion order: `N`
- reduce the diffusion coefficient: `nu`
- reduce the initial perturbation: `scale`


#### around t=75-125

The timestep is too big in the turbulent phase. CFL criteria are no longer satisfied and simulation crashes.
- reduce: `step_size`

### Chessboard pattern emerges

The energy accumulates at grid scale. Hyper-diffusion component is not large enough to dissipate the energy.
- increase: `nu`
- increase: `N`
  

### Physical values deviate from references

The HW2D model can create stable simulations that are underresolved, through very large hyper-diffusion terms. A higher resolution is needed for this box size.
- increase: `grid_pts`

If the esntrophy goes way above reference values, however, it can mean that the hyper-diffusion is too small.
- increase: `nu`

# References

The region between the adiabatic and hydrodynamic limit is defined at `c_1=1`. For this dynamic and a box size of `k0=0.15`, a minimum grid size of `512x512` is needed at a `dt=0.025`. To generate a stable simulation with hyperdiffusion (`N=3`) requires a value of `nu=5e-08`.

## Reference Step Sizes

Minimum step sizes for the system can be evaluated by setting hyperdiffusion to zero `N=0` and `nu=0` and running to about `age=200` to reach into the turbulent steady-state regime.

| integrator | `c1` | Box Size | `grid_pts` | min `dt` |
| ---------- | ---- | -------- | ---------- | -------- |
| rk4        | 1.0  | 0.15     | 1024x1024  | 0.025    |
| rk4        | 1.0  | 0.15     | 512x512    | 0.025    |
| rk4        | 1.0  | 0.15     | 256x256    | 0.05     |
| rk4        | 1.0  | 0.15     | 128x128    | 0.05     |
| rk4        | 1.0  | 0.15     | 64x64      | 0.05     |
| rk4        | 1.0  | 0.15     | 32x32      | 0.05     |


## Reference Timetraces

Sample traces are given for `512x512`, `dt=0.05`, `c1=1`, `N=3`, and `nu=5e-08`. Note that the statistical nature does mean single simulations can deviate for quite some time from the statistical mean.

![Plot1](imgs/gamma_n-and-gamma_c.jpg)
![Plot2](imgs/enstrophy-energy-kinetic_energy-thermal_energy.jpg)


## Reference Values

Reference values are averaged over 25 runs starting from well within the turbulent steady-state `t=300` with the standard deviation across the simulations denoted by $\pm$. 
Each run to `t=1,000` at `512x512` and `dt=0.025` requires roughly 125GB (3 million floats/frame for 3 fields over 40,000 frames per simulation), meaning the summary contains information for 10TB of data. This does not include the hypterparameter stabilization tests. 
As a result, it is practically unfeasible to supply this data. 

| **Metric**           | **Our Data**    | **Stegmeir** | **Camargo** | **HW**     | **Zeiler** |
| -------------------- | --------------- | ------------ | ----------- | ---------- | ---------- |
| ****                 | 512x512         | [@grillix]   | [@camargo]  | [@grillix] | [@zeiler]  |
| **$\Gamma_n$**       | $0.60 \pm 0.01$ | $0.64$       | $0.73$      | $0.61$     | $0.8$      |
| **$\delta\Gamma_n$** | $0.05 \pm 0.01$ | $n/a$        | $n/a$       | $n/a$      | $n/a$      |
| **$\Gamma_c$**       | $0.60 \pm 0.01$ | $n/a$        | $0.72$      | $n/a$      | $n/a$      |
| **$\delta\Gamma_n$** | $0.03 \pm 0.01$ | $n/a$        | $n/a$       | $n/a$      | $n/a$      |
| **$E$**              | $3.78 \pm 0.07$ | $3.97$       | $4.4$       | $3.82$     | $6.1$      |
| **$\delta E$**       | $0.29 \pm 0.03$ | $0.26$       | $0.16$      | $0.26$     | $0.51$     |
| **$U$**              | $13.2 \pm 0.91$ | $n/a$        | $12.8$      | $n/a$      | $n/a$      |
| **$\delta U$**       | $0.68 \pm 0.08$ | $n/a$        | $1.66$      | $n/a$      | $n/a$      |

