Metadata-Version: 2.4
Name: linerate
Version: 2.1.0
Summary: Library for computing line ampacity ratings for overhead lines
Author-email: Statnett Datascience <Datascience.Drift@Statnett.no>, Yngve Mardal Moe <yngve.m.moe@gmail.com>
Requires-Python: >=3.9
Description-Content-Type: text/markdown
License-File: LICENSE
Requires-Dist: numpy
Requires-Dist: scipy
Requires-Dist: numba>=0.56.4
Requires-Dist: pygeodesy
Dynamic: license-file

# Overview

A package containing functionality to compute ampacity line ratings for overhead lines.
Currently, the package only contains equations from CIGRE TB 601.

## Installation

```raw
pip install linerate
```

## Documentation

This library is split into four main parts:

 1. The `equations` module, which contains one pure function for each equation in CIGRE TB 601,
 2. the `types` module, which contains datatypes for conductors, weather parameters and spans,
 3. the `model` module, which contains a wrapper class `Cigre601` to easily compute the ampacity and conductor temperature based on a `Span` and `Weather` instance,
 4. and the `solver` module, which contains a vectorized bisection solver for estimating the steady state ampacity and temperature of a conductor.

A typical user of this software package will only use the `types` and `model` module,
and the `model` module will then use functions from `equations` and `solver` to estimate the conductor temperature and ampacity. However, to understand the parameters, it may be useful to look at the functions
in the `equations` module, as we have taken care to ensure that the argument names stay consistent.

Below, we see an example of how to compute the conductor temperature based on *Example B* on page 79-81 in CIGRE TB 601.

```python
import numpy as np
import linerate


conductor = linerate.Conductor(
    core_diameter=10.4e-3,
    conductor_diameter=28.1e-3,
    outer_layer_strand_diameter=2.2e-3,
    emissivity=0.9,
    solar_absorptivity=0.9,
    temperature1=25,
    temperature2=75,
    resistance_at_temperature1=7.283e-5,
    resistance_at_temperature2=8.688e-5,
    aluminium_cross_section_area=float("nan"),  # No core magnetisation loss
    constant_magnetic_effect=1,
    current_density_proportional_magnetic_effect=0,
    max_magnetic_core_relative_resistance_increase=1,
)


start_tower = linerate.Tower(latitude=50 - 0.0045, longitude=0, altitude=500 - 88)
end_tower = linerate.Tower(latitude=50 + 0.0045, longitude=0, altitude=500 + 88)
span = linerate.Span(
    conductor=conductor,
    start_tower=start_tower,
    end_tower=end_tower,
    num_conductors=1,
)


weather = linerate.Weather(
    air_temperature=20,
    wind_direction=np.radians(80),  # Conductor azimuth is 0, so angle of attack is 80
    wind_speed=1.66,
    ground_albedo=0.15,
    clearness_ratio=0.5,
)


time_of_measurement = np.datetime64("2016-10-03 14:00")
max_conductor_temperature = 100
current_load = 1000

model = linerate.Cigre601(span, weather, time_of_measurement)
conductor_rating = model.compute_steady_state_ampacity(max_conductor_temperature)
print(f"The span has a steady-state ampacity rating of {conductor_rating:.0f} A if the maximum temperature is {max_conductor_temperature} °C")
conductor_temperature = model.compute_conductor_temperature(current_load)
print(f"The conductor has a temperature of {conductor_temperature:.0f} °C when operated at {current_load} A")
```

## Transient state solver

There is currently no transient solver or short time thermal rating solver, but that is on the roadmap.

## Development

Dependencies for the project are managed with uv.
To install all dependencies run:

```raw
uv sync
```

### Generate docs
To generate docs locally:
- Install required dependencies with `uv sync --group docs`.
- Generate docs with `uv run make html` in the `docs` folder.

### Release new version
Press the "Draft new release" button on the [Releases](https://github.com/statnett/linerate/releases) page.
Choose or create an appropriate tag, e.g. `1.2.3`.
Press "Generate release notes" to generate release notes.
Edit Release notes if necessary and press "Publish release".
This causes the publish workflow to run, which publishes the package to PyPI and generates [docs on Github pages](https://statnett.github.io/linerate/).
