Metadata-Version: 2.1
Name: NatPy
Version: 0.1.3
Summary: Convert the units of particle physics quantities.
Home-page: https://github.com/AndreScaffidi/NatPy
Author: Tomas Howson and Andre Scaffidi
Author-email: tomas.howson@adelaide.edu.au, andre.scaffidi@adelaide.edu.au
Classifier: Programming Language :: Python :: 3
Classifier: License :: OSI Approved :: MIT License
Classifier: Operating System :: OS Independent
Requires-Python: >=3.7
Description-Content-Type: text/markdown
License-File: LICENSE
Requires-Dist: numpy
Requires-Dist: astropy

# NatPy

## Convert the units of particle physics quantities

---

### Packages needed:

- astropy
- numpy

---
### Guided Tutorial
https://github.com/AndreScaffidi/Natpy_pyhep_2021

### Basic Usage

Code levarages `astropy.units.core.Unit` and `astropy.units.quantity.Quantity` objects.

1. Run `import natpy`.
1. Access physical constants with symbol within `const`:

   ```
   >>> import natpy as nat

   >>> nat.const.c
   <class 'astropy.constants.codata2018.CODATA2018'> name='Speed of light in vacuum' value=299792458.0 uncertainty=0.0 unit='m / s' reference='CODATA 2018'>


   >>> nat.const.hbar
   <class 'astropy.constants.codata2018.CODATA2018'> name='Reduced Planck constant' value=1.0545718176461565e-34 uncertainty=0.0 unit='J s' reference='CODATA 2018'>

   ```

1. Access units with symbol. Combine with values or `numpy` objects to form quantities:

   ```
   >>> nat.m
   Unit("m")

   >>> nat.m / nat.s
   Unit("m / s")

   >>> 500 * nat.MeV
   <Quantity 500. MeV>
   ```

1. Specify base of natural units with `natpy.set_active_units()`. Pass a string corresponding to a list of default natural units, or a list of physical constants to set your own. The list of default bases may be found in `natpy/default_values.py`. The default sets c = ℏ = ε₀ = 1.

1. Run `natpy.convert()` to convert between units, including necessary factors of natural units. Pass just unit objects to obtain conversion factors. Pass quantity objects to perform conversions. E.g.

   ```
   >>> import natpy as nat

   # kg to keV
   >>> nat.convert(nat.kg, nat.keV)
   5.6173581670146864e+32

   # Electron mass
   >>> me = nat.convert(9.11e-31 * nat.kg, nat.keV)
   >>> me
   <Quantity 511.74132902 keV>

   # Energy of electron with momentum of 1 MeV
   >>> p = 1 * nat.MeV
   >>> E = np.sqrt(p**2 + me**2)

   # Convert to SI units
   >>> nat.convert(E, nat.J)
   <Quantity 1.79926309e-13 J>
   ```

   Note: Summing quantities of compatible units results in a quantity with the first terms units.

1. `natpy.convert()` may also be accessed as a method for unit or quantity objects.

   ```
   >>> import natpy as nat

   >>> nat.GeV.convert( nat.fm**(-1) )
   5.067730716156395

   >>> (1 * nat.GeV).convert( nat.fm**(-1) )
   <Quantity 5.06773072 1 / fm>
   ```

1. Electromagnetic constants are defined in the SI system by default:

   ```
   >>> nat.const.e
   <<class 'astropy.constants.codata2018.EMCODATA2018'> name='Electron charge' value=1.602176634e-19 uncertainty=0.0 unit='C' reference='CODATA 2018'>
   ```

   Values may be accessed in other systems as attributes of the `nat.const.cgs` submodule:

   ```
   >>> nat.const.cgs.e.gauss
   <<class 'astropy.constants.codata2018.EMCODATA2018'> name='Electron charge' value=4.803204712570263e-10 uncertainty=0.0 unit='Fr' reference='CODATA 2018'>
   ```

   The default system may be changed using `natpy.set_active_em_system()`, with arguments `si`, `gauss`, `esu` or `emu`:

   ```
   >>> nat.set_active_em_system('gauss')
   >>> nat.const.e
   <<class 'astropy.constants.codata2018.EMCODATA2018'> name='Electron charge' value=4.803204712570263e-10 uncertainty=0.0 unit='Fr' reference='CODATA 2018'>
   ```

1. Dimensionless unscales quantities may be constructed using `natpy.dimensionless_unscaled`, which is also bound to `natpy.dimensionless`, `natpy.unitless` and `natpy.one`, for added usability.

1. See `examples/conversion.py` for more examples.
