Metadata-Version: 2.1
Name: numpsy
Version: 0.0.3
Summary: NumpSy - Integrated NumPy, SymPy, Pandas and unit management for scientific programming.
Home-page: https://github.com/daquintero/numpsy
Author: Dario Quintero
Author-email: darioaquintero@gmail.com
License: UNKNOWN
Description: # NumpSy
        
        Straight up mix between NumPy, SymPy and Pandas into a value single-declaration extendable framework to simulatenously perform symbolic and numerical operations.
        
        Objectives:
        1. Ever think you wanted to simultaneously perform numerical and symbolic mathematics for an engineering or optimization derivation? Now you can pretty much intuitively derivate simultaneously whilst performing unit management automatically.
        2. Integrate mathematical analytical derivation Python toolchains into a single handy one that retains and expands each of the constituent packages methods. Retain intuitive compatibility.
        3. Have fun!
        
        ## Quick Start
        
        Download the [Anaconda distribution first](https://www.anaconda.com/).
        
        Pip install:
        ```bash
        $ pip install numpsy
        ```
        
        Local install for most recent version:
        ```bash
        $ git clone https://github.com/daquintero/numpsy.git
        $ cd numpsy
        $ python3 setup.py install
        ```
        
        ## Quick Example
        See the [10 minutes to NumpSy jupyter notebook](https://github.com/daquintero/numpsy/blob/master/docs/ten_minutes_to_numpsy/10_minutes_to_numpsy.ipynb) for much more.
        
        ```py
        >>> import numpsy as nsy
        ```
        
        #### Create a unit and operate with it
        ```py
        >>> farad_unit = nsy.Unit(name="Farad", symbol="F")
        >>> farad_unit
        <Unit name:"Farad" symbol:"F" symbolic_expression:"">
        >>> farad_per_meter = farad_unit / nsy.Unit("meter", "m")
        >>> farad_per_meter
        <Unit name:"(Farad_by_meter)" symbol:"" symbolic_expression:"F/m">
        >>> farad_per_meter.symbolic_expression
        F/m
        ```
        
        #### Create a constant
        ```py
        >>> e_0 = nsy.Constant(
            name="permittivity_vaccum",
            symbol= "\epsilon_0",
            numerical=8.8541878128e-12,
            unit=farad_per_meter)
        >>> e_0
        <Constant name:"permittivity_vaccum" symbol:"\epsilon_0" symbolic_expression:"None" numerical:"8.8541878128e-12" unit:"<Unit name:"(Farad_by_meter)" symbol:"" symbolic_expression:"F/m">">
        >>> e_0.numerical
        8.8541878128e-12
        ```
        
        #### Create a variable
        ```py
        >> capacitor_plate_separation = nsy.Variable(
        ...     name="capacitor_plate_separation",
        ...     symbol= "d",
        ...     numerical=None,
        ...     unit=nsy.u.meter
        ... )
        >>> capacitor_plate_separation
        <Variable name:"capacitor_plate_separation" symbol:"d" symbolic_expression:"None" numerical:"None" unit:"<Unit name:"Meter" symbol:"m" symbolic_expression:"">">
        
        >>> car_speed = nsy.Variable(
            name="car_speed",
            symbol= "c",
            numerical=20,
            unit= nsy.Unit("meter", "m") / nsy.Unit("second", "s") )
        >>> time_to_arrive = roadtrip_distance / car_speed
        >>> time_to_arrive.n
        5.0
        ```
        
        
        ### Is it any good?
        I think it's an elegant mathematical representation to simultanously perform symbolic, numerical, and data science operations into a single system.
        
        ### Future plans
        * Extend unit management and verification.
        * Create a full constants list, probably even in Excel or as an importable CSV file into Pandas.
        
        Open to contributions.
        
Platform: UNKNOWN
Classifier: Programming Language :: Python :: 3
Classifier: License :: OSI Approved :: MIT License
Classifier: Operating System :: OS Independent
Requires-Python: >=3.6
Description-Content-Type: text/markdown
