Metadata-Version: 2.1
Name: py-polar-codes
Version: 1.2.1
Summary: A package for polar codes in Python.
Home-page: https://github.com/mcba1n/polar-codes
Author: Brendon McBain
Author-email: brendon.mcbain9@gmail.com
License: UNKNOWN
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
Requires-Dist: numpy
Requires-Dist: matplotlib

# Polar Codes in Python

A library written in Python3 for Polar Codes, a capacity-achieving channel coding technique used in 5G. The library includes functions for construction, encoding, decoding, and simulation of polar codes. In addition, it supports puncturing and shortening.

It provides:
 - a systematic and non-systemic encoder.
 - non-recursive implementations of the successive cancellation decoder (SCD).
 - mothercode construction of polar codes using Bhattacharyya Bounds or Gaussian Approximation
 - support for puncturing and shortening.
 - Bit-Reversal Shortening (BRS), Wang-Liu Shortening (WLS), and Bioglio-Gabry-Land (BGL) shortening constructions.
 - an AWGN channel with BPSK modulation.
 - an easy-to-use Graphical User Interface (GUI)

Documentation:
 - [Main reference (pdf)](https://github.com/mcba1n/polar-codes/blob/master/main_reference_v1.0.pdf)
 - [Quick reference (website)](https://mcba1n.github.io/polar-codes-docs/)
 - Introduction to polar codes, shortening, and the library: http://www.youtube.com/watch?v=v47rn77RAxM

## Getting Started

1. Install the package with `pip install py-polar-codes` from https://pypi.org/project/py-polar-codes/.
2. Install matplotlib from https://matplotlib.org/users/installing.html.
3. Install numpy from https://docs.scipy.org/doc/numpy/user/install.html.
4. Run test.py using a Python3 compiler. If the program runs successfully, the library is ready to use. Make sure the compiler has writing access to directory "root/data", where simulation data will be saved by default.
5. Call `GUI()` to start the GUI.

## Examples
### Mothercode Encoding & Decoding
An example of encoding and decoding over an AWGN channel for a (256,100) non-systematic mothercode, using Bhattacharyya Bounds for construction and SCD for decoding.
For systematic encoding and decoding, replace `Encode(myPC)` with `Encode(myPC, 'systematic_encode')` and `Decode(myPC)` with `Decode(myPC, 'systematic_scd')`.

```python
   import numpy as np
   from polarcodes import *

    # initialise polar code
    myPC = PolarCode(256, 100)
    myPC.construction_type = 'bb'

    # mothercode construction
    design_SNR  = 5.0
    Construct(myPC, design_SNR)
    print(myPC, "\n\n")

    # set message
    my_message = np.random.randint(2, size=myPC.K)
    myPC.set_message(my_message)
    print("The message is:", my_message)

    # encode message
    Encode(myPC)
    print("The coded message is:", myPC.u)

    # transmit the codeword
    AWGN(myPC, design_SNR)
    print("The log-likelihoods are:", myPC.likelihoods)

    # decode the received codeword
    Decode(myPC)
    print("The decoded message is:", myPC.message_received)
```

### Shortened Code Construction
An example of constructing a shortened polar code with Bit-Reversal Shortening (BRS) algorithm.
The shortening parameters are set by the tuple `shorten_params`, the third argument of `PolarCode`, and is defined by:
- Puncturing type: `shorten` or `punct`.
- Puncturing algorithm: `brs`, `wls`, or `bgl`.
- Puncturing set (for manual puncturing): `List`
- Overcapable set (for manual puncturing): `List`
- Update reliabilities after puncturing (or use mothercode reliabilities): `True` or `False`.


```python
   import numpy as np
   from polarcodes import *

    # initialise shortened polar code
    shorten_params = ('shorten', 'brs', None, None, False)
    myPC = PolarCode(200, 100, shorten_params)

    # construction
    design_SNR  = 5.0
    Shorten(myPC, design_SNR)
    print(myPC, "\n\n")
```

### Simulation & Plotting
A script to simulate a defined polar code, save the data to directory "/data", and then display the result in a *matplotlib* figure.

```python
    # simulate polar code 
    myPC.simulate(save_to='data/pc_sim', Eb_No_vec=np.arange(1,5), manual_const_flag=True)

    # plot the frame error rate
    myPC.plot(['pc_sim'], 'data/')
```

The simulation will save your PolarCode object in a JSON file, for example:
```JSON
{
    "N": 64,
    "n": 6,
    "K": 32,
    "frozen": [
        22, 38, 49, 26, 42, 3, 28, 50, 5,44,9, 52, 6, 17, 10, 33, 56, 18, 12, 34, 20, 36, 1, 24, 40, 48, 2, 4, 8, 16, 32, 0
    ],
    "construction_type": "bb",
    "punct_flag": false,
    "punct_type": "",
    "punct_set": [],
    "source_set": [],
    "punct_algorithm": "",
    "update_frozen_flag": [],
    "BER": [
        0.09709375, 0.03740625, 0.00815625, 0.0010184612211221122
    ],
    "FER": [
        0.313, 0.126, 0.03,0.004125412541254125
    ],
    "SNR": [
        1, 2, 3, 4
    ]
}
```

### Graphical User Interface
An example of using the GUI to simulate and plot a specified polar code. Note: if "manual construction" is ticked, the user is required to input the frozen bits and the shortened bits.
<br/><img src="https://github.com/mcba1n/polar-codes/blob/master/gui_example.PNG" width="500">

*This is a final year project created by Brendon McBain under the supervision of Dr Harish Vangala at Monash University.*


