Skip to content

Python package for simulation and visualization of quantum error-correction on surface codes. The package provides the ability to inspect the error-correcting code during the decoding process, and tools to benchmark the decoder.

License

Notifications You must be signed in to change notification settings

watermarkhu/qsurface

Repository files navigation

Qsurface

PyPI version Build Documentation Status codecov Binder License DOI Unitary Fund

Qsurface is a simulation package for the surface code, and is designed to modularize 3 aspects of a surface code simulation.

  1. The surface code
  2. The error model
  3. The used decoder

New types of surface codes, error modules and decoders can be added to Qsurface by using the included templates for each of the three core module categories.

The current included decoders are:

  • The Mininum-Weight Perfect Matching (mwpm) decoder.
  • Delfosse's and Nickerson's Union-Find (unionfind) decoder, which has almost-linear worst-case time complexity.
  • Our modification to the Union-Find decoder; the Union-Find Node-Suspension (ufns) decoder, which improves the threshold of the Union-Find decoder to near MWPM performance, while retaining quasi-linear worst-case time complexity.

The compatibility of these decoders with the included surface codes are listed below.

Decoders toric code planar code
mwpm
unionfind
ufns

Installation

All required packages can be installed through:

pip install qsurface

Requirements

  • Python 3.7+
  • Tkinter or PyQt5 for interactive plotting.
  • Matplotlib 3.4+ for plotting on a 3D lattice (Refers to a future release of matplotlib, see pull request)

MWPM decoder

The MWPM decoder utilizes networkx for finding the minimal weights in a fully connected graph. This implementation is however rather slow compared to Kolmogorov's Blossom V algorithm. Blossom V has its own license and is thus not included with Qsurface. We do provided a single function to download and compile Blossom V, and to setup the integration with Qsurface automatically.

>>> from qsurface.decoders import mwpm
>>> mwpm.get_blossomv()

Usage

To simulate the toric code and simulate with bitflip error for 10 iterations and decode with the MWPM decoder:

>>> from qsurface.main import initialize, run
>>> code, decoder = initialize((6,6), "toric", "mwpm", enabled_errors=["pauli"])
>>> run(code, decoder, iterations=10, error_rates = {"p_bitflip": 0.1})
{'no_error': 8}

Benchmarking of decoders can be enabled by attaching a benchmarker object to the decoder. See the docs for the syntax and information to setup benchmarking.

>>> from qsurface.main import initialize, run
>>> benchmarker = BenchmarkDecoder({"decode":"duration"})
>>> run(code, decoder, iterations=10, error_rates = {"p_bitflip": 0.1}, benchmark=benchmarker)
{'no_error': 8,
'benchmark': {'success_rate': [10, 10],
'seed': 12447.413636559,
'durations': {'decode': {'mean': 0.00244155000000319,
'std': 0.002170364089572033}}}}

Plotting

The figures in Qsurface allows for step-by-step visualization of the surface code simulation (and if supported the decoding process). Each figure logs its history such that the user can move backwards in time to view past states of the surface (and decoder). Press h when the figure is open for more information.

>>> from qsurface.main import initialize, run
>>> code, decoder = initialize((6,6), "toric", "mwpm", enabled_errors=["pauli"], plotting=True, initial_states=(0,0))
>>> run(code, decoder, error_rates = {"p_bitflip": 0.1, "p_phaseflip": 0.1}, decode_initial=False)

Interactive plotting on a 6x6 toric code.

Plotting will be performed on a 3D axis if faulty measurements are enabled.

>>> code, decoder = initialize((3,3), "toric", "mwpm", enabled_errors=["pauli"], faulty_measurements=True, plotting=True, initial_states=(0,0))
>>> run(code, decoder, error_rates = {"p_bitflip": 0.05, "p_bitflip_plaq": 0.05}, decode_initial=False)

Interactive plotting on a toric code with faulty measurements.

In IPython, inline images are created for each iteration of the plot, which can be tested in the example notebook.

Command line interface

Simulations can also be initiated from the command line

$ python -m qsurface -e pauli -D mwpm -C toric simulation --p_bitflip 0.1 -n 10
{'no_error': 8}

For more information on command line interface:

$ python -m qsurface -h
usage: qsurface
...

This project is proudly funded by the Unitary Fund.

About

Python package for simulation and visualization of quantum error-correction on surface codes. The package provides the ability to inspect the error-correcting code during the decoding process, and tools to benchmark the decoder.

Topics

Resources

License

Stars

Watchers

Forks

Packages

No packages published