The PennyLane-AQT plugin provides the ability to use Alpine Quantum Technologies' ion-trap quantum computing backends with PennyLane.
PennyLane provides open-source tools for quantum machine learning, quantum computing, quantum chemistry, and hybrid quantum-classical computing.
Alpine Quantum Technologies is an ion-trap quantum computing company offering access to quantum computing devices over the cloud.
The plugin documentation can be found here: PennyLane-AQT.
- Provides two devices which can be used with AQT's online API:
"aqt.sim"
and"aqt.noisy_sim"
. These provide access to an ideal ion-trap simulator and a noisy ion-trap simulator, respectively. - The plugin provides additional support for the AQT's custom rotation and Mølmer-Sørenson-type gates.
- Supports core PennyLane operations such as qubit rotations, Hadamard, basis state preparations, etc.
PennyLane-AQT requires Python >= 3.10. If you currently do not have Python 3 installed, we recommend Anaconda for Python 3, a distributed version of Python packaged for scientific computation. If you are using Python 3.12, ensure setuptools is up to date prior to installation:
$ python3 -m pip install --upgrade setuptools
PennyLane-AQT only requires PennyLane for use, no additional external frameworks are needed.
The plugin can be installed via pip
:
$ python3 -m pip install pennylane-aqt
Alternatively, you can install PennyLane-AQT from the source code by navigating to the top directory and running
$ python3 setup.py install
To ensure that PennyLane-AQT is working correctly after installation, the test suite can be run by navigating to the source code folder and running
$ make test
To build the HTML documentation, go to the top-level directory and run
$ make docs
The documentation can then be found in the doc/_build/html/
directory.
Once PennyLane is installed, the provided AQT devices can be accessed straight
away in PennyLane. However, the user will need access credentials for the AQT platform in order to
use these remote devices. These credentials should be provided to PennyLane via a
configuration file or environment variable.
Specifically, the variable AQT_TOKEN
must contain a valid access key for AQT's online platform.
You can instantiate the AQT devices for PennyLane as follows:
import pennylane as qml
dev1 = qml.device('aqt.sim', wires=2)
dev2 = qml.device('aqt.noisy_sim', wires=2)
These devices can then be used just like other devices for the definition and evaluation of quantum circuits within PennyLane. For more details and ideas, see the PennyLane website and refer to the PennyLane documentation.
We welcome contributions—simply fork the PennyLane-AQT repository, and then make a pull request containing your contribution. All contributers to PennyLane-AQT will be listed as contributors on the releases.
We also encourage bug reports, suggestions for new features and enhancements, and even links to cool projects or applications built on PennyLane and AQT.
PennyLane-AQT is the work of many contributors.
If you are doing research using PennyLane, please cite our papers:
Ville Bergholm, Josh Izaac, Maria Schuld, Christian Gogolin, M. Sohaib Alam, Shahnawaz Ahmed, Juan Miguel Arrazola, Carsten Blank, Alain Delgado, Soran Jahangiri, Keri McKiernan, Johannes Jakob Meyer, Zeyue Niu, Antal Száva, Nathan Killoran. PennyLane: Automatic differentiation of hybrid quantum-classical computations. 2018. arXiv:1811.04968
Maria Schuld, Ville Bergholm, Christian Gogolin, Josh Izaac, and Nathan Killoran. Evaluating analytic gradients on quantum hardware. 2018. Phys. Rev. A 99, 032331
- Source Code: https://github.com/PennyLaneAI/pennylane-aqt
- Issue Tracker: https://github.com/PennyLaneAI/pennylane-aqt/issues
If you are having issues, please let us know by posting the issue on our GitHub issue tracker.
PennyLane-AQT is free and open source, released under the Apache License, Version 2.0.