Skip to content

This repository contains the code to reproduce the results in the paper A Variational algorithm for Quantum Neural Networks, accepted in the International Conference on Computational Science 2020, Quantum Computing track.

License

Notifications You must be signed in to change notification settings

amacaluso/Quantum-Single-Layer-Perceptron

Repository files navigation

qSLP: A Variational Algorithm for Quantum Neural Networks

This repository contains the code to reproduce the results in the paper A Variational algorithm for Quantum Neural Networks, published in the International Conference on Computational Science 2020, Quantum Computing track.

Description

We introduce a novel variational algorithm for quantum Single Layer Perceptron. In particular, we design a quantum circuit to perform linear combinations in superposition and discuss adaptations to classification tasks. After this theoretical investigation, we also provide practical implementations using various simulation environments. Finally, we test the proposed algorithm on synthetic data exploiting both simulators and real quantum devices.

Quantum Circuit

Intuitively, a qSLP can be implemented into a quantum computer in two steps. Firstly, we generate different linear operations in superposition, each one having different parameters , entangled with a control register. Secondly, we propagate the activation function to all the linear combinations in superposition. To this end, three quantum registers are necessary: control, data and temp. The latter is responsible for generating the linear combinations of the input data in superposition.

The circuit above leads to the following quantum state:

where the two linear operations, , are put through the same activation function, , represented by the gate . Each output is weighed by the parameters of the control qubit , i.e. the coefficients attached to the hidden neurons in the linear combination that produces the output of the NN. This is exactly the quantum version of the two-neurons classical SLP.

Thus, the quantum circuit described above allows reproducing a classical Neural Network with one hidden layer on a quantum computer.

Usage

The code implements all the experiments regarding the implementation of the quantum Single Layer Perceptron using two frameworks for quantum computation: the qml_ scripts use pennylane and reproduce the experiments reported in the paper. The qiskit_ scripts use Qiskit and allow to visualize easily the quantum circuit. The qSLP works well in both cases, this strengthens the validity of the model which is independent from the implementation.

Pennylane implementation:

  • The script qml_qSLP.py contains the code for generating data and training a single classifier.

  • The script qml_multiple_runs.py generates many dataset from two bivariate gaussian distributions with different standard deviations and trains the classifier for each of them.

  • The script qml-qiskit_real_device.py executes the trained algorithm on real device, using a specific plug-in that allows to run the circuit using qiskit environment.

  • The script qml_Utils.py contains the import of the needed packages and all the custom routines for evaluation.

  • The script qml_visualization.py plots the data and the performances of the classifier.

  • The script qml_collect_results_rl.py collects the results generated by running the quantum algorithm in a real device.

Some of the functions for optimisation are taken from https://pennylane.ai/qml/demos/tutorial_variational_classifier.html

Qiskit implementation:

  • The script qiskit_qSLP.py contains the code for generating data and training a single classifier. Also it allows to visualise the two-layer qSLP.

  • The script qiskit_Utils.py contains the import of the needed packages and all the custom routines for evaluation.

Issues

For any issues or questions related to the code, open a new git issue or send a mail to antonio.macaluso@dfki.de

About

This repository contains the code to reproduce the results in the paper A Variational algorithm for Quantum Neural Networks, accepted in the International Conference on Computational Science 2020, Quantum Computing track.

Topics

Resources

License

Stars

Watchers

Forks

Releases

No releases published

Packages

No packages published

Languages