Python tools for supervised learning by Quantum Neural Networks.
You can install Quantum Edward from the Python package manager
pip install qedward --user
Quantum Edward at this point is just a small library of Python tools for doing classical supervised learning on Quantum Neural Networks (QNNs).
An analytical model of the QNN is entered as input into QEdward and the training is done on a classical computer, using training data already available (e.g., MNIST), and using the famous BBVI (Black Box Variational Inference) method described in Reference 1 below.
The input analytical model of the QNN is given as a sequence of gate operations for a gate model quantum computer. The hidden variables are angles by which the qubits are rotated. The observed variables are the input and output of the quantum circuit. Since it is already expressed in the qc's native language, once the QNN has been trained using QEdward, it can be run immediately on a physical gate model qc such as the ones that IBM and Google have already built. By running the QNN on a qc and doing classification with it, we can compare the performance in classification tasks of QNNs and classical artificial neural nets (ANNs).
Other workers have proposed training a QNN on an actual physical qc. But current qc's are still fairly quantum noisy. Training an analytical QNN on a classical computer might yield better results than training it on a qc because in the first strategy, the qc's quantum noise does not degrade the training.
The BBVI method is a mainstay of the "Edward" software library. Edward uses Google's TensorFlow lib to implement various inference methods (Monte Carlo and Variational ones) for Classical Bayesian Networks and for Hierarchical Models. H.M.s (pioneered by Andrew Gelman) are a subset of C.B. nets (pioneered by Judea Pearl). Edward is now officially a part of TensorFlow, and the original author of Edward, Dustin Tran, now works for Google. Before Edward came along, TensorFlow could only do networks with deterministic nodes. With the addition of Edward, TensorFlow now can do nets with both deterministic and non-deterministic (probabilistic) nodes.
This first baby-step lib does not do distributed computing. The hope is that it can be used as a kindergarten to learn about these techniques, and that then the lessons learned can be used to write a library that does the same thing, classical supervised learning on QNNs, but in a distributed fashion using Edward/TensorFlow on the cloud.
The first version of Quantum Edward analyzes two QNN models called NbTrols and NoNbTrols. These two models were chosen because they are interesting to the author, but the author attempted to make the library general enough so that it can accommodate other akin models in the future. The allowable models are referred to as QNNs because they consist of 'layers', as do classical ANNs (Artificial Neural Nets). TensorFlow can analyze layered models (e.g., ANN) or more general DAG (directed acyclic graph) models (e.g., Bayesian networks).
This software is distributed under the MIT License.
R. Ranganath, S. Gerrish, D. M. Blei, "Black Box Variational Inference", https://arxiv.org/abs/1401.0118
https://en.wikipedia.org/wiki/Stochastic_approximation discusses Robbins-Monro conditions
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