Backpropagation training in adaptive quantum networks
Abstract
We introduce a robust, error-tolerant adaptive training algorithm for generalized learning paradigms in high-dimensional superposed quantum networks, or \emph{adaptive quantum networks}. The formalized procedure applies standard backpropagation training across a coherent ensemble of discrete topological configurations of individual neural networks, each of which is formally merged into appropriate linear superposition within a predefined, decoherence-free subspace. Quantum parallelism facilitates simultaneous training and revision of the system within this coherent state space, resulting in accelerated convergence to a stable network attractor under consequent iteration of the implemented backpropagation algorithm. Parallel evolution of linear superposed networks incorporating backpropagation training provides quantitative, numerical indications for optimization of both single-neuron activation functions and optimal reconfiguration of whole-network quantum structure.
Cite
@article{arxiv.0903.4416,
title = {Backpropagation training in adaptive quantum networks},
author = {Christopher Altman and Romàn R. Zapatrin},
journal= {arXiv preprint arXiv:0903.4416},
year = {2015}
}
Comments
Talk presented at "Quantum Structures - 2008", Gdansk, Poland