Quantum Neural Machine Learning - Backpropagation and Dynamics
Abstract
Quantum artificial neural networks operate in two stages—learning and backpropagation—functioning as self-programming quantum computing systems that select quantum circuits for problem-solving while adapting through recurrent architectures and dynamic regimes.
The current work addresses quantum machine learning in the context of Quantum Artificial Neural Networks such that the networks' processing is divided in two stages: the learning stage, where the network converges to a specific quantum circuit, and the backpropagation stage where the network effectively works as a self-programing quantum computing system that selects the quantum circuits to solve computing problems. The results are extended to general architectures including recurrent networks that interact with an environment, coupling with it in the neural links' activation order, and self-organizing in a dynamical regime that intermixes patterns of dynamical stochasticity and persistent quasiperiodic dynamics, making emerge a form of noise resilient dynamical record.
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