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Main Authors: Mayorga, Alejandro Antonio, Yuan, Alexander, Yuan, Andrew, Wooldridge, Tyler, Wang, Xiaodi
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2408.15462
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author Mayorga, Alejandro Antonio
Yuan, Alexander
Yuan, Andrew
Wooldridge, Tyler
Wang, Xiaodi
author_facet Mayorga, Alejandro Antonio
Yuan, Alexander
Yuan, Andrew
Wooldridge, Tyler
Wang, Xiaodi
contents Neural networks have continued to gain prevalence in the modern era for their ability to model complex data through pattern recognition and behavior remodeling. However, the static construction of traditional neural networks inhibits dynamic intelligence. This makes them inflexible to temporal changes in data and unfit to capture complex dependencies. With the advent of quantum technology, there has been significant progress in creating quantum algorithms. In recent years, researchers have developed quantum neural networks that leverage the capabilities of qubits to outperform classical networks. However, their current formulation exhibits a static construction limiting the system's dynamic intelligence. To address these weaknesses, we develop a Liquid Quantum Neural Network (LQNet) and a Continuous Time Recurrent Quantum Neural Network (CTRQNet). Both models demonstrate a significant improvement in accuracy compared to existing quantum neural networks (QNNs), achieving accuracy increases as high as 40\% on CIFAR 10 through binary classification. We propose LQNets and CTRQNets might shine a light on quantum machine learning's black box.
format Preprint
id arxiv_https___arxiv_org_abs_2408_15462
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle CTRQNets & LQNets: Continuous Time Recurrent and Liquid Quantum Neural Networks
Mayorga, Alejandro Antonio
Yuan, Alexander
Yuan, Andrew
Wooldridge, Tyler
Wang, Xiaodi
Quantum Physics
Artificial Intelligence
Machine Learning
Neural and Evolutionary Computing
Neural networks have continued to gain prevalence in the modern era for their ability to model complex data through pattern recognition and behavior remodeling. However, the static construction of traditional neural networks inhibits dynamic intelligence. This makes them inflexible to temporal changes in data and unfit to capture complex dependencies. With the advent of quantum technology, there has been significant progress in creating quantum algorithms. In recent years, researchers have developed quantum neural networks that leverage the capabilities of qubits to outperform classical networks. However, their current formulation exhibits a static construction limiting the system's dynamic intelligence. To address these weaknesses, we develop a Liquid Quantum Neural Network (LQNet) and a Continuous Time Recurrent Quantum Neural Network (CTRQNet). Both models demonstrate a significant improvement in accuracy compared to existing quantum neural networks (QNNs), achieving accuracy increases as high as 40\% on CIFAR 10 through binary classification. We propose LQNets and CTRQNets might shine a light on quantum machine learning's black box.
title CTRQNets & LQNets: Continuous Time Recurrent and Liquid Quantum Neural Networks
topic Quantum Physics
Artificial Intelligence
Machine Learning
Neural and Evolutionary Computing
url https://arxiv.org/abs/2408.15462