Quantum AI and hybrid simulators for a Universal Quantum Field Computation Model

Quantum field theory (QFTh) simulators simulate physical systems using quantum circuits that process quantum information (qubits) via single field (SF) and/or quantum double field (QDF) transformation. This review presents models that classify states against pairwise particle states [Formula: see te...

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Autores principales: Alipour, Philip Baback, Gulliver, Thomas Aaron
Formato: Online Artículo Texto
Lenguaje:English
Publicado: Elsevier 2023
Materias:
Computer Science
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC10520359/
https://www.ncbi.nlm.nih.gov/pubmed/37767157
http://dx.doi.org/10.1016/j.mex.2023.102366
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author Alipour, Philip Baback
Gulliver, Thomas Aaron
author_facet Alipour, Philip Baback
Gulliver, Thomas Aaron
author_sort Alipour, Philip Baback
collection PubMed
description Quantum field theory (QFTh) simulators simulate physical systems using quantum circuits that process quantum information (qubits) via single field (SF) and/or quantum double field (QDF) transformation. This review presents models that classify states against pairwise particle states [Formula: see text] , given their state transition (ST) probability [Formula: see text]. A quantum AI (QAI) program, weighs and compares the field’s distance between entangled states as qubits from their scalar field of radius [Formula: see text]. These states distribute across [Formula: see text] with expected probability [Formula: see text] and measurement outcome [Formula: see text]. A quantum-classical hybrid model of processors via QAI, classifies and predicts states by decoding qubits into classical bits. For example, a QDF as a quantum field computation model (QFCM) in IBM-QE, performs the doubling of [Formula: see text] for a strong state prediction outcome. QFCMs are compared to achieve a universal QFCM (UQFCM). This model is novel in making strong event predictions by simulating systems on any scale using QAI. Its expected measurement fidelity is [Formula: see text] in classifying states to select 7 optimal QFCMs to predict [Formula: see text] ’s on QFTh observables. This includes QFCMs’ commonality of [Formula: see text] against QFCMs limitations in predicting system events. Common measurement results of QFCMs include their expected success probability [Formula: see text] over STs occurring in the system. Consistent results with high [Formula: see text] ’s, are averaged over STs as [Formula: see text] yielding [Formula: see text] performed by an SF or QDF of certain QFCMs. A combination of QFCMs with this fidelity level predicts error rates (uncertainties) in measurements, by which a [Formula: see text] is weighed as a QAI output to a QFCM user. The user then decides which QFCMs perform a more efficient system simulation as a reliable solution. A UQFCM is useful in predicting system states by preserving and recovering information for intelligent decision support systems in applied, physical, legal and decision sciences, including industry 4.0 systems.
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spelling pubmed-105203592023-09-27 Quantum AI and hybrid simulators for a Universal Quantum Field Computation Model Alipour, Philip Baback Gulliver, Thomas Aaron MethodsX Computer Science Quantum field theory (QFTh) simulators simulate physical systems using quantum circuits that process quantum information (qubits) via single field (SF) and/or quantum double field (QDF) transformation. This review presents models that classify states against pairwise particle states [Formula: see text] , given their state transition (ST) probability [Formula: see text]. A quantum AI (QAI) program, weighs and compares the field’s distance between entangled states as qubits from their scalar field of radius [Formula: see text]. These states distribute across [Formula: see text] with expected probability [Formula: see text] and measurement outcome [Formula: see text]. A quantum-classical hybrid model of processors via QAI, classifies and predicts states by decoding qubits into classical bits. For example, a QDF as a quantum field computation model (QFCM) in IBM-QE, performs the doubling of [Formula: see text] for a strong state prediction outcome. QFCMs are compared to achieve a universal QFCM (UQFCM). This model is novel in making strong event predictions by simulating systems on any scale using QAI. Its expected measurement fidelity is [Formula: see text] in classifying states to select 7 optimal QFCMs to predict [Formula: see text] ’s on QFTh observables. This includes QFCMs’ commonality of [Formula: see text] against QFCMs limitations in predicting system events. Common measurement results of QFCMs include their expected success probability [Formula: see text] over STs occurring in the system. Consistent results with high [Formula: see text] ’s, are averaged over STs as [Formula: see text] yielding [Formula: see text] performed by an SF or QDF of certain QFCMs. A combination of QFCMs with this fidelity level predicts error rates (uncertainties) in measurements, by which a [Formula: see text] is weighed as a QAI output to a QFCM user. The user then decides which QFCMs perform a more efficient system simulation as a reliable solution. A UQFCM is useful in predicting system states by preserving and recovering information for intelligent decision support systems in applied, physical, legal and decision sciences, including industry 4.0 systems. Elsevier 2023-09-14 /pmc/articles/PMC10520359/ /pubmed/37767157 http://dx.doi.org/10.1016/j.mex.2023.102366 Text en © 2023 The Author(s) https://creativecommons.org/licenses/by-nc-nd/4.0/This is an open access article under the CC BY-NC-ND license (http://creativecommons.org/licenses/by-nc-nd/4.0/).
spellingShingle Computer Science
Alipour, Philip Baback
Gulliver, Thomas Aaron
Quantum AI and hybrid simulators for a Universal Quantum Field Computation Model
title Quantum AI and hybrid simulators for a Universal Quantum Field Computation Model
title_full Quantum AI and hybrid simulators for a Universal Quantum Field Computation Model
title_fullStr Quantum AI and hybrid simulators for a Universal Quantum Field Computation Model
title_full_unstemmed Quantum AI and hybrid simulators for a Universal Quantum Field Computation Model
title_short Quantum AI and hybrid simulators for a Universal Quantum Field Computation Model
title_sort quantum ai and hybrid simulators for a universal quantum field computation model
topic Computer Science
url https://www.ncbi.nlm.nih.gov/pmc/articles/PMC10520359/
https://www.ncbi.nlm.nih.gov/pubmed/37767157
http://dx.doi.org/10.1016/j.mex.2023.102366
work_keys_str_mv AT alipourphilipbaback quantumaiandhybridsimulatorsforauniversalquantumfieldcomputationmodel
AT gulliverthomasaaron quantumaiandhybridsimulatorsforauniversalquantumfieldcomputationmodel

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