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Journal of Quantum Information Science 2024

Bridging Classical and Quantum Realms: The Conceptual and Theoretical Framework of the Advanced Observer Model

DOI: 10.4236/jqis.2024.144007, PP. 123-157

Joseph H. C. Wong

Keywords: Advanced Observer Model, AOM, Determinacy, Indeterminacy, Reverse Engineering, Observer-Observed Interaction, Quantum Wave Function, Probability Density Function, PDF, Probability Space, Potential Space, Quantum Computing, Quantum Information Processing, Static Configuration, SC, Dynamic Configuration, DC, Sequence of Quantum States, SQS, Perceptual Sequence of Observations, PSO, Theory of Relativity, Lorentz Transformation

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Abstract:

This paper presents the Advanced Observer Model (AOM), a groundbreaking conceptual framework designed to clarify the complex and often enigmatic nature of quantum mechanics. The AOM serves as a metaphorical lens, bringing the elusive quantum realm into sharper focus by transforming its inherent uncertainty into a coherent, structured ‘Frame Stream’ that aids in the understanding of quantum phenomena. While the AOM offers conceptual simplicity and clarity, it recognizes the necessity of a rigorous theoretical foundation to address the fundamental uncertainties that lie at the core of quantum mechanics. This paper seeks to illuminate those theoretical ambiguities, bridging the gap between the abstract insights of the AOM and the intricate mathematical foundations of quantum theory. By integrating the conceptual clarity of the AOM with the theoretical intricacies of quantum mechanics, this work aspires to deepen our understanding of this fascinating and elusive field.

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