Quantum Entanglement of the Brain, Dynamics of Information, and Intelligent Finance
Journal: Financial Markets, Institutions and Risks (FMIR) (Vol.7, No. 3)Publication Date: 2023-09-30
Authors : Ana Njegovanović;
Page : 12-30
Keywords : classical mechanics; quantum physics; neuroscience; quantum geometric information; artificial intelligence/intelligent finance;
Abstract
Our research forms two directions, the first considers two approaches to the brain, one based on classical mechanics, the second using quantum physics, the second direction of research refers to the dynamics of0 information as an interaction between differential geometry, mathematical statistics, probability theory. and quantum mechanics which led to the construction of classical and quantum information geometry. Financial entanglement is multidimensiona in time and space, dynamic, less understood and interesting because it functions in real life, like the brain. Neuroscientists who focus on mathematical frameworks for how the brain's shape affects its activity—an area of mathematical neuroscience called neural field theory will begin to understand the relationship between brain shape, structure, and function in yet another way. Analysis of research into the geometry of the brain's contours, that is, the way in which brain activity resonates over and through its architecture, is perhaps more significant than the connections between neurons. Research by scientists from the University of Sydney and Monash University showed that the overall shape and geometry of the human brain - its contours and curvature - has a greater influence on brain dynamics than the internal connectivity of brain cells (Our brain shape influences how it works, 2023) in short, Australian scientists indicate the possibility of predicting brain function directly from its shape. "We have long thought that specific thoughts or sensations elicit activity in specific parts of the brain, but this study reveals that structured patterns of activity are excited across nearly the entire brain, just like the way in which a musical note arises from vibrations occurring along the entire length of a violin string, and not just an isolated segment," (Dr J. Pang,2023)."We found that eigenmodes defined by brain geometry - its contours and curvature - represented the strongest anatomical constraint on brain function, much like the shape of a drum influences the sounds it can make" (A. Fornito, 2023). "Using mathematical models, we confirmed theoretical predictions that the close link between geometry and function is driven by wave-like activity propagating throughout the brain, just as the shape of a pond influences the wave ripples that are formed by a falling pebble" (A. Fornito, 2023).
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Last modified: 2023-10-20 19:05:43