Nonlinear Dynamical Systems and Quantum-Entropy theory in Psychology and Medicine

Mohammad Ebrahimi; Vera Ivanovna Nesterova

doi:10.33700/jhrs.3.2.123

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Open Access

Authors

Mohammad Ebrahimi The Research Center for New Technologies in Life Science Engineering, Institute of Bio-signal and Immunculus, Tehran University, Tehran, Iran https://orcid.org/0000-0002-7537-8265
Vera Ivanovna Nesterova he Institute of Practical Psychophysics, 2, 1st Proizvodstvennaya street, 644001 Omsk, Russia https://orcid.org/0000-0002-7537-8265

https://doi.org/10.33700/jhrs.3.2.123

Keywords:

Nonlinear dynamical systems, Psychology, Brainwave entrainment, Quantum-Entropy theory, Metatron bio feed-back system.

Abstract

Introduction: Nonlinear dynamical systems (NDS) have proven to be valuable tools in various disciplines, such as psychology, medicine, and biology, where they offer insights into complex, non-linear behaviors. These systems often complement the Theory of Quantum Entropy Logic (TQEL), a framework used to model complex systems and predict the behavior of biological systems. NDS and TQEL are particularly effective in understanding the underlying mechanisms of psychological disorders and optimizing medical treatment protocols.

Methodology: This article examines the application of NDS in psychology and medicine, focusing on key concepts such as attractors, bifurcations, chaos theory, fractals, and self-organization. These concepts are utilized to explain complex psychological phenomena, including human behavior, emotions, and cognition. Additionally, the article explores the role of brainwave entrainment and Quantum-Entropy theory in influencing specific cognitive and consciousness states.

Results: The integration of NDS with psychological and medical research has led to novel insights into human behavior and the mechanisms underlying psychological disorders. Concepts like attractors, bifurcations, and chaos theory have been used to model human emotions, cognition, and mental states. The application of brainwave entrainment and Quantum-Entropy theory has demonstrated the potential for inducing specific cognitive states, which could have therapeutic applications.

Conclusion: Nonlinear dynamical systems, in conjunction with quantum-entropy theory, offer a promising framework for advancing the understanding of human psychology and medicine. By elucidating the complex behaviors of the mind and body, these systems provide new opportunities for developing diagnostic tools, therapeutic interventions, and personalized medicine.

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