PRINCIPLES OF QUANTUM MECHANICS IN ACCESS CONTROL SYSTEMS WITH TIME PARAMETERS
Authors:
1.
Astrakhan Tatishchev State University
(Student, training area «Information Systems and Technologies»)
Russian Federation
Russian Federation
2.
Astrakhan Tatishchev State University
(Senior Lecturer of the Department of Informational Technologies)
Russian Federation
Russian Federation
Type:
Article
Pages:
from 137
to 141
Status:
Published
Received:
31.01.2026
Accepted:
31.01.2026
Published:
31.01.2026
Language:
Russian
Keywords:
ACCESS CONTROL AND MANAGEMENT SYSTEMS (ACS), TIME PASSES, QUANTUM MECHANICS, VON NEUMANN REDUCTION, QUANTUM SUPERPOSITION, DECOHERENCE, ANTI-CLONING THEOREM, QUANTUM AUTHENTICATION, CYBERSECURITY
Abstract:
The article explores an innovative methodology for applying the principles of quantum mechanics to create a new generation of access control systems with dynamic time parameters. The relevance of the work is due to the growing threats to security in the digital environment in the context of the proliferation of cloud services, the Internet of things and mobile technologies, which are radically changing the traditional perimeter of protection. A quantum approach based on fundamental physical principles rather than computational complexity of algorithms is proposed as a promising and secure solution. The key concepts of quantum mechanics are considered in detail: superposition of access states, quantum entanglement and the decoherence process, which make it possible to create dynamic control of time parameters of gaps. Special attention is paid to the theoretical foundations of the proposed quantum solution. A complex mathematical model describing the state of passing through a wave function is presented. The phenomenon of wave function collapse during verification at the time of authentication is analyzed in detail, which ensures the fundamental uncertainty of the verification procedure. The paper highlights important practical aspects of the system's implementation, including scenarios for instant pass blocking, dynamic reconfiguration of access rights, and collective authentication based on quantum entanglement. Of particular interest are the considered mechanisms of non-local synchronization of states and the creation of "blurred" time boundaries of access. The key advantages of the approach are analyzed, including absolute copy protection due to the anti-cloning theorem and the fundamental impossibility of unauthorized prediction of the pass status. The research represents a paradigm shift in the field of security and opens up new prospects for the creation of fundamentally new "non-breakable" access control systems, the security of which is directly guaranteed by the laws of quantum physics.
The article explores an innovative methodology for applying the principles of quantum mechanics to create a new generation of access control systems with dynamic time parameters. The relevance of the work is due to the growing threats to security in the digital environment in the context of the proliferation of cloud services, the Internet of things and mobile technologies, which are radically changing the traditional perimeter of protection. A quantum approach based on fundamental physical principles rather than computational complexity of algorithms is proposed as a promising and secure solution. The key concepts of quantum mechanics are considered in detail: superposition of access states, quantum entanglement and the decoherence process, which make it possible to create dynamic control of time parameters of gaps. Special attention is paid to the theoretical foundations of the proposed quantum solution. A complex mathematical model describing the state of passing through a wave function is presented. The phenomenon of wave function collapse during verification at the time of authentication is analyzed in detail, which ensures the fundamental uncertainty of the verification procedure. The paper highlights important practical aspects of the system's implementation, including scenarios for instant pass blocking, dynamic reconfiguration of access rights, and collective authentication based on quantum entanglement. Of particular interest are the considered mechanisms of non-local synchronization of states and the creation of "blurred" time boundaries of access. The key advantages of the approach are analyzed, including absolute copy protection due to the anti-cloning theorem and the fundamental impossibility of unauthorized prediction of the pass status. The research represents a paradigm shift in the field of security and opens up new prospects for the creation of fundamentally new "non-breakable" access control systems, the security of which is directly guaranteed by the laws of quantum physics.
Keywords:
ACCESS CONTROL AND MANAGEMENT SYSTEMS (ACS), TIME PASSES, QUANTUM MECHANICS, VON NEUMANN REDUCTION, QUANTUM SUPERPOSITION, DECOHERENCE, ANTI-CLONING THEOREM, QUANTUM AUTHENTICATION, CYBERSECURITY
ACCESS CONTROL AND MANAGEMENT SYSTEMS (ACS), TIME PASSES, QUANTUM MECHANICS, VON NEUMANN REDUCTION, QUANTUM SUPERPOSITION, DECOHERENCE, ANTI-CLONING THEOREM, QUANTUM AUTHENTICATION, CYBERSECURITY
