Decoherence is a sort of leaking away of quantum behavior when a particle interacts with its surroundings. Decoherence offers a way to understand classicality as emergent from within the quantum formalism, and the classical world no longer sits in opposition to quantum mechanics, but is demanded by it. The decoherence description shows that there is no abrupt boundary, no critical size, at which quantum behavior switches to classical. And the blurry boundary itself shifts depending on how it is measured. It is the choice of the measuring apparatus that defines whether a specific object can be represented by a quantum or classical model. Nowadays unfortunately, even the most sophisticated instrumentation system is completely unable to reliably discriminate so called "random noise" (RN) from any combinatorically optimized encoded message, called Deterministic Noise (DN). Mankind’s best conceivable worldview is at most a partial picture of the real world, a picture, a representation centered on man. Clearly, the observer, having incomplete information about the real underlying generating process, and no reliable theory about what the data correspond to, will always make mistakes, but these mistakes have a certain pattern. Unfortunately, the "probabilistic veil" can be very opaque computationally, and misplaced precision leads to confusion. To grasp a more reliable representation of reality and to get stronger physical and biological system correlates, researchers and scientists need two intelligently articulated hands: both stochastic and combinatorial approach synergistically articulated by natural coupling. The first attempt to identify basic principles to get stronger physical and biological measurement and correlates from experiment has been developing at Politecnico di Milano since the end of last century. In 2013, the basic principles on computational information conservation theory (CICT), from discrete system parameter and generator, appeared in literature. In this paper, our goal is to show that CICT can offer stronger quantum decoherence incomputability modeling relations than by modern statistical approach only. An example is presented. Specifically, advanced mathematical modeling, advanced wellbeing applications (AWA), high reliability organization (HRO), mission critical project (MCP) system, very low technological risk (VLTR) and crisis management (CM) system will be highly benefited mostly.

Stronger Physical and Biological Measurement Strategy for Biomedical and Wellbeing Application by CICT

FIORINI, RODOLFO
2014-01-01

Abstract

Decoherence is a sort of leaking away of quantum behavior when a particle interacts with its surroundings. Decoherence offers a way to understand classicality as emergent from within the quantum formalism, and the classical world no longer sits in opposition to quantum mechanics, but is demanded by it. The decoherence description shows that there is no abrupt boundary, no critical size, at which quantum behavior switches to classical. And the blurry boundary itself shifts depending on how it is measured. It is the choice of the measuring apparatus that defines whether a specific object can be represented by a quantum or classical model. Nowadays unfortunately, even the most sophisticated instrumentation system is completely unable to reliably discriminate so called "random noise" (RN) from any combinatorically optimized encoded message, called Deterministic Noise (DN). Mankind’s best conceivable worldview is at most a partial picture of the real world, a picture, a representation centered on man. Clearly, the observer, having incomplete information about the real underlying generating process, and no reliable theory about what the data correspond to, will always make mistakes, but these mistakes have a certain pattern. Unfortunately, the "probabilistic veil" can be very opaque computationally, and misplaced precision leads to confusion. To grasp a more reliable representation of reality and to get stronger physical and biological system correlates, researchers and scientists need two intelligently articulated hands: both stochastic and combinatorial approach synergistically articulated by natural coupling. The first attempt to identify basic principles to get stronger physical and biological measurement and correlates from experiment has been developing at Politecnico di Milano since the end of last century. In 2013, the basic principles on computational information conservation theory (CICT), from discrete system parameter and generator, appeared in literature. In this paper, our goal is to show that CICT can offer stronger quantum decoherence incomputability modeling relations than by modern statistical approach only. An example is presented. Specifically, advanced mathematical modeling, advanced wellbeing applications (AWA), high reliability organization (HRO), mission critical project (MCP) system, very low technological risk (VLTR) and crisis management (CM) system will be highly benefited mostly.
2014
Proceedings of the 15th International Conference on Automation and Information (ICAI 2014)
9781618042699
quantum-classical transition, decoherence, incomputability, combinatorial optimization, reversibility, quantum mechanics,entropy, statistical mechanics
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/11311/965065
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