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06:44, 11 November 2022 Gianfranco talk contribs created page Store:EMde03 (Created page with "=== Sclerosi multipla e riflessi trigeminali === Dobbiamo fare un ulteriore attenzione premessa che riguarda la demilienizzazione assonale nelle sclerosi multiple. Da uno studio di Joanna Kamińska et el.<ref>Joanna Kamińska, Olga M Koper, Kinga Piechal, Halina Kemona . [https://pubmed.ncbi.nlm.nih.gov/28665284/ Multiple sclerosis - etiology and diagnostic potential].Postepy Hig Med Dosw. 2017 Jun 30;71(0):551-563.doi: 10.5604/01.3001.0010.3836. </ref> si evince che...")
06:44, 11 November 2022 Gianfranco talk contribs created page Store:EMfr03 (Created page with "=== Sclerosi multipla e riflessi trigeminali === Dobbiamo fare un ulteriore attenzione premessa che riguarda la demilienizzazione assonale nelle sclerosi multiple. Da uno studio di Joanna Kamińska et el.<ref>Joanna Kamińska, Olga M Koper, Kinga Piechal, Halina Kemona . [https://pubmed.ncbi.nlm.nih.gov/28665284/ Multiple sclerosis - etiology and diagnostic potential].Postepy Hig Med Dosw. 2017 Jun 30;71(0):551-563.doi: 10.5604/01.3001.0010.3836. </ref> si evince che...")
06:43, 11 November 2022 Gianfranco talk contribs created page Store:EMit03 (Created page with "=== Sclerosi multipla e riflessi trigeminali === Dobbiamo fare un ulteriore attenzione premessa che riguarda la demilienizzazione assonale nelle sclerosi multiple. Da uno studio di Joanna Kamińska et el.<ref>Joanna Kamińska, Olga M Koper, Kinga Piechal, Halina Kemona . [https://pubmed.ncbi.nlm.nih.gov/28665284/ Multiple sclerosis - etiology and diagnostic potential].Postepy Hig Med Dosw. 2017 Jun 30;71(0):551-563.doi: 10.5604/01.3001.0010.3836. </ref> si evince che...")
06:42, 11 November 2022 Gianfranco talk contribs created page File:Scwannoma.jpeg
06:42, 11 November 2022 Gianfranco talk contribs uploaded File:Scwannoma.jpeg
06:41, 11 November 2022 Gianfranco talk contribs created page Store:EMes02 (Created page with "=== Scwannoma vestibolare e trigeminale === Lo spasmo emifacciale secondario dovuto a schwannoma vestibolare è molto raro. U_no studio di S Peker et al.<ref>S Peker, K Ozduman, T Kiliç, M N Pamir. [https://pubmed.ncbi.nlm.nih.gov/15346321/ Relief of hemifacial spasm after radiosurgery for intracanalicular vestibular schwannoma.] Minim Invasive Neurosurg. 2004 Aug;47(4):235-7. doi: 10.1055/s-2004-818485. </ref> è stato il primo caso riportato di spasmo emifacciale re...")
06:40, 11 November 2022 Gianfranco talk contribs created page Store:EMde02 (Created page with "=== Scwannoma vestibolare e trigeminale === Lo spasmo emifacciale secondario dovuto a schwannoma vestibolare è molto raro. U_no studio di S Peker et al.<ref>S Peker, K Ozduman, T Kiliç, M N Pamir. [https://pubmed.ncbi.nlm.nih.gov/15346321/ Relief of hemifacial spasm after radiosurgery for intracanalicular vestibular schwannoma.] Minim Invasive Neurosurg. 2004 Aug;47(4):235-7. doi: 10.1055/s-2004-818485. </ref> è stato il primo caso riportato di spasmo emifacciale re...")
06:40, 11 November 2022 Gianfranco talk contribs created page Store:EMfr02 (Created page with "=== Scwannoma vestibolare e trigeminale === Lo spasmo emifacciale secondario dovuto a schwannoma vestibolare è molto raro. U_no studio di S Peker et al.<ref>S Peker, K Ozduman, T Kiliç, M N Pamir. [https://pubmed.ncbi.nlm.nih.gov/15346321/ Relief of hemifacial spasm after radiosurgery for intracanalicular vestibular schwannoma.] Minim Invasive Neurosurg. 2004 Aug;47(4):235-7. doi: 10.1055/s-2004-818485. </ref> è stato il primo caso riportato di spasmo emifacciale re...")
06:40, 11 November 2022 Gianfranco talk contribs created page Store:EMit02 (Created page with "=== Scwannoma vestibolare e trigeminale === Lo spasmo emifacciale secondario dovuto a schwannoma vestibolare è molto raro. U_no studio di S Peker et al.<ref>S Peker, K Ozduman, T Kiliç, M N Pamir. [https://pubmed.ncbi.nlm.nih.gov/15346321/ Relief of hemifacial spasm after radiosurgery for intracanalicular vestibular schwannoma.] Minim Invasive Neurosurg. 2004 Aug;47(4):235-7. doi: 10.1055/s-2004-818485. </ref> è stato il primo caso riportato di spasmo emifacciale re...")
06:38, 11 November 2022 Gianfranco talk contribs created page Store:EMes01 (Created page with "== Introduzione == Prima di entrare nel vivo della discussione riguardante la patologia della nostra paziente Mary Poppins quella che dai capitoli precedenti sembra di tipo neuromotriia ed in particolare un 'Spasmo emimasticatorio' dovremmo focalizzare alcuni punti selettivi che ci aiuteranno a comprendere l'importanza dello excursus dei capitoli precedenti per finire al determinante processo di decriptazione del segnale. Cominciamo con il dire che non è tanto comples...")
06:37, 11 November 2022 Gianfranco talk contribs created page Store:EMde01 (Created page with "== Introduzione == Prima di entrare nel vivo della discussione riguardante la patologia della nostra paziente Mary Poppins quella che dai capitoli precedenti sembra di tipo neuromotriia ed in particolare un 'Spasmo emimasticatorio' dovremmo focalizzare alcuni punti selettivi che ci aiuteranno a comprendere l'importanza dello excursus dei capitoli precedenti per finire al determinante processo di decriptazione del segnale. Cominciamo con il dire che non è tanto comples...")
06:37, 11 November 2022 Gianfranco talk contribs created page Store:EMfr01 (Created page with "== Introduzione == Prima di entrare nel vivo della discussione riguardante la patologia della nostra paziente Mary Poppins quella che dai capitoli precedenti sembra di tipo neuromotriia ed in particolare un 'Spasmo emimasticatorio' dovremmo focalizzare alcuni punti selettivi che ci aiuteranno a comprendere l'importanza dello excursus dei capitoli precedenti per finire al determinante processo di decriptazione del segnale. Cominciamo con il dire che non è tanto comples...")
06:35, 11 November 2022 Gianfranco talk contribs created page Store:EMit01 (Created page with "== Introduzione == Prima di entrare nel vivo della discussione riguardante la patologia della nostra paziente Mary Poppins quella che dai capitoli precedenti sembra di tipo neuromotriia ed in particolare un 'Spasmo emimasticatorio' dovremmo focalizzare alcuni punti selettivi che ci aiuteranno a comprendere l'importanza dello excursus dei capitoli precedenti per finire al determinante processo di decriptazione del segnale. Cominciamo con il dire che non è tanto comples...")
06:27, 11 November 2022 Gianfranco talk contribs created page Emimasticatory spasm - it (Created page with "{{transl|it}} left|200x200px Questo capitolo e la serie di sub capitoli saranno dedicati principalmente al caso clinico della nostra povera paziente Mary Poppins che ha dovuto aspettare ben 10 anni per avere una diagnosi certa e dettagliata di Spasmo Emimasticatorio trovandosi tra due fuochi quello del contesto odontoiatrico, e quello neurologico oltre tutte le altre branche della medicina incontrate nel percorso clinico tipo la derma...")
05:33, 10 November 2022 Gianfranco talk contribs created page Store:QLMfr09 (Created page with "==4. Quantum instruments from the scheme of indirect measurements== The basic model for construction of quantum instruments is based on the scheme of indirect measurements. This scheme formalizes the following situation: measurement’s outputs are generated via interaction of a system <math>S</math> with a measurement apparatus <math>M</math> . This apparatus consists of a complex physical device interacting with <math>S</math> and a pointer that shows the result of me...")
05:33, 10 November 2022 Gianfranco talk contribs created page Store:QLMfr04 (Created page with "==2. Classical versus quantum probability== CP was mathematically formalized by Kolmogorov (1933)<ref name=":2" /> This is the calculus of probability measures, where a non-negative weight <math>p(A)</math> is assigned to any event <math>A</math>. The main property of CP is its additivity: if two events <math>O_1, O_2</math> are disjoint, then the probability of disjunction of these events equals to the sum of probabilities: {| width="80%" | |- | width="33%" | ...")
05:30, 10 November 2022 Gianfranco talk contribs created page Quantum-like modeling in biology with open quantum systems and instruments - fr (Created page with "{{transl|en}} {{FR | Title = Quantum-like modeling in biology with open quantum systems and instruments | author1 = Irina Basieva | author2 = Andrei Khrennikov | author3 = Masanao Ozawa | Source = https://pubmed.ncbi.nlm.nih.gov/33347968/ | Original =  | Date = 2021<!-- date of the original work, when the author/s publish...")
05:28, 10 November 2022 Gianfranco talk contribs created page Quantum-like modeling in biology with open quantum systems and instruments - it (Created page with "{{transl|en}} {{FR | Title = Quantum-like modeling in biology with open quantum systems and instruments | author1 = Irina Basieva | author2 = Andrei Khrennikov | author3 = Masanao Ozawa | Source = https://pubmed.ncbi.nlm.nih.gov/33347968/ | Original =  | Date = 2021<!-- date of the original work, when the author/s publish...")
05:23, 10 November 2022 Gianfranco talk contribs created page Store:QLMes18 (Created page with "===11.3. Psychological functions=== Now, we turn to the model presented in Section 10. A neural network is modeled as a compound quantum system; its state is presented in tensor product of single-neuron state spaces. Brain’s functions perform self-measurements modeled within theory of open quantum systems. (There is no need to consider state’s collapse.) State’s dynamics of some brain’s function (psychological function) <math>F</math> is described by the quantum...")
05:23, 10 November 2022 Gianfranco talk contribs created page Store:QLMde18 (Created page with "===11.3. Psychological functions=== Now, we turn to the model presented in Section 10. A neural network is modeled as a compound quantum system; its state is presented in tensor product of single-neuron state spaces. Brain’s functions perform self-measurements modeled within theory of open quantum systems. (There is no need to consider state’s collapse.) State’s dynamics of some brain’s function (psychological function) <math>F</math> is described by the quantum...")
05:23, 10 November 2022 Gianfranco talk contribs moved page Store:QLMfr8 to Store:QLMfr18 without leaving a redirect
05:23, 10 November 2022 Gianfranco talk contribs created page Store:QLMfr8 (Created page with "===11.3. Psychological functions=== Now, we turn to the model presented in Section 10. A neural network is modeled as a compound quantum system; its state is presented in tensor product of single-neuron state spaces. Brain’s functions perform self-measurements modeled within theory of open quantum systems. (There is no need to consider state’s collapse.) State’s dynamics of some brain’s function (psychological function) <math>F</math> is described by the quantum...")
05:22, 10 November 2022 Gianfranco talk contribs created page Store:QLMit18 (Created page with "===11.3. Psychological functions=== Now, we turn to the model presented in Section 10. A neural network is modeled as a compound quantum system; its state is presented in tensor product of single-neuron state spaces. Brain’s functions perform self-measurements modeled within theory of open quantum systems. (There is no need to consider state’s collapse.) State’s dynamics of some brain’s function (psychological function) <math>F</math> is described by the quantum...")
05:22, 10 November 2022 Gianfranco talk contribs created page Store:QLMen18 (Created page with "===11.3. Psychological functions=== Now, we turn to the model presented in Section 10. A neural network is modeled as a compound quantum system; its state is presented in tensor product of single-neuron state spaces. Brain’s functions perform self-measurements modeled within theory of open quantum systems. (There is no need to consider state’s collapse.) State’s dynamics of some brain’s function (psychological function) <math>F</math> is described by the quantum...")
05:22, 10 November 2022 Gianfranco talk contribs created page Store:QLMes17 (Created page with "==11. Compound biosystems== ===11.1. Entanglement of information states of biosystems=== The state space <math>{\mathcal{H}}</math> of the biosystem <math>S</math> consisting of the subsystems <math>S_j,j=1,2,....n</math>, is the tensor product of subsystems’ state spaces<math>{\mathcal{H}}_j</math> , so {| width="80%" | |- | width="33%" |'''<big>*</big>''' | width="33%" |<math>\Im=\Im_1\otimes....\otimes\Im_n</math> | width="33%" align="right" |<math>(31)</math>...")
05:21, 10 November 2022 Gianfranco talk contribs created page Store:QLMde17 (Created page with "==11. Compound biosystems== ===11.1. Entanglement of information states of biosystems=== The state space <math>{\mathcal{H}}</math> of the biosystem <math>S</math> consisting of the subsystems <math>S_j,j=1,2,....n</math>, is the tensor product of subsystems’ state spaces<math>{\mathcal{H}}_j</math> , so {| width="80%" | |- | width="33%" |'''<big>*</big>''' | width="33%" |<math>\Im=\Im_1\otimes....\otimes\Im_n</math> | width="33%" align="right" |<math>(31)</math>...")
05:21, 10 November 2022 Gianfranco talk contribs created page Store:QLMfr17 (Created page with "==11. Compound biosystems== ===11.1. Entanglement of information states of biosystems=== The state space <math>{\mathcal{H}}</math> of the biosystem <math>S</math> consisting of the subsystems <math>S_j,j=1,2,....n</math>, is the tensor product of subsystems’ state spaces<math>{\mathcal{H}}_j</math> , so {| width="80%" | |- | width="33%" |'''<big>*</big>''' | width="33%" |<math>\Im=\Im_1\otimes....\otimes\Im_n</math> | width="33%" align="right" |<math>(31)</math>...")
05:21, 10 November 2022 Gianfranco talk contribs created page Store:QLMit17 (Created page with "==11. Compound biosystems== ===11.1. Entanglement of information states of biosystems=== The state space <math>{\mathcal{H}}</math> of the biosystem <math>S</math> consisting of the subsystems <math>S_j,j=1,2,....n</math>, is the tensor product of subsystems’ state spaces<math>{\mathcal{H}}_j</math> , so {| width="80%" | |- | width="33%" |'''<big>*</big>''' | width="33%" |<math>\Im=\Im_1\otimes....\otimes\Im_n</math> | width="33%" align="right" |<math>(31)</math>...")
05:21, 10 November 2022 Gianfranco talk contribs created page Store:QLMen17 (Created page with "==11. Compound biosystems== ===11.1. Entanglement of information states of biosystems=== The state space <math>{\mathcal{H}}</math> of the biosystem <math>S</math> consisting of the subsystems <math>S_j,j=1,2,....n</math>, is the tensor product of subsystems’ state spaces<math>{\mathcal{H}}_j</math> , so {| width="80%" | |- | width="33%" |'''<big>*</big>''' | width="33%" |<math>\Im=\Im_1\otimes....\otimes\Im_n</math> | width="33%" align="right" |<math>(31)</math>...")
05:19, 10 November 2022 Gianfranco talk contribs created page Store:QLMes16 (Created page with "==9. Epigenetic evolution within theory of open quantum systems== In paper (Asano et al., 2012b), a general model of the epigenetic evolution unifying neo-Darwinian with neo-Lamarckian approaches was created in the framework of theory of open quantum systems. The process of evolution is represented in the form of ''adaptive dynamics'' given by the quantum(-like) master equation describing the dynamics of the information state of epigenome in the process of interaction wi...")
05:19, 10 November 2022 Gianfranco talk contribs created page Store:QLMde16 (Created page with "==9. Epigenetic evolution within theory of open quantum systems== In paper (Asano et al., 2012b), a general model of the epigenetic evolution unifying neo-Darwinian with neo-Lamarckian approaches was created in the framework of theory of open quantum systems. The process of evolution is represented in the form of ''adaptive dynamics'' given by the quantum(-like) master equation describing the dynamics of the information state of epigenome in the process of interaction wi...")
05:19, 10 November 2022 Gianfranco talk contribs created page Store:QLMfr16 (Created page with "==9. Epigenetic evolution within theory of open quantum systems== In paper (Asano et al., 2012b), a general model of the epigenetic evolution unifying neo-Darwinian with neo-Lamarckian approaches was created in the framework of theory of open quantum systems. The process of evolution is represented in the form of ''adaptive dynamics'' given by the quantum(-like) master equation describing the dynamics of the information state of epigenome in the process of interaction wi...")
05:19, 10 November 2022 Gianfranco talk contribs created page Store:QLMit16 (Created page with "==9. Epigenetic evolution within theory of open quantum systems== In paper (Asano et al., 2012b), a general model of the epigenetic evolution unifying neo-Darwinian with neo-Lamarckian approaches was created in the framework of theory of open quantum systems. The process of evolution is represented in the form of ''adaptive dynamics'' given by the quantum(-like) master equation describing the dynamics of the information state of epigenome in the process of interaction wi...")
05:18, 10 November 2022 Gianfranco talk contribs created page Store:QLMen16 (Created page with "==9. Epigenetic evolution within theory of open quantum systems== In paper (Asano et al., 2012b), a general model of the epigenetic evolution unifying neo-Darwinian with neo-Lamarckian approaches was created in the framework of theory of open quantum systems. The process of evolution is represented in the form of ''adaptive dynamics'' given by the quantum(-like) master equation describing the dynamics of the information state of epigenome in the process of interaction wi...")
05:16, 10 November 2022 Gianfranco talk contribs created page Store:QLMes15 (Created page with "===8.3. Operation of biological functions through decoherence=== To make the previous considerations concrete, let us consider a pure quantum state as the initial state. Suppose that a biological function <math>F</math> is dichotomous, <math>F=0,1 </math>, and it is symbolically represented by the Hermitian operator that is diagonal in orthonormal basis <math>|0\rangle</math>,<math>|1\rangle</math> . (We consider the two dimensional state space — the qubit space.) Le...")
05:16, 10 November 2022 Gianfranco talk contribs created page Store:QLMde15 (Created page with "===8.3. Operation of biological functions through decoherence=== To make the previous considerations concrete, let us consider a pure quantum state as the initial state. Suppose that a biological function <math>F</math> is dichotomous, <math>F=0,1 </math>, and it is symbolically represented by the Hermitian operator that is diagonal in orthonormal basis <math>|0\rangle</math>,<math>|1\rangle</math> . (We consider the two dimensional state space — the qubit space.) Le...")
05:16, 10 November 2022 Gianfranco talk contribs created page Store:QLMfr15 (Created page with "===8.3. Operation of biological functions through decoherence=== To make the previous considerations concrete, let us consider a pure quantum state as the initial state. Suppose that a biological function <math>F</math> is dichotomous, <math>F=0,1 </math>, and it is symbolically represented by the Hermitian operator that is diagonal in orthonormal basis <math>|0\rangle</math>,<math>|1\rangle</math> . (We consider the two dimensional state space — the qubit space.) Le...")
05:15, 10 November 2022 Gianfranco talk contribs created page Store:QLMit15 (Created page with "===8.3. Operation of biological functions through decoherence=== To make the previous considerations concrete, let us consider a pure quantum state as the initial state. Suppose that a biological function <math>F</math> is dichotomous, <math>F=0,1 </math>, and it is symbolically represented by the Hermitian operator that is diagonal in orthonormal basis <math>|0\rangle</math>,<math>|1\rangle</math> . (We consider the two dimensional state space — the qubit space.) Le...")
05:15, 10 November 2022 Gianfranco talk contribs created page Store:QLMen15 (Created page with "===8.3. Operation of biological functions through decoherence=== To make the previous considerations concrete, let us consider a pure quantum state as the initial state. Suppose that a biological function <math>F</math> is dichotomous, <math>F=0,1 </math>, and it is symbolically represented by the Hermitian operator that is diagonal in orthonormal basis <math>|0\rangle</math>,<math>|1\rangle</math> . (We consider the two dimensional state space — the qubit space.) Le...")
05:14, 10 November 2022 Gianfranco talk contribs created page Store:QLMes14 (Created page with "===8.2. Biological functions in the quantum Markov framework=== We turn to the open system dynamics with the GKSL-equation. In our modeling, Hamiltonian <math>\widehat{\mathcal{H}}</math> and Lindbladian <math>\widehat{{L}}</math> represent some special ''biological function'' <math>F</math> (see Khrennikov et al., 2018) for details. Its functioning results from interaction of internal and external information flows. In Sections 10, 11.3, <math>F</math> is some ''...")
05:14, 10 November 2022 Gianfranco talk contribs created page Store:QLMde14 (Created page with "===8.2. Biological functions in the quantum Markov framework=== We turn to the open system dynamics with the GKSL-equation. In our modeling, Hamiltonian <math>\widehat{\mathcal{H}}</math> and Lindbladian <math>\widehat{{L}}</math> represent some special ''biological function'' <math>F</math> (see Khrennikov et al., 2018) for details. Its functioning results from interaction of internal and external information flows. In Sections 10, 11.3, <math>F</math> is some ''...")
05:14, 10 November 2022 Gianfranco talk contribs created page Store:QLMfr14 (Created page with "===8.2. Biological functions in the quantum Markov framework=== We turn to the open system dynamics with the GKSL-equation. In our modeling, Hamiltonian <math>\widehat{\mathcal{H}}</math> and Lindbladian <math>\widehat{{L}}</math> represent some special ''biological function'' <math>F</math> (see Khrennikov et al., 2018) for details. Its functioning results from interaction of internal and external information flows. In Sections 10, 11.3, <math>F</math> is some ''...")
05:13, 10 November 2022 Gianfranco talk contribs created page Store:QLMit14 (Created page with "===8.2. Biological functions in the quantum Markov framework=== We turn to the open system dynamics with the GKSL-equation. In our modeling, Hamiltonian <math>\widehat{\mathcal{H}}</math> and Lindbladian <math>\widehat{{L}}</math> represent some special ''biological function'' <math>F</math> (see Khrennikov et al., 2018) for details. Its functioning results from interaction of internal and external information flows. In Sections 10, 11.3, <math>F</math> is some ''...")
05:13, 10 November 2022 Gianfranco talk contribs created page Store:QLMen14 (Created page with "===8.2. Biological functions in the quantum Markov framework=== We turn to the open system dynamics with the GKSL-equation. In our modeling, Hamiltonian <math>\widehat{\mathcal{H}}</math> and Lindbladian <math>\widehat{{L}}</math> represent some special ''biological function'' <math>F</math> (see Khrennikov et al., 2018) for details. Its functioning results from interaction of internal and external information flows. In Sections 10, 11.3, <math>F</math> is some ''...")
05:12, 10 November 2022 Gianfranco talk contribs created page Store:QLMfr13 (Created page with "==8. Open quantum systems: interaction of a biosystem with its environment== As was already emphasized, any biosystem <math>S</math> is fundamentally open. Hence, dynamics of its state has to be modeled via an interaction with surrounding environment <math> \varepsilon</math>. The states of <math>S</math> and <math> \varepsilon</math> are represented in the Hilbert spaces <math>\mathcal{H}</math> and <math>\mathcal{H}</math>. The compound system <math>S+\varepsilon</...")
05:12, 10 November 2022 Gianfranco talk contribs created page Store:QLMde13 (Created page with "==8. Open quantum systems: interaction of a biosystem with its environment== As was already emphasized, any biosystem <math>S</math> is fundamentally open. Hence, dynamics of its state has to be modeled via an interaction with surrounding environment <math> \varepsilon</math>. The states of <math>S</math> and <math> \varepsilon</math> are represented in the Hilbert spaces <math>\mathcal{H}</math> and <math>\mathcal{H}</math>. The compound system <math>S+\varepsilon</...")
05:11, 10 November 2022 Gianfranco talk contribs created page Store:QLMit13 (Created page with "==8. Open quantum systems: interaction of a biosystem with its environment== As was already emphasized, any biosystem <math>S</math> is fundamentally open. Hence, dynamics of its state has to be modeled via an interaction with surrounding environment <math> \varepsilon</math>. The states of <math>S</math> and <math> \varepsilon</math> are represented in the Hilbert spaces <math>\mathcal{H}</math> and <math>\mathcal{H}</math>. The compound system <math>S+\varepsilon</...")
05:11, 10 November 2022 Gianfranco talk contribs created page Store:QLMen13 (Created page with "==8. Open quantum systems: interaction of a biosystem with its environment== As was already emphasized, any biosystem <math>S</math> is fundamentally open. Hence, dynamics of its state has to be modeled via an interaction with surrounding environment <math> \varepsilon</math>. The states of <math>S</math> and <math> \varepsilon</math> are represented in the Hilbert spaces <math>\mathcal{H}</math> and <math>\mathcal{H}</math>. The compound system <math>S+\varepsilon</...")
05:11, 10 November 2022 Gianfranco talk contribs created page Store:QLMes13 (Created page with "==8. Open quantum systems: interaction of a biosystem with its environment== As was already emphasized, any biosystem <math>S</math> is fundamentally open. Hence, dynamics of its state has to be modeled via an interaction with surrounding environment <math> \varepsilon</math>. The states of <math>S</math> and <math> \varepsilon</math> are represented in the Hilbert spaces <math>\mathcal{H}</math> and <math>\mathcal{H}</math>. The compound system <math>S+\varepsilon</...")
05:09, 10 November 2022 Gianfranco talk contribs created page Store:QLMes12 (Created page with "===6.4. Mental realism=== Since very beginning of quantum mechanics, noncommutativity of operators <math>\widehat{A},\widehat{B} </math> representing observables <math>A,B </math> was considered as the mathematical representation of their incompatibility. In philosophic terms, this situation is treated as impossibility of the realistic description. In cognitive science, this means that there exist mental states such that an individual cannot assign the definite values...")

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