Information Physics
-10%
portes grátis
Information Physics
Physics-Information and Quantum Analogies for Complex Systems Modeling
Svitek, Miroslav
Elsevier Science & Technology
06/2021
154
Mole
Inglês
9780323910118
15 a 20 dias
340
Descrição não disponível.
1. Introduction to Information Physics 1.1 Dynamical systems1.2 Information representation1.3 Information source and recipient1.4 Information gate1.5 Information perception1.6 Information scenarios1.7 Information channel
2. Classical Physics - Information Analogies 2.1 Electrics - information analogies 2.2 Magnetic - information analogies 2.3 Information elements2.4 Extended information elements 2.5 Information mem-elements
3. Information circuits3.1 Telematics 3.2 Brain adaptive resonance 3.3 Knowledge cycle
4. Quantum Physics - Information Analogies 4.1 Quantum events 4.2 Quantum objects 4.3 Two (non-)exclusive observers4.4 Composition of quantum objects4.5 Mixture of partial quantum information4.6 Time-varying quantum objects 4.7 Quantum information coding and decoding 4.8 Quantum data flow rate4.9 Holographic approach to phase parameters4.10 Two (non-) distinguished quantum subsystems 4.11 Quantum information gate4.12 Quantum learning
5 Features of Quantum Information 5.1 Quantization 5.2 Quantum entanglement 5.3 Quantum environment 5.4 Quantum identity 5.5 Quantum self-organization 5.6 Quantum interference 5.7 Distance between wave components 5.8 Interaction's speed between wave components 5.9 Component strength5.10 Quantum node6. Composition rules of quantum subsystems6.1 Connected subsystems6.2 Disconnected subsystems6.3 Coexisted subsystems6.4 Symmetrically disconnected subsystems6.5 Symmetrically competing subsystems6.6 Interactions with an environment6.7 Illustrative examples
7. Applicability of quantum models7.1 Quantum processes7.2 Quantum model of hierarchical networks7.3 Time-varying quantum systems7.4 Quantum information gyrator7.5 Quantum transfer functions
8. Extended quantum models8.1 Ordering models8.2 Incremental models8.3 Inserted models}8.4 Intersectional extended models
9. Complex adaptive systems 9.1 Basic agent of smart services9.2 Smart resilient cities9.3 Intelligent transport systemts9.4 Ontology and multiagent technologies
10. Conclusion
2. Classical Physics - Information Analogies 2.1 Electrics - information analogies 2.2 Magnetic - information analogies 2.3 Information elements2.4 Extended information elements 2.5 Information mem-elements
3. Information circuits3.1 Telematics 3.2 Brain adaptive resonance 3.3 Knowledge cycle
4. Quantum Physics - Information Analogies 4.1 Quantum events 4.2 Quantum objects 4.3 Two (non-)exclusive observers4.4 Composition of quantum objects4.5 Mixture of partial quantum information4.6 Time-varying quantum objects 4.7 Quantum information coding and decoding 4.8 Quantum data flow rate4.9 Holographic approach to phase parameters4.10 Two (non-) distinguished quantum subsystems 4.11 Quantum information gate4.12 Quantum learning
5 Features of Quantum Information 5.1 Quantization 5.2 Quantum entanglement 5.3 Quantum environment 5.4 Quantum identity 5.5 Quantum self-organization 5.6 Quantum interference 5.7 Distance between wave components 5.8 Interaction's speed between wave components 5.9 Component strength5.10 Quantum node6. Composition rules of quantum subsystems6.1 Connected subsystems6.2 Disconnected subsystems6.3 Coexisted subsystems6.4 Symmetrically disconnected subsystems6.5 Symmetrically competing subsystems6.6 Interactions with an environment6.7 Illustrative examples
7. Applicability of quantum models7.1 Quantum processes7.2 Quantum model of hierarchical networks7.3 Time-varying quantum systems7.4 Quantum information gyrator7.5 Quantum transfer functions
8. Extended quantum models8.1 Ordering models8.2 Incremental models8.3 Inserted models}8.4 Intersectional extended models
9. Complex adaptive systems 9.1 Basic agent of smart services9.2 Smart resilient cities9.3 Intelligent transport systemts9.4 Ontology and multiagent technologies
10. Conclusion
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Active information power; Basic Smart City agent; Brain adaptive resonance; City Information Management; Coexisted quantum subsystems; Component strength; Connected quantum subsystems; Disconnected quantum subsystems; Distance between wave components; Distinguished quantum subsystems; Electrics-information analogies; Entanglement swapping; Fragility; Holographic approach; ITS architecture; Incremental quantum model; Information capacitance; Information channel; Information elements; Information gate; Information impedance; Information inductance; Information mem-element; Information mem-elements; Information memcapacitor; Information meminductor; Information memristor; Information norator; Information nullator; Information perception; Information representation; Information scenarios; Inserted quantum model; Intelligent transport systems; Interaction's speed between wave components; Intersectional extended quantum model; Key Performance Indicators (KPIs); Knowledge cycle; Magnetic-information analogies; Mixture of quantum information; Multiagent systems (MAS); Multiagent technologies (MATs); Nondistinguished quantum subsystems; Ontology; Ordering quantum model; Quantization; Quantum coherence; Quantum decoherence; Quantum entanglement; Quantum environment; Quantum event; Quantum feedback system; Quantum finite impulse response (QFIR); Quantum identity; Quantum infinite impulse response (QIIR); Quantum information coding; Quantum information decoding; Quantum information gate; Quantum information gyrator; Quantum information science; Quantum interference; Quantum learning; Quantum node; Quantum object; Quantum process; Quantum self-organization; Quantum transfer function (QTF); Quasi-stationary quantum system; Reactive information power; Smart City concept; Smart Resilient City (SRC); Symmetrically competing quantum subsystems; Symmetrically disconnected quantum subsystems; System resiliency; Telematics; Time-varying quantum system; Wave information content; Wave information flow; Wave probabilistic function
1. Introduction to Information Physics 1.1 Dynamical systems1.2 Information representation1.3 Information source and recipient1.4 Information gate1.5 Information perception1.6 Information scenarios1.7 Information channel
2. Classical Physics - Information Analogies 2.1 Electrics - information analogies 2.2 Magnetic - information analogies 2.3 Information elements2.4 Extended information elements 2.5 Information mem-elements
3. Information circuits3.1 Telematics 3.2 Brain adaptive resonance 3.3 Knowledge cycle
4. Quantum Physics - Information Analogies 4.1 Quantum events 4.2 Quantum objects 4.3 Two (non-)exclusive observers4.4 Composition of quantum objects4.5 Mixture of partial quantum information4.6 Time-varying quantum objects 4.7 Quantum information coding and decoding 4.8 Quantum data flow rate4.9 Holographic approach to phase parameters4.10 Two (non-) distinguished quantum subsystems 4.11 Quantum information gate4.12 Quantum learning
5 Features of Quantum Information 5.1 Quantization 5.2 Quantum entanglement 5.3 Quantum environment 5.4 Quantum identity 5.5 Quantum self-organization 5.6 Quantum interference 5.7 Distance between wave components 5.8 Interaction's speed between wave components 5.9 Component strength5.10 Quantum node6. Composition rules of quantum subsystems6.1 Connected subsystems6.2 Disconnected subsystems6.3 Coexisted subsystems6.4 Symmetrically disconnected subsystems6.5 Symmetrically competing subsystems6.6 Interactions with an environment6.7 Illustrative examples
7. Applicability of quantum models7.1 Quantum processes7.2 Quantum model of hierarchical networks7.3 Time-varying quantum systems7.4 Quantum information gyrator7.5 Quantum transfer functions
8. Extended quantum models8.1 Ordering models8.2 Incremental models8.3 Inserted models}8.4 Intersectional extended models
9. Complex adaptive systems 9.1 Basic agent of smart services9.2 Smart resilient cities9.3 Intelligent transport systemts9.4 Ontology and multiagent technologies
10. Conclusion
2. Classical Physics - Information Analogies 2.1 Electrics - information analogies 2.2 Magnetic - information analogies 2.3 Information elements2.4 Extended information elements 2.5 Information mem-elements
3. Information circuits3.1 Telematics 3.2 Brain adaptive resonance 3.3 Knowledge cycle
4. Quantum Physics - Information Analogies 4.1 Quantum events 4.2 Quantum objects 4.3 Two (non-)exclusive observers4.4 Composition of quantum objects4.5 Mixture of partial quantum information4.6 Time-varying quantum objects 4.7 Quantum information coding and decoding 4.8 Quantum data flow rate4.9 Holographic approach to phase parameters4.10 Two (non-) distinguished quantum subsystems 4.11 Quantum information gate4.12 Quantum learning
5 Features of Quantum Information 5.1 Quantization 5.2 Quantum entanglement 5.3 Quantum environment 5.4 Quantum identity 5.5 Quantum self-organization 5.6 Quantum interference 5.7 Distance between wave components 5.8 Interaction's speed between wave components 5.9 Component strength5.10 Quantum node6. Composition rules of quantum subsystems6.1 Connected subsystems6.2 Disconnected subsystems6.3 Coexisted subsystems6.4 Symmetrically disconnected subsystems6.5 Symmetrically competing subsystems6.6 Interactions with an environment6.7 Illustrative examples
7. Applicability of quantum models7.1 Quantum processes7.2 Quantum model of hierarchical networks7.3 Time-varying quantum systems7.4 Quantum information gyrator7.5 Quantum transfer functions
8. Extended quantum models8.1 Ordering models8.2 Incremental models8.3 Inserted models}8.4 Intersectional extended models
9. Complex adaptive systems 9.1 Basic agent of smart services9.2 Smart resilient cities9.3 Intelligent transport systemts9.4 Ontology and multiagent technologies
10. Conclusion
Este título pertence ao(s) assunto(s) indicados(s). Para ver outros títulos clique no assunto desejado.
Active information power; Basic Smart City agent; Brain adaptive resonance; City Information Management; Coexisted quantum subsystems; Component strength; Connected quantum subsystems; Disconnected quantum subsystems; Distance between wave components; Distinguished quantum subsystems; Electrics-information analogies; Entanglement swapping; Fragility; Holographic approach; ITS architecture; Incremental quantum model; Information capacitance; Information channel; Information elements; Information gate; Information impedance; Information inductance; Information mem-element; Information mem-elements; Information memcapacitor; Information meminductor; Information memristor; Information norator; Information nullator; Information perception; Information representation; Information scenarios; Inserted quantum model; Intelligent transport systems; Interaction's speed between wave components; Intersectional extended quantum model; Key Performance Indicators (KPIs); Knowledge cycle; Magnetic-information analogies; Mixture of quantum information; Multiagent systems (MAS); Multiagent technologies (MATs); Nondistinguished quantum subsystems; Ontology; Ordering quantum model; Quantization; Quantum coherence; Quantum decoherence; Quantum entanglement; Quantum environment; Quantum event; Quantum feedback system; Quantum finite impulse response (QFIR); Quantum identity; Quantum infinite impulse response (QIIR); Quantum information coding; Quantum information decoding; Quantum information gate; Quantum information gyrator; Quantum information science; Quantum interference; Quantum learning; Quantum node; Quantum object; Quantum process; Quantum self-organization; Quantum transfer function (QTF); Quasi-stationary quantum system; Reactive information power; Smart City concept; Smart Resilient City (SRC); Symmetrically competing quantum subsystems; Symmetrically disconnected quantum subsystems; System resiliency; Telematics; Time-varying quantum system; Wave information content; Wave information flow; Wave probabilistic function
