Universal complexity in action UNREDUCED COMPLEXITY APPLICATIONS UNREDUCED COMPLEXITY APPLICATIONS � Unified, causally complete fundamental physics (quantum mechan Unified, causally complete fundamental physics (quantum mechanics, relativity, ics, relativity, � particles, fields, forces, cosmology): no “ particles, fields, forces, cosmology): no “mysteries mysteries” ”, transparent, realistic , transparent, realistic knowledge and world view, the unique way to unlimited clean energy energy knowledge and world view, the unique way to unlimited clean � Real, complex Real, complex- -dynamic nanodevices (quantum & classical), huge efficiency dynamic nanodevices (quantum & classical), huge efficiency � � Causally complete, reliable genomics (unreduced interaction dy Causally complete, reliable genomics (unreduced interaction dynamics) namics) � � Complex Complex- -dynamic biology: causal evolution theory, integral medicine dynamic biology: causal evolution theory, integral medicine � � Creative ecology/development: realistic, unreduced sustainabil Creative ecology/development: realistic, unreduced sustainability concept ity concept � � Emerging genuine intelligence and consciousness (natural and a Emerging genuine intelligence and consciousness (natural and artificial) rtificial) � � Complex Complex- -dynamic, intelligent communication networks and software systems dynamic, intelligent communication networks and software systems � UNREDUCED SUSTAINABILITY FEATURES UNREDUCED SUSTAINABILITY FEATURES � Progress through permanent, constructive, omnipresent interacti Progress through permanent, constructive, omnipresent interaction: on: � creating a superior, individually structured quality of life e creating a superior, individually structured quality of lif � Practical responsibility of scientists for creation of Practical responsibility of scientists for creation of “ “knowledge knowledge- -based society based society” ” � and “ and “understanding understanding- -based (complete) knowledge based (complete) knowledge” ”: no deficient : no deficient “ “models models” ” � Constructive use of diversity instead of destructive mechanist Constructive use of diversity instead of destructive mechanistic unification ic unification � http://arxiv.org/find/quant- http://arxiv.org/find/quant -ph,gr ph,gr- -qc,physics/1/au:+Kirilyuk/0/1/0/all/0/1 qc,physics/1/au:+Kirilyuk/0/1/0/all/0/1
UNIFIED SCIENCE OF REAL COMPLEX SYSTEMS UNIFIED SCIENCE OF REAL COMPLEX SYSTEMS UNIFIED SCIENCE OF REAL COMPLEX SYSTEMS Principles of Complex System Operation & Design Principles of Complex System Operation & Design Principles of Complex System Operation & Design I. Complexity correspondence principle I. Complexity correspondence principle I. Complexity correspondence principle Efficient interaction of comparable complexity comparable complexity units units Efficient interaction of Efficient interaction of comparable complexity units II. Complex- -dynamic control principle dynamic control principle II. Complex II. Complex-dynamic control principle Complexity development as the purpose of control as the purpose of control Complexity development Complexity development as the purpose of control III. Unreduced (free) interaction principle III. Unreduced (free) interaction principle III. Unreduced (free) interaction principle Huge power of unreduced interaction complexity of unreduced interaction complexity Huge power Huge power of unreduced interaction complexity UNIFIED BY THE SYMMETRY OF COMPLEXITY SYMMETRY OF COMPLEXITY UNIFIED BY THE UNIFIED BY THE SYMMETRY OF COMPLEXITY
Complexity Correspondence Principle Complexity Correspondence Principle Complexity Correspondence Principle Efficient Interaction of Comparable Complexity Units Efficient Interaction of Comparable Complexity Units Efficient Interaction of Comparable Complexity Units � Higher complexity enslaves lower complexity Higher complexity enslaves lower complexity � Higher complexity enslaves lower complexity � Low complexity cannot cannot control/simulate high complexity control/simulate high complexity Low complexity Low complexity cannot control/simulate high complexity � only unreduced complexity only unreduced complexity tools for tools for real real system design system design � only unreduced complexity tools for real system design � � Similar complexities give rise to strong chaoticity Similar complexities give rise to strong chaoticity � Similar complexities give rise to strong chaoticity � Creative power of power of “ confined ” ” chaos (dynamic adaptability) chaos (dynamic adaptability) Creative “ confined Creative power of “ confined ” chaos (dynamic adaptability) � Excessive complexity tool replaces useful operation Excessive complexity tool replaces useful operation � Excessive complexity tool replaces useful operation � Complex tools at context/software, not Complex tools at context/software, not traffic/hardware level traffic/hardware level Complex tools at context/software, not traffic/hardware level
Complex- -Dynamic Control Principle Dynamic Control Principle Complex-Dynamic Control Principle Complex Complexity Development as Unified Control Purpose Complexity Development as Unified Control Purpose Complexity Development as Unified Control Purpose � Controlled dynamics cannot be totally regular Controlled dynamics cannot be totally regular � Controlled dynamics cannot be totally regular � Relying upon usual “ total ” ” control gives control gives total system failure total system failure Relying upon usual “ total Relying upon usual “ total ” control gives total system failure Multivalued, chaotic SOC regime is a general control result regime is a general control result Multivalued, chaotic SOC Multivalued, chaotic SOC regime is a general control result � Optimal interaction complexity development Optimal interaction complexity development � Optimal interaction complexity development � Creative, rather than restrictive control is , rather than restrictive control is more more reliable reliable Creative Creative, rather than restrictive control is more reliable � Universal guiding line and criterion of control Universal guiding line and criterion of control � Universal guiding line and criterion of control � Sustainable control: global stability by local creativity Sustainable control : global stability by local creativity Sustainable control: global stability by local creativity
Unreduced (Free) Interaction Principle Unreduced (Free) Interaction Principle Unreduced (Free) Interaction Principle Huge Power of Unreduced Interaction Complexity Huge Power of Unreduced Interaction Complexity Huge Power of Unreduced Interaction Complexity � General purpose of complexity General purpose of complexity- -entropy growth entropy growth � General purpose of complexity-entropy growth � Only general direction is fixed/controlled, not the details Only general direction is fixed/controlled, not the details Only general direction is fixed/controlled, not the details Intrinsic chaoticity is a normal, useful system state is a normal, useful system state Intrinsic chaoticity Intrinsic chaoticity is a normal, useful system state � Huge power of unreduced complex dynamics Huge power of unreduced complex dynamics � Huge power of unreduced complex dynamics � Genuine parallelism of multivalued dynamical fractal of multivalued dynamical fractal Genuine parallelism Genuine parallelism of multivalued dynamical fractal � Constructive alternation of strong chaos and SOC Constructive alternation of strong chaos and SOC � Constructive alternation of strong chaos and SOC � Symmetry of complexity: chaotic search and ordered creation Symmetry of complexity : chaotic search and ordered creation Symmetry of complexity: chaotic search and ordered creation
Unreduced complexity applications • Causal universe origin and structure: fundamental physics without mysteries fundamental physics without mysteries • Complex-dynamic nanoscience and biology: reliable genomics and integral medicine reliable genomics and integral medicine • Emerging intelligence and consciousness: complex- -dynamic interaction dynamic interaction � � genuine AI genuine AI complex • Complex-dynamic information systems: intelligent software and autonomic networks intelligent software and autonomic networks • Creative ecology and sustainability transition: bifurcation of civilisation development bifurcation of civilisation development
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