The Resource The holographic anthropic multiverse : formalizing the complex geometry of reality, Richard L. Amoroso, Elizabeth A. Rauscher
The holographic anthropic multiverse : formalizing the complex geometry of reality, Richard L. Amoroso, Elizabeth A. Rauscher
Resource Information
The item The holographic anthropic multiverse : formalizing the complex geometry of reality, Richard L. Amoroso, Elizabeth A. Rauscher represents a specific, individual, material embodiment of a distinct intellectual or artistic creation found in University of MissouriSt. Louis Libraries.This item is available to borrow from 1 library branch.
Resource Information
The item The holographic anthropic multiverse : formalizing the complex geometry of reality, Richard L. Amoroso, Elizabeth A. Rauscher represents a specific, individual, material embodiment of a distinct intellectual or artistic creation found in University of MissouriSt. Louis Libraries.
This item is available to borrow from 1 library branch.
 Summary
 Every hundred years or so, a unique groundbreaking Copernican class volume arises unexpectedly. From ashes long thought cold of Einstein's static universe model, for the first time technically viable alternative interpretations to all pillars of Big Bang cosmology are presented in the context of a profound new "continuousstate" cosmological paradigm able to elucidate many contemporary problems plaguing the standard model of particle physics. The cosmology provides an alternative derivation of the string/brane tension formalism derived from largescale additional dimensions that leads to a putative unique backgroundindependent string vacuum without requiring the Higgs mechanism or SUSY superpartners. Breakthroughs presented, arising from the broad spectrum of explanatory power, include an empirical protocol for violation of the quantum uncertainty principle that provides a viable model for the implementation of universal bulk quantum computing. Other developments naturally arising from utility of the new regime include a design for constructing de Broglietype matterwave projectile defense shields with farreaching consequences
 Language
 eng
 Extent
 1 online resource (xxii, 485 pages)
 Contents

 1. Demise of the big bang  a philosophical conundrum. 1.1. Philosophical overview. 1.2. A new cosmological horizon  2. Extending the standard model : towards the ultimate evolution of string theory. 2.1. Preambulatory hoopla. 2.2. Ultimate evolution of Mtheory. 2.3. String/Brane dynamics. 2.4. New horizons beyond the standard model  3. Fundamental parameters for a continuousstate holographic anthropic multiverse. 3.1. Introduction to the cosmological issues. 3.2. Clarification of pertinent cosmological nomenclature. 3.3. Parallel interpretations of cosmological data. 3.4. Euclidean/Minkowski geometry as basis for observed reality. 3.5. Philosophy of space in HAM cosmology  origin of structure. 3.6. Space : relational versus absolute. 3.7. Physical cosmology of fundamental least cosmological unit. 3.8. Holographic Anthropic Multiverse Cosmology (HAM). 3.9. Overview of the formalism for noetic cosmology. 3.10. Transformation of space into time. 3.11. Energy dependent spacetime metric. 3.12. The Wheeler Geon concept extended to noetic superspace. 3.13. The HyperGeon domain of HAM noetic field theory. 3.14. Conclusions  4. An alternative derivation of string tension determining a unique background independent string vacuum. 4.1. Introductory prolegomena. 4.2. Scaling in cosmology and the continuousstate postulate. 4.3. Fine tuning implied by astrophysical observation. 4.4. Numerical relations coupled to the concept of scaling. 4.5. Physical cosmology of the closepacked fundamental least unit for an energy dependent spacetime metric. 4.6. The formalism for noetic HAM cosmology. 4.7. Transformation of space into time and string tension. 4.8. Alternative derivation of string tension in HAM cosmology. 4.9. Parameters of the spacetime Incursive Oscillator (IO). 4.10. Emergence of 2Branes from inherent spacetime oscillations. 4.11. Summary of noetic spacetime parameters. 4.12. Simplistic computer simulated production of the 2Brane. 4.13. Conclusions  5. Formalizing the ultimate geometry of reality : dimensionality, awareness and arrow of time. 5.1. Introduction. 5.2. Current philosophy of temporal science. 5.3. Complementarity of physical time and observer time. 5.4. The vacuum origin of thermodynamics and entropy. 5.5. Peripheral physical properties related to the observer. 5.6. Introduction to spin exchange compactification dynamics and the permutation of dimensions in the noetic transformation. 5.7. Dirac spherical rotation inherent to the transformation of the fundamental leastunit. 5.8. Preparing the noetic spacetime transformation. 5.9. Developing the line element for noetic superspace. 5.10. Formalizing the noetic group of transformations. 5.11. Final remarks  6. Integration of gravity & electromagnetism in terms of a Dirac polarized vacuum. 6.1. Introduction to fixing the G/EM framework. 6.2. Flat spacetime and a real physical aether. 6.3. General relativity represented as a polarizable vacuum. 6.4. Maxwell's equations extended. 6.5. Possible new consequences of the model. 6.6. Extending Newton's model with inertia and vacuum drag. 6.7. Relativistic Maxwell's equations in complex form. 6.8. Summation and conclusions  7. Redshift/CMBR as intrinsic blackbody cavityQED absorption/emission equilibrium dynamics. 7.1. Introductory cosmological parameters. 7.2. Origin of redshift in nonzero restmass photon anisotropy in photon propagation and the vigier tiredlight hypothesis. 7.3. Weakfield gravitational approach of a finite lightpencil and derivation of the gravitational field of radiation. 7.4. Gravitational action of a light pencil. 7.5. Internal motion structure of the photon. 7.6. Introduction to spin exchange compactification dynamics. 7.7. Blackbody exciplex radiationcosmological constraints. 7.8. Blackbody microcavityQED constraints. 7.9. CMBR energy damping by vacuum conductivity. 7.10. Possible black hole considerations for discussion. 7.11. Size temperature relationship of Kerr black holes. 7.12. Temperature relationship of Dirac QED cavity 'black holes'. 7.13. Spin exchange parameters of spacetimephoton coupling. 7.14. Spontaneous CMBR emission by spacetime cavityQED. 7.15. Possibility of blackbody emission from continuous spacetime compactification. 7.16. New background conditions of the Dirac vacuum. 7.17. Deriving the topological action principle for CMBR emission. 7.18. A putative model of exciplex proton nucleosynthesis. 7.19. Summary and conclusions  8. Implications of multidimensional geometries and measurement. 8.1. Introduction. 8.2. Complexified EM fields in local and nonlocal Minkowski space. 8.3. Complex Minkowski space : implications for physics. 8.4. Complex vector and advanced potentials and Bell's inequality. 8.5. Superluminal vector and scalar potential transformation laws. 8.6. Insights into Dirac and Penrose spinor calculus. 8.7. Conclusions  9. Probability [symbol]1 : an empirical protocol for surmounting quantum uncertainty. 9.1. Introduction  philosophy of phenomenology versus ontology. 9.2. The proper cosmological perspective is key. 9.3. Micromagnetics of spacetime conformation. 9.4. Catastrophe theory and the noetic formalism. 9.5. Protocol for experimentally testing noetic cosmology. 9.6. Introduction to the P[symbol]1 experimental design. 9.7. Conclusions  10. On the possibility of relativistic shockwave effects in observations of quasar luminosity. 10.1. The quasar redshiftdistance interpretation controversy. 10.2. QSOs an issue of the fundamental basis of geometrodynamics. 10.3. Recent refinements of the TitiusBode series as an indicator of a possible new gravitational dynamic. 10.4. Critique of Hubble's law as applied to Doppler expansion. 10.5. The observer and the cosmological principle. 10.6. Some fundamental insights on shock waves. 10.7. New cosmological gravitational shock parameters. 10.8. Hypersonic shock waves. 10.9. Gravitational shock waves. 10.10. Conclusions  11. The bulk implementation of universal scalable quantum computing. 11.1. Introduction  basics of quantum computing. 11.2. Overview of new fundamental parameters. 11.3. The causal separation of phenomenology from ontology. 11.4. Review of angular momentum and PauliDirac spin matrices. 11.5. Noumenal reality versus phenomenology of quantum theory. 11.6. Justification for the incursive noetic model. 11.7. Essential properties of complex noetic 12 space. 11.8. Geometric introduction to the noetic QC ontology. 11.9. Microphysical computation limits : case of relativistic qubits. 11.10. Essential parameters of the incursive oscillator. 11.11. Ontological I/O by superceding quantum uncertainty. 11.12. A twistor approach to the UQC I/O ontology. 11.13. Class II mesoionic xanthines as potential 10qubit quantum computer substrate registers. 11.14. Initialization of mesoionic xanthine registers. 11.15. Conclusions  12. Practical matterwave antiballistic defense shield technologies. 12.1. Introduction  current status of shield technology. 12.2. Overview of new theoretical and physical requirements. 12.3. Critical philosophical considerations on the limits of potentia. 12.4. The shield vacuum. 12.5. What are the required vacuum parameters? 12.6. Domain wall boundary conditions and emission absorption loci for advancedretarded waves. 12.7. Energy increase from Ising model latticegas properties. 12.8. Programming matter through cellular automata. 12.9. Introduction to de Broglie matterwaves. 12.10. Coherent control of standing matterwaves. 12.11. Afterward. 12.12. Summary of the defense shield design parameters  13. Is a differernt search protocol required for success in SETI research? 13.1. On the horns of a dilemma. 13.2. SETI epistemology from the anthropic perspective. 13.3. The Drake equation. 13.4. Brief review of anthropic multiverse parameters. 13.5. Does SETI require a different strategy for success? 13.6
 Theological arguments  Adam given his reckoning versus the cosmological age of the earth. 13.7. Seemingly farout absurd pseudoscientific arguments. 13.8. The Anthropic Principle (AP). 13.9. Calculations for a holographic anthropic multiverse. 13.10. Wave Function of the Universe (WFU). 13.11. Subtractive interferometry. 13.12. New SETI technology  the interdimensional Qtelescope. 13.13. Conclusions contusions and cowardice
 Isbn
 9789812839312
 Label
 The holographic anthropic multiverse : formalizing the complex geometry of reality
 Title
 The holographic anthropic multiverse
 Title remainder
 formalizing the complex geometry of reality
 Statement of responsibility
 Richard L. Amoroso, Elizabeth A. Rauscher
 Language
 eng
 Summary
 Every hundred years or so, a unique groundbreaking Copernican class volume arises unexpectedly. From ashes long thought cold of Einstein's static universe model, for the first time technically viable alternative interpretations to all pillars of Big Bang cosmology are presented in the context of a profound new "continuousstate" cosmological paradigm able to elucidate many contemporary problems plaguing the standard model of particle physics. The cosmology provides an alternative derivation of the string/brane tension formalism derived from largescale additional dimensions that leads to a putative unique backgroundindependent string vacuum without requiring the Higgs mechanism or SUSY superpartners. Breakthroughs presented, arising from the broad spectrum of explanatory power, include an empirical protocol for violation of the quantum uncertainty principle that provides a viable model for the implementation of universal bulk quantum computing. Other developments naturally arising from utility of the new regime include a design for constructing de Broglietype matterwave projectile defense shields with farreaching consequences
 Cataloging source
 LLB
 http://library.link/vocab/creatorName
 Amoroso, Richard L
 Dewey number
 523.1
 Illustrations
 illustrations
 Index
 index present
 LC call number
 QB991.Q36
 LC item number
 A46 2009eb
 Literary form
 non fiction
 Nature of contents

 dictionaries
 bibliography
 http://library.link/vocab/relatedWorkOrContributorName

 Rauscher, Elizabeth A
 World Scientific (Firm)
 Series statement
 K & E series on knots and everything
 Series volume
 v. 43
 http://library.link/vocab/subjectName

 Quantum cosmology
 Anthropic principle
 Supersymmetry
 SCIENCE
 Anthropic principle
 Quantum cosmology
 Supersymmetry
 Label
 The holographic anthropic multiverse : formalizing the complex geometry of reality, Richard L. Amoroso, Elizabeth A. Rauscher
 Bibliography note
 Includes bibliographical references and index
 Carrier category
 online resource
 Carrier category code

 cr
 Carrier MARC source
 rdacarrier
 Color
 black and white
 Content category
 text
 Content type code

 txt
 Content type MARC source
 rdacontent
 Contents

 1. Demise of the big bang  a philosophical conundrum. 1.1. Philosophical overview. 1.2. A new cosmological horizon  2. Extending the standard model : towards the ultimate evolution of string theory. 2.1. Preambulatory hoopla. 2.2. Ultimate evolution of Mtheory. 2.3. String/Brane dynamics. 2.4. New horizons beyond the standard model  3. Fundamental parameters for a continuousstate holographic anthropic multiverse. 3.1. Introduction to the cosmological issues. 3.2. Clarification of pertinent cosmological nomenclature. 3.3. Parallel interpretations of cosmological data. 3.4. Euclidean/Minkowski geometry as basis for observed reality. 3.5. Philosophy of space in HAM cosmology  origin of structure. 3.6. Space : relational versus absolute. 3.7. Physical cosmology of fundamental least cosmological unit. 3.8. Holographic Anthropic Multiverse Cosmology (HAM). 3.9. Overview of the formalism for noetic cosmology. 3.10. Transformation of space into time. 3.11. Energy dependent spacetime metric. 3.12. The Wheeler Geon concept extended to noetic superspace. 3.13. The HyperGeon domain of HAM noetic field theory. 3.14. Conclusions  4. An alternative derivation of string tension determining a unique background independent string vacuum. 4.1. Introductory prolegomena. 4.2. Scaling in cosmology and the continuousstate postulate. 4.3. Fine tuning implied by astrophysical observation. 4.4. Numerical relations coupled to the concept of scaling. 4.5. Physical cosmology of the closepacked fundamental least unit for an energy dependent spacetime metric. 4.6. The formalism for noetic HAM cosmology. 4.7. Transformation of space into time and string tension. 4.8. Alternative derivation of string tension in HAM cosmology. 4.9. Parameters of the spacetime Incursive Oscillator (IO). 4.10. Emergence of 2Branes from inherent spacetime oscillations. 4.11. Summary of noetic spacetime parameters. 4.12. Simplistic computer simulated production of the 2Brane. 4.13. Conclusions  5. Formalizing the ultimate geometry of reality : dimensionality, awareness and arrow of time. 5.1. Introduction. 5.2. Current philosophy of temporal science. 5.3. Complementarity of physical time and observer time. 5.4. The vacuum origin of thermodynamics and entropy. 5.5. Peripheral physical properties related to the observer. 5.6. Introduction to spin exchange compactification dynamics and the permutation of dimensions in the noetic transformation. 5.7. Dirac spherical rotation inherent to the transformation of the fundamental leastunit. 5.8. Preparing the noetic spacetime transformation. 5.9. Developing the line element for noetic superspace. 5.10. Formalizing the noetic group of transformations. 5.11. Final remarks  6. Integration of gravity & electromagnetism in terms of a Dirac polarized vacuum. 6.1. Introduction to fixing the G/EM framework. 6.2. Flat spacetime and a real physical aether. 6.3. General relativity represented as a polarizable vacuum. 6.4. Maxwell's equations extended. 6.5. Possible new consequences of the model. 6.6. Extending Newton's model with inertia and vacuum drag. 6.7. Relativistic Maxwell's equations in complex form. 6.8. Summation and conclusions  7. Redshift/CMBR as intrinsic blackbody cavityQED absorption/emission equilibrium dynamics. 7.1. Introductory cosmological parameters. 7.2. Origin of redshift in nonzero restmass photon anisotropy in photon propagation and the vigier tiredlight hypothesis. 7.3. Weakfield gravitational approach of a finite lightpencil and derivation of the gravitational field of radiation. 7.4. Gravitational action of a light pencil. 7.5. Internal motion structure of the photon. 7.6. Introduction to spin exchange compactification dynamics. 7.7. Blackbody exciplex radiationcosmological constraints. 7.8. Blackbody microcavityQED constraints. 7.9. CMBR energy damping by vacuum conductivity. 7.10. Possible black hole considerations for discussion. 7.11. Size temperature relationship of Kerr black holes. 7.12. Temperature relationship of Dirac QED cavity 'black holes'. 7.13. Spin exchange parameters of spacetimephoton coupling. 7.14. Spontaneous CMBR emission by spacetime cavityQED. 7.15. Possibility of blackbody emission from continuous spacetime compactification. 7.16. New background conditions of the Dirac vacuum. 7.17. Deriving the topological action principle for CMBR emission. 7.18. A putative model of exciplex proton nucleosynthesis. 7.19. Summary and conclusions  8. Implications of multidimensional geometries and measurement. 8.1. Introduction. 8.2. Complexified EM fields in local and nonlocal Minkowski space. 8.3. Complex Minkowski space : implications for physics. 8.4. Complex vector and advanced potentials and Bell's inequality. 8.5. Superluminal vector and scalar potential transformation laws. 8.6. Insights into Dirac and Penrose spinor calculus. 8.7. Conclusions  9. Probability [symbol]1 : an empirical protocol for surmounting quantum uncertainty. 9.1. Introduction  philosophy of phenomenology versus ontology. 9.2. The proper cosmological perspective is key. 9.3. Micromagnetics of spacetime conformation. 9.4. Catastrophe theory and the noetic formalism. 9.5. Protocol for experimentally testing noetic cosmology. 9.6. Introduction to the P[symbol]1 experimental design. 9.7. Conclusions  10. On the possibility of relativistic shockwave effects in observations of quasar luminosity. 10.1. The quasar redshiftdistance interpretation controversy. 10.2. QSOs an issue of the fundamental basis of geometrodynamics. 10.3. Recent refinements of the TitiusBode series as an indicator of a possible new gravitational dynamic. 10.4. Critique of Hubble's law as applied to Doppler expansion. 10.5. The observer and the cosmological principle. 10.6. Some fundamental insights on shock waves. 10.7. New cosmological gravitational shock parameters. 10.8. Hypersonic shock waves. 10.9. Gravitational shock waves. 10.10. Conclusions  11. The bulk implementation of universal scalable quantum computing. 11.1. Introduction  basics of quantum computing. 11.2. Overview of new fundamental parameters. 11.3. The causal separation of phenomenology from ontology. 11.4. Review of angular momentum and PauliDirac spin matrices. 11.5. Noumenal reality versus phenomenology of quantum theory. 11.6. Justification for the incursive noetic model. 11.7. Essential properties of complex noetic 12 space. 11.8. Geometric introduction to the noetic QC ontology. 11.9. Microphysical computation limits : case of relativistic qubits. 11.10. Essential parameters of the incursive oscillator. 11.11. Ontological I/O by superceding quantum uncertainty. 11.12. A twistor approach to the UQC I/O ontology. 11.13. Class II mesoionic xanthines as potential 10qubit quantum computer substrate registers. 11.14. Initialization of mesoionic xanthine registers. 11.15. Conclusions  12. Practical matterwave antiballistic defense shield technologies. 12.1. Introduction  current status of shield technology. 12.2. Overview of new theoretical and physical requirements. 12.3. Critical philosophical considerations on the limits of potentia. 12.4. The shield vacuum. 12.5. What are the required vacuum parameters? 12.6. Domain wall boundary conditions and emission absorption loci for advancedretarded waves. 12.7. Energy increase from Ising model latticegas properties. 12.8. Programming matter through cellular automata. 12.9. Introduction to de Broglie matterwaves. 12.10. Coherent control of standing matterwaves. 12.11. Afterward. 12.12. Summary of the defense shield design parameters  13. Is a differernt search protocol required for success in SETI research? 13.1. On the horns of a dilemma. 13.2. SETI epistemology from the anthropic perspective. 13.3. The Drake equation. 13.4. Brief review of anthropic multiverse parameters. 13.5. Does SETI require a different strategy for success? 13.6
 Theological arguments  Adam given his reckoning versus the cosmological age of the earth. 13.7. Seemingly farout absurd pseudoscientific arguments. 13.8. The Anthropic Principle (AP). 13.9. Calculations for a holographic anthropic multiverse. 13.10. Wave Function of the Universe (WFU). 13.11. Subtractive interferometry. 13.12. New SETI technology  the interdimensional Qtelescope. 13.13. Conclusions contusions and cowardice
 Control code
 613381655
 Dimensions
 other
 Extent
 1 online resource (xxii, 485 pages)
 File format
 unknown
 Form of item
 online
 Isbn
 9789812839312
 Lccn
 2009017158
 Media category
 computer
 Media MARC source
 rdamedia
 Media type code

 c
 Other physical details
 illustrations.
 Quality assurance targets
 unknown
 Sound
 unknown sound
 Specific material designation
 remote
 System control number
 (OCoLC)613381655
 Label
 The holographic anthropic multiverse : formalizing the complex geometry of reality, Richard L. Amoroso, Elizabeth A. Rauscher
 Bibliography note
 Includes bibliographical references and index
 Carrier category
 online resource
 Carrier category code

 cr
 Carrier MARC source
 rdacarrier
 Color
 black and white
 Content category
 text
 Content type code

 txt
 Content type MARC source
 rdacontent
 Contents

 1. Demise of the big bang  a philosophical conundrum. 1.1. Philosophical overview. 1.2. A new cosmological horizon  2. Extending the standard model : towards the ultimate evolution of string theory. 2.1. Preambulatory hoopla. 2.2. Ultimate evolution of Mtheory. 2.3. String/Brane dynamics. 2.4. New horizons beyond the standard model  3. Fundamental parameters for a continuousstate holographic anthropic multiverse. 3.1. Introduction to the cosmological issues. 3.2. Clarification of pertinent cosmological nomenclature. 3.3. Parallel interpretations of cosmological data. 3.4. Euclidean/Minkowski geometry as basis for observed reality. 3.5. Philosophy of space in HAM cosmology  origin of structure. 3.6. Space : relational versus absolute. 3.7. Physical cosmology of fundamental least cosmological unit. 3.8. Holographic Anthropic Multiverse Cosmology (HAM). 3.9. Overview of the formalism for noetic cosmology. 3.10. Transformation of space into time. 3.11. Energy dependent spacetime metric. 3.12. The Wheeler Geon concept extended to noetic superspace. 3.13. The HyperGeon domain of HAM noetic field theory. 3.14. Conclusions  4. An alternative derivation of string tension determining a unique background independent string vacuum. 4.1. Introductory prolegomena. 4.2. Scaling in cosmology and the continuousstate postulate. 4.3. Fine tuning implied by astrophysical observation. 4.4. Numerical relations coupled to the concept of scaling. 4.5. Physical cosmology of the closepacked fundamental least unit for an energy dependent spacetime metric. 4.6. The formalism for noetic HAM cosmology. 4.7. Transformation of space into time and string tension. 4.8. Alternative derivation of string tension in HAM cosmology. 4.9. Parameters of the spacetime Incursive Oscillator (IO). 4.10. Emergence of 2Branes from inherent spacetime oscillations. 4.11. Summary of noetic spacetime parameters. 4.12. Simplistic computer simulated production of the 2Brane. 4.13. Conclusions  5. Formalizing the ultimate geometry of reality : dimensionality, awareness and arrow of time. 5.1. Introduction. 5.2. Current philosophy of temporal science. 5.3. Complementarity of physical time and observer time. 5.4. The vacuum origin of thermodynamics and entropy. 5.5. Peripheral physical properties related to the observer. 5.6. Introduction to spin exchange compactification dynamics and the permutation of dimensions in the noetic transformation. 5.7. Dirac spherical rotation inherent to the transformation of the fundamental leastunit. 5.8. Preparing the noetic spacetime transformation. 5.9. Developing the line element for noetic superspace. 5.10. Formalizing the noetic group of transformations. 5.11. Final remarks  6. Integration of gravity & electromagnetism in terms of a Dirac polarized vacuum. 6.1. Introduction to fixing the G/EM framework. 6.2. Flat spacetime and a real physical aether. 6.3. General relativity represented as a polarizable vacuum. 6.4. Maxwell's equations extended. 6.5. Possible new consequences of the model. 6.6. Extending Newton's model with inertia and vacuum drag. 6.7. Relativistic Maxwell's equations in complex form. 6.8. Summation and conclusions  7. Redshift/CMBR as intrinsic blackbody cavityQED absorption/emission equilibrium dynamics. 7.1. Introductory cosmological parameters. 7.2. Origin of redshift in nonzero restmass photon anisotropy in photon propagation and the vigier tiredlight hypothesis. 7.3. Weakfield gravitational approach of a finite lightpencil and derivation of the gravitational field of radiation. 7.4. Gravitational action of a light pencil. 7.5. Internal motion structure of the photon. 7.6. Introduction to spin exchange compactification dynamics. 7.7. Blackbody exciplex radiationcosmological constraints. 7.8. Blackbody microcavityQED constraints. 7.9. CMBR energy damping by vacuum conductivity. 7.10. Possible black hole considerations for discussion. 7.11. Size temperature relationship of Kerr black holes. 7.12. Temperature relationship of Dirac QED cavity 'black holes'. 7.13. Spin exchange parameters of spacetimephoton coupling. 7.14. Spontaneous CMBR emission by spacetime cavityQED. 7.15. Possibility of blackbody emission from continuous spacetime compactification. 7.16. New background conditions of the Dirac vacuum. 7.17. Deriving the topological action principle for CMBR emission. 7.18. A putative model of exciplex proton nucleosynthesis. 7.19. Summary and conclusions  8. Implications of multidimensional geometries and measurement. 8.1. Introduction. 8.2. Complexified EM fields in local and nonlocal Minkowski space. 8.3. Complex Minkowski space : implications for physics. 8.4. Complex vector and advanced potentials and Bell's inequality. 8.5. Superluminal vector and scalar potential transformation laws. 8.6. Insights into Dirac and Penrose spinor calculus. 8.7. Conclusions  9. Probability [symbol]1 : an empirical protocol for surmounting quantum uncertainty. 9.1. Introduction  philosophy of phenomenology versus ontology. 9.2. The proper cosmological perspective is key. 9.3. Micromagnetics of spacetime conformation. 9.4. Catastrophe theory and the noetic formalism. 9.5. Protocol for experimentally testing noetic cosmology. 9.6. Introduction to the P[symbol]1 experimental design. 9.7. Conclusions  10. On the possibility of relativistic shockwave effects in observations of quasar luminosity. 10.1. The quasar redshiftdistance interpretation controversy. 10.2. QSOs an issue of the fundamental basis of geometrodynamics. 10.3. Recent refinements of the TitiusBode series as an indicator of a possible new gravitational dynamic. 10.4. Critique of Hubble's law as applied to Doppler expansion. 10.5. The observer and the cosmological principle. 10.6. Some fundamental insights on shock waves. 10.7. New cosmological gravitational shock parameters. 10.8. Hypersonic shock waves. 10.9. Gravitational shock waves. 10.10. Conclusions  11. The bulk implementation of universal scalable quantum computing. 11.1. Introduction  basics of quantum computing. 11.2. Overview of new fundamental parameters. 11.3. The causal separation of phenomenology from ontology. 11.4. Review of angular momentum and PauliDirac spin matrices. 11.5. Noumenal reality versus phenomenology of quantum theory. 11.6. Justification for the incursive noetic model. 11.7. Essential properties of complex noetic 12 space. 11.8. Geometric introduction to the noetic QC ontology. 11.9. Microphysical computation limits : case of relativistic qubits. 11.10. Essential parameters of the incursive oscillator. 11.11. Ontological I/O by superceding quantum uncertainty. 11.12. A twistor approach to the UQC I/O ontology. 11.13. Class II mesoionic xanthines as potential 10qubit quantum computer substrate registers. 11.14. Initialization of mesoionic xanthine registers. 11.15. Conclusions  12. Practical matterwave antiballistic defense shield technologies. 12.1. Introduction  current status of shield technology. 12.2. Overview of new theoretical and physical requirements. 12.3. Critical philosophical considerations on the limits of potentia. 12.4. The shield vacuum. 12.5. What are the required vacuum parameters? 12.6. Domain wall boundary conditions and emission absorption loci for advancedretarded waves. 12.7. Energy increase from Ising model latticegas properties. 12.8. Programming matter through cellular automata. 12.9. Introduction to de Broglie matterwaves. 12.10. Coherent control of standing matterwaves. 12.11. Afterward. 12.12. Summary of the defense shield design parameters  13. Is a differernt search protocol required for success in SETI research? 13.1. On the horns of a dilemma. 13.2. SETI epistemology from the anthropic perspective. 13.3. The Drake equation. 13.4. Brief review of anthropic multiverse parameters. 13.5. Does SETI require a different strategy for success? 13.6
 Theological arguments  Adam given his reckoning versus the cosmological age of the earth. 13.7. Seemingly farout absurd pseudoscientific arguments. 13.8. The Anthropic Principle (AP). 13.9. Calculations for a holographic anthropic multiverse. 13.10. Wave Function of the Universe (WFU). 13.11. Subtractive interferometry. 13.12. New SETI technology  the interdimensional Qtelescope. 13.13. Conclusions contusions and cowardice
 Control code
 613381655
 Dimensions
 other
 Extent
 1 online resource (xxii, 485 pages)
 File format
 unknown
 Form of item
 online
 Isbn
 9789812839312
 Lccn
 2009017158
 Media category
 computer
 Media MARC source
 rdamedia
 Media type code

 c
 Other physical details
 illustrations.
 Quality assurance targets
 unknown
 Sound
 unknown sound
 Specific material designation
 remote
 System control number
 (OCoLC)613381655
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