| Introduction: General Principles and Approaches in Dynamics | p. 1 |
| Principle of Mutual Reversibility | p. 2 |
| Action and Integral Canonical Pairs | p. 7 |
| Integral Characteristics in the Study of Dynamics of Natural Systems | p. 15 |
| Method of Moments: Specific Features in Integral Approach and First Moments | p. 22 |
| Recent Observations and Understanding Physical Meaning of Jacobi's Virial Equation | p. 31 |
| Dynamical Effects Discovered by Space Study | p. 31 |
| Interpretation of Satellite Orbits and Failure of Hydrostatic Equilibrium of the Earth and the Moon | p. 35 |
| Imbalance Between the Earth's Potential and Kinetic Energy | p. 42 |
| Generalization of Classical Virial Theorem | p. 43 |
| Reduction of Inner Gravitational Field of a Body to the Resultant Envelope of Pressure | p. 50 |
| Derivation of Jacobi's Virial Equation for Description of Dynamics of Natural Systems | p. 57 |
| Derivation of Jacobi's Virial Equation from Newtonian Equations of Motion | p. 58 |
| Derivation of a Generalized Jacobi's Virial Equation for Dissipative Systems | p. 66 |
| Derivation of Jacobi's Virial Equation from Eulerian Equations | p. 69 |
| Derivation of Jacobi's Virial Equation from Hamiltonian Equations | p. 76 |
| Derivation of Jacobi's Virial Equation in Quantum Mechanics | p. 78 |
| General Covariant Form of Jacobi's Virial Equation | p. 86 |
| Relativistic Analogue of Jacobi's Virial Equation | p. 88 |
| Universality of Jacobi's Virial Equation for Description of Dynamics of Natural Systems | p. 91 |
| Solution of Jacobi's Virial Equation for Conservative Systems | p. 93 |
| Solution of Jacobi's Virial Equation in Classical Mechanics | p. 94 |
| The Classical Approach | p. 94 |
| The Dynamic Approach | p. 98 |
| Solution of the N-Body Problem in the Framework of Conservative System | p. 100 |
| Solution of Jacobi's Virial Equation in Hydrodynamics | p. 105 |
| The Hydrodynamic Approach | p. 105 |
| The Virial Approach | p. 109 |
| The Hydrogen Atom as a Quantum Mechanical Analogue of the Two-Body Problem | p. 111 |
| Solution of a Virial Equation in the Theory of Relativity (Static Approach) | p. 119 |
| Perturbed Virial Oscillations of a System | p. 123 |
| Analytical Solution of a Generalized Equation of Virial Oscillations | p. 125 |
| Solution of the Virial Equation for a Dissipative System | p. 132 |
| Solution of the Virial Equation for a System with Friction | p. 135 |
| Relationship Between Jacobi Function and Potential Energy | p. 139 |
| Asymptotic Limit of Simultaneous Collision of Mass Points for a Conservative System | p. 140 |
| Asymptotic Limit of Simultaneous Collision of Mass Points for Non-conservative Systems | p. 142 |
| Asymptotic Limit of Simultaneous Collision of Charged Particles of a System | p. 156 |
| Relationship Between Jacobi Function and Potential Energy for a System with High Symmetry | p. 161 |
| Systems with Spherical Symmetry | p. 162 |
| Polytropic Gas Sphere Model | p. 166 |
| System with Elliptical Symmetry | p. 171 |
| System with Charged Particles | p. 176 |
| Applications in Celestial Mechanics and Geodynamics | p. 183 |
| The Problem of Eigenoscillations of a Celestial Body | p. 184 |
| Hydrostatic Approach | p. 184 |
| Dynamic Approach | p. 189 |
| Structure of Potential and Kinetic Energies of a Non-uniform Body | p. 194 |
| Equations of Dynamical Equilibrium of Oscillation and Rotation of a Body | p. 196 |
| Equations of Oscillation and Rotation of a Body and Their Solution | p. 197 |
| Application of Roche's Tidal Approach for Separation of the Body Shells | p. 201 |
| Physical Meaning of Archimedes and Coriolis Forces and Separation of the Earth's Shells | p. 202 |
| Self-similarity Principle and the Radial Component of a Non-uniform Sphere | p. 203 |
| Charges-Like Motion of Non-uniformities and Tangential Component of the Force Function | p. 205 |
| Radial Distribution of Mass Density and the Body's Inner Force Field | p. 207 |
| Oscillation Frequency and Angular Velocity of the Earth's Shell Rotation | p. 215 |
| Thickness of the Upper Earth's Rotating Shell | p. 216 |
| Oscillation of the Earth's Shells | p. 217 |
| Angular Velocity of Shell Rotation | p. 218 |
| Perturbation Effects Studied on Basis of Dynamic Equilibrium | p. 219 |
| The Nature of Perturbation for Orbital Motion of a Body | p. 219 |
| Change of the Outer Force Field and the Nature of Precession and Nutation | p. 222 |
| Observed Picture of a Body Precession | p. 224 |
| The Nature of Precession and Nutation | p. 224 |
| The Nature of Possible Clockwise Rotation of the Outer Core of the Earth | p. 225 |
| The Nature of the Force Field Potential Change | p. 227 |
| The Nature of the Earth's Orbit Plane Obliquity | p. 227 |
| The Nature of Chandler's Effect of the Earth Pole Wobbling | p. 227 |
| Change in Climate as an Effect of Rotation of the Earth's Shells | p. 228 |
| The Nature of Obliquity of the Earth's Equatorial Plane to the Ecliptic | p. 228 |
| Tidal Interaction of Two Bodies | p. 229 |
| Dynamics of the Earth's Atmosphere and Ocean | p. 230 |
| Derivation of the Virial Equation for the Earth's Atmosphere | p. 231 |
| Non-perturbed Oscillation of the Atmosphere | p. 235 |
| Perturbed Oscillations | p. 238 |
| Resonance Oscillation | p. 242 |
| Observation of the Virial Eigenoscillations of the Earth's Atmosphere | p. 245 |
| Dynamics of the Oceans | p. 253 |
| The Nature of the Weather and Climate Changes | p. 253 |
| Lyapunov Stability of Motion in Jacobi Dynamics | p. 256 |
| Lyapunov Stability of Motion of a System Described in Terms of Co-ordinates and Integral Characteristics | p. 256 |
| Stability of Virial Oscillations According to Lyapunov | p. 263 |
| Stability of Virial Oscillations of Celestial Bodies as Dissipative Systems | p. 266 |
| Creation and Evolution of the Solar System Bodies | p. 267 |
| The Third Kepler's Law as a Kinematics Basis for the Problem Solution of Creation of the Solar System Bodies | p. 268 |
| Evolution by Radiation and Gravitational Contraction of a Gaseous Sphere | p. 274 |
| Equilibrium Boundary Conditions for a Gravitating Gaseous Sphere | p. 275 |
| Velocity of Gravitational Contraction of a Gaseous Sphere | p. 277 |
| The Luminosity-Mass Relationship | p. 283 |
| Bifurcation of a Dissipative System | p. 285 |
| Cosmo-Chemical Effects | p. 288 |
| Direct Derivation of the Equation of Virial Oscillation from Einstein's Equation | p. 291 |
| The Nature of Electromagnetic Field of a Celestial Body and Mechanism of Its Energy Generation | p. 297 |
| Electromagnetic Component of the Interacted Masses | p. 298 |
| Potential Energy of the Coulomb Interaction of Mass Particles | p. 300 |
| Emission of Electromagnetic Energy by a Celestial Body as an Electric Dipole | p. 300 |
| Quantum Effects of Generated Electromagnetic Energy | p. 305 |
| The Nature of the Star Emitted Radiation Spectrum | p. 307 |
| Temperature of the Relict Radiation | p. 308 |
| Conclusions | p. 311 |
| References | p. 321 |
| Index | p. 323 |
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