Marinov Stefan. Classical Physics. Part 3. High-velocity mechanics

International Publishers East-West, 1981. — 284 p.High-velocity mechanics represents Part Iii of Marinov's enciclopaedic Classical physics wtiich consists of the following five volumes: I. Mathematical apparatus. Ii. Axiomatics. Low-velocity mechanics. Iii. High-velocity mechanics. Iv. Gravimagretlsm. V. Eleclromagnetism. Classical physics is constructed on the Newtonian notions of absolute space and time. The notion "aether" can be considered exclusively as a synonym to the notion "absolute space", being defined as the space in which the center of mass of the universe Is at rest, or the space in which the velocity of light is isotropic. The fundamental aspects of Marinov's absolute space-time theory are elaborated in Part Iii. Within effects of first order in v/c Marinov's theory is identical with Newton's theory. The differences are for effects of second (and higher) order in v/c. Marinov shows that all high-velocity.
light experiments can ba explained if the laboratory velocity of light is taken not in the Newtonian fonm c' = c — vcosѲ, but in the form c' = c'²/(c + vcosѲ), wfiere Ѳ is the angle between the absolute velocity v of the laboratory and th3 direction of light propagation. Almost the half of Part Iii is dedicated to the analysis of experiments giving confirmation of Marinov's absolute space-time theory. A detailed description is given to Marinov's own numerous experiments, the most important of which is the "coupled-mirrors«" experiment with whose help, as a first man in history, in 1973, Marinov succeeded in registering the.
absolute motion of the Earth in a laboratory; in 1975/76 he measured accurately enough the Sun's absolute velocity, obtaining a magnitude 303 km/sec with equatorial coordinates of the apex: declination 23°, right ascension 14h 17m. This experiment shows in the most direct way that Einstein's principle of relativity is invalid. Very important are also the various Marinov's experiments on the rotating disk.Kinematics.
The light clock.
Transformation of coordinates.
The Galilean transformation.
The Lorentz transformation.
The Marinov trasnformation.
Group properties of the Marinov transformation.
Transformation of velocities.
The Galilean transformation.
The Lorentz transformation.
The Marinov transformation.
Transformation of accelerations.
The Galilean transformation.
The Lorentz transformation.
The Marinov transformation.
Space intervals.
Emission, reception, and middle distances.
Advanced, retarded, and observation distances.
The proper distance.
Tine intervals. Kinematic (Lorentz) time dilation.
The twin paradox.
Slow transfer of clocks.
Kinematics in the 4-space.
4-space.
Transformation of coordinates in the 4-space.
Transformation of velocities in the 4-space.
4- vectors.
4- tensors.
Fundamental 4-vector equations.
4-interval.
The light cone.
4-radius vector.
4-velocity.
4-acceleration.
4-super-acceleration.
Application of the fundamental 4-vector equations for particle 4-vectors.
Equations of motion.
Establishment of the form of time energy.
The fundamental equations of motion.
The fundamental equations in gravimagretism.
The fundamental equations in electromagnetism.
The Newton-Mar inov equation.
The Newton-Lorentz equation.
The Lagrange equations.
Kinetic and potential forces.
The laboratory fundamental equations of motion.
Gravimagretism.
Electromagnetism.
Mechanics.
Laws of conservation.
Energy and momentum (4-momentum).
Action.
4-angular momentum.
Canonical equations.
Hamilton's equations.
Hamilton-Jacobi 's equation.
Particles and waves.
The de Broglie relations.
The Heisenberg uncertainty relations.
Massive and massless particles.
Collisions.
Disintegration of particles.
Inelastic collision of particles.
Elastic collision of particles.
Description in the 1 -frame.
Description in the c-frame.
Graphical presentation.
The Compton effect.
The Mbssbauer effect.
The velocity mass increase is a Newtonian phenomenon.
Kinematics of light.
Kinematic frequency and wavelength shifts (the Doppler effect).
Source and observer both at rest.
Source moving, observer at rest.
Source at rest, observer moving.
Source and observer both moving.
4-dimensional treatment.
The equivalence of Compton and Doppler effects.
Aberration (the Bradley effect).
Propagation of light in a medium.
Medium and observer both at rest.
Medium moving, observer at rest (the Fizeau effect).
Medium at rest, observer moving (the Dufour effect).
Medium and observer both moving (the Marinov effect).
Application of the Lorentz transfprmation.
Phenomena on the boundary of two media.
Reflection.
Refraction.
Drag aberration (the Jones effect).
Relation between refractive index and density.
The absolute character of motion.
The Marinov and Einstein forms of the proper quantities.
The first-order in V/c effects.
The second-order in V/c effects.
The relativity treatment.
The "rotating disk" experiment.
The "rotating axle" experiments.
The Michel son experiment.
The convection of light as a kinematic phenomenon.
The interaction of particles with fields considered as elastic collision.
The experimental evidence for the space-time absoluteness.
The quasi-Romer experiment.
The quasi -Bradley experiment.
The quasi-Doppler experiment.
The experiments for measurement of the two-way light velocity.
The Fizeau "rotating cog-wheel" experiment.
The Foucault "rotating mirror" experiment.
The flichelson experiment.
The Michel son-Mori ey experiment.
The Michel son-Marinov experiment.
The quasi-Fizeu "coupled shutters" experiment.
The "coupled shutters" experiment.
The "uncoupled shutters" experiment.
The absolute "coupled shutters" experiment.
The differential "coupled shutters" experiment.
The quasi -Foucault "coupled mirrors" experiment.
The deviative "coupled mirrors" experiment.
The oscilloscopic "coupled mirrors" experiment.
The oscilloscopic "coupled shutters" experiment.
The Marinov "coupled mirrors" experiment.
General remarks.
The interferometric "coupled mirrors" experiment.
Improved version of the interferometric "coupled mirrors" experiment.
The interferometric "coupled mirrors" experiment with neutrons.
The accelerated "coupled mirrors" experiment.
The experiments with sound synchronization.
The propagation of sound.
The ultrasonic "coupled shutters" experiment.
Improved version of the ultrasonic "coupled shutters" experiment.
The kinematic time dilation experiments.
The Rossi-Hall "meson" experiment.
Relativistic and absolute treatment of the "meson" experiment.
The Hafele-Keating "clocks-round-the-world" experiment.
The "antipodal clocks" experiment.
The time dilation of a spring clock.
The "synchronous light clocks" experiment.
The "drag-of-light" experiments.
The first-order in v/c effects.
The Marinov "water tube" experiment.
The second-order in v/c effects.
The "drag aberration" experiments.
The Jones experiment.
The Airy experiment.
The "rotating disk" experiment.
General remarks.
The Harress-Dufour experiment.
The Harress-Fizeau experiment.
The Harress-Marinov experiment.
The Harress-Sagnac experiment.
Karinov's performance of the Harress-Dufour and Harress-Fizeau experiments.
The inertial "rotating disk" experiment.
The "rotating disk" experiment with neutrons.
The interrupted "rotating disk" experiment.
The "coupled shutters on a rotating disk" experiment.
The second-order effects in the "rotating disk" experiments.
General remarks.
The Harress-Dufour experiment.
The Harress-Fizeau experiment.
The Harress-Karinov experiment.
The Harress-Sagnac experiment.
Connection with kinematic time dilation.
The "moving platform" experiment.
General remarks.
The Zeeman-Fizeau experiment.
The Zeeman-Dufour experiment.
The Zeeman-Marinov experiment.
The Zeeman-Sagnac experiment.
The non-inertial "moving platform" experiment.
The light Doppler-effect experiment.
The Ives-Stilwell longitudinal "canal ray" experiment.
The transverse "canal ray" experiment.
The Hay "rotor" experiment.
The "rotor- rotor" experiment.
The Santos experiment.
The quasi-Wiener "standing waves" experiment.
The "coherent lasers" experiment.
General remarks.
The inertial "coherent lasers" experiment.
The "coherent lasers on a rotating disk" experiment.
The relationship betv/een the "coherent lasers" and light Doppler-effect.
experiments.
The "wired photocells" experinient.
The inertial "wired photocells" experiment.
The "aether wind" effect.
The effect of the anisotropy of the radiation from a moving source.
The "wired photocells on a rotating disk" experiment.
The "synchrotron" experiment.