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With the available data in planets, stars and galaxies, it is studied the functions of angular momenta J(M) and amounts of action A,(M) (associated to the non rotational terms in the kinetic energy). The results indicate that independently of how are these functions J(M), A,(M) their ratio A,IJ remains a near invariant. It is independent also from the type of angular momenta: intrinsic "spins" of the bodies or the total angular (orbital) momenta of the bodies forming a system; for instance, the Solar System and the planets.The relation A,(M) for the Solar System are analogous to these in the FGK stars of the main sequence, and the relation .7(M) (also for the Solar System) is analogous to the lower possible limit for binary stars.The different types of binary stars from the short period, detached systems to contactary systems, gives a range of functions J(M), A,(M) that are the same that one can expect in stars with planetary systems. According to the detection limits given for planetary companions by Campbell, Walker and Yang (1988) (masses of less than 9 Jupiter masses and orbital periods of less than 50 years) we calculate the limits for J(M) and A,(M) This gives a lower limit A,/J 3 1 associated to stars with planetary systems as 61 Cygni and to short period detached binaries. The upper limit A,IJ% 16 correspond to planetary systems as the ours and probably to cataclysmic binaries. There are reasons to suspect that systems as the ours and in range 4 s AC/J G 16 (with a lower limit analogous to contactary binaries as Algols and W Ursa Majoris) must be the most common type of planetary systems. The analogies with the functions J(M) A,(M) for galaxies suggest cosmogonical conditions in the stellar formation.Independently of this, one can have boundary conditions for the Jacobi problem when applied to a collapsing cloud. Namely, from the initial stage (a molecular cloud) to the final stage (a formed stellar system: binary or planetary) the angular momenta and amounts of action decayed to 10m4 the initial values, but in such a form that A,(t)/J(t) remains a near invariant.
With the available data in planets, stars and galaxies, it is studied the functions of angular momenta J(M) and amounts of action A,(M) (associated to the non rotational terms in the kinetic energy). The results indicate that independently of how are these functions J(M), A,(M) their ratio A,IJ remains a near invariant. It is independent also from the type of angular momenta: intrinsic "spins" of the bodies or the total angular (orbital) momenta of the bodies forming a system; for instance, the Solar System and the planets.The relation A,(M) for the Solar System are analogous to these in the FGK stars of the main sequence, and the relation .7(M) (also for the Solar System) is analogous to the lower possible limit for binary stars.The different types of binary stars from the short period, detached systems to contactary systems, gives a range of functions J(M), A,(M) that are the same that one can expect in stars with planetary systems. According to the detection limits given for planetary companions by Campbell, Walker and Yang (1988) (masses of less than 9 Jupiter masses and orbital periods of less than 50 years) we calculate the limits for J(M) and A,(M) This gives a lower limit A,/J 3 1 associated to stars with planetary systems as 61 Cygni and to short period detached binaries. The upper limit A,IJ% 16 correspond to planetary systems as the ours and probably to cataclysmic binaries. There are reasons to suspect that systems as the ours and in range 4 s AC/J G 16 (with a lower limit analogous to contactary binaries as Algols and W Ursa Majoris) must be the most common type of planetary systems. The analogies with the functions J(M) A,(M) for galaxies suggest cosmogonical conditions in the stellar formation.Independently of this, one can have boundary conditions for the Jacobi problem when applied to a collapsing cloud. Namely, from the initial stage (a molecular cloud) to the final stage (a formed stellar system: binary or planetary) the angular momenta and amounts of action decayed to 10m4 the initial values, but in such a form that A,(t)/J(t) remains a near invariant.
The explanation of dependencies of the parameters of the stars and the Sun which was measured by astronomers is considered as a main task of the physics of stars. This theory is based on taking into account of the existence of a gravityinduced electric polarization of intra-stellar plasma because this plasma is an electrically polarized substance. The accounting of the gravity-induced electric polarization gives the explanation to data of astronomical measurements: the temperatureradius-mass-luminosity relations, the spectra of seismic oscillations of the Sun, distribution of stars on their masses, magnetic fields of stars and etc. The stellar radiuses, masses and temperatures are expressed by the corresponding ratios of the fundamental constants, and individuality of stars are determined by two parameters -by the charge and mass numbers of nuclei, from which a stellar plasma is composed. This theory is the lack of a collapse in the final stage of the star development, as well as "black holes" that could be results from a such collapse.
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