Exact solution to the problem of N bodies forming a multi-layer rotating structure

Smulsky, Joseph J.

doi:10.1186/s40064-015-1141-1

Cited by 6 publications

(7 citation statements)

References 17 publications

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“…Also, J.J. Smulsky has analytically exactly solved some previously unsolved N-body problems, including the following ones: what motions are exercised by bodies on a ring [7]? Can a system of bodies involving several of rings rotate as an entity [8]? Those and other exact solutions have allowed J.J. Smulsky to solve several previously unsolved problems: about an optimum mission to the Sun [9], about the motion of Mercury's perihelion [10], about the evolution of the Earth axis [11,12], and so forth.…”

Section: Forewordmentioning

confidence: 99%

“…The structures were obtained by integration of differential motion equations performed using the Galactica program: N 2 = 15; N 3 = 30; period P rd =1 year; the mass of the central body is equal to the Sun mass. Given in the table are the relative radii of the rings and the masses of one body in the rings[8].Here (Fig. 5), results of an exact solution of the problem of N-bodies located in N 2 layers around a central body are shown.…”

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confidence: 99%

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Computing the Bodies Motions in the Space and Long-term Changes in the Earth's Climate

Smulsky¹

2019

IJMECS

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The paper considers various aspects of the interaction and movement of bodies. The stability of the Solar system by the example of the evolution of the Mars orbit for 100 million years is shown. The optimal motion of the spacecraft to the vicinity of the Sun is considered. The results of an exact solution to the problem of the interaction of N bodies, which form a rotating structure, are presented. It is shown the evolution of two asteroids: Apophis and 1950DA, as well as ways to transform them into Earth satellites. The cause of the excess rotation of the Mercury perihelion is explained. The examples of the simulation of globular star clusters are given. As a result of the interaction of the bodies of the Solar System, the parameters of the orbital and rotational motions of the Earth change. This change leads to a change in the distribution of solar heat over the surface of the Earth. In contrast to the works of previous authors, a new understanding of the evolution of the orbital and rotational motions of the Earth has been obtained. In particular, it has been established that the Earth's orbit and its axis of rotation precess relative to different directions in space. The paper compares the distribution of the amount of the solar heat, i.e. insolation, on the surface of the Earth in different epochs. The insolation periods of climate change are shown. They coincide with the known changes of the paleoclimate. The changes in insolation for different time intervals, including for 20 million years ago, are given. Changes in insolation in the contemporary epoch and in the next million years are also shown. Sunrises and sunsets are also evolving. The duration of the polar days and nights in different epochs is given in the distribution by latitude. The paper popularly acquaints readers with the latest scientific results and is useful for students and graduate students to choose topics for their term papers and dissertations.

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Section: Forewordmentioning

confidence: 99%

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confidence: 99%

Computing the Bodies Motions in the Space and Long-term Changes in the Earth's Climate

Smulsky¹

2019

IJMECS

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“…The layers are counted from the center, and the bodies in each layer are counted from the x o axis. Such notation permits an easy determination of the distances between any two bodies and the angle between their central radii [20]. Such analysis of the problem has allowed us to write the following simple expression for the force of impact of bodies on one first body in the j-th layer: …”

Section: Multi-layer Rotating Structures Involving N Bodiesmentioning

confidence: 99%

“…For constructing the rotating systems, a program RtCrcSt2.for was developed [20]; this program can be accessed at www.ikz.ru/~smulski/Data/RtCrcStr/. Structures with different total numbers of layers N 2 and with different total numbers of bodies in the layers N 3 were obtained.…”

Section: Multi-layer Rotating Structures Involving N Bodiesmentioning

confidence: 99%

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Advances in Mechanics and Outlook for Future Mankind Progress

Smulsky¹

2017

IJMECS

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Abstract-Three problems for the interaction between N bodies to which exact solutions were obtained are discussed. In the first problem, the bodies are located axisymmetrically in a plane. Possible trajectories of the bodies here are ellipses, parabolas, hyperbolas, or straight lines. Results of solving this problem are further used for solving problems about Earth's rotation and Mercury's perihelion. In the second problem, the body system consists of several layers, and it rotates as an entity. In the third problem, the bodies are uniformly distributed over a sphere, and they move experiencing no mutual collisions. The latter problem allows the formation of several planets, for instance, one hundred planets resembling the Earth and moving under identical conditions with respect to the Sun. The latter possibility opens a way toward unrestricted mankind progress.

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Periodic Orbits of N Bodies on a Sphere

Smulsky

2019

Cosmic Res

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Exact solution to the problem of N bodies forming a multi-layer rotating structure

Cited by 6 publications

References 17 publications

Computing the Bodies Motions in the Space and Long-term Changes in the Earth's Climate

Computing the Bodies Motions in the Space and Long-term Changes in the Earth's Climate

Advances in Mechanics and Outlook for Future Mankind Progress

Periodic Orbits of N Bodies on a Sphere

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