We propose a structural scheme for the origin and unfolding of the large solar cycle as a group of physical phenomena that are registered on the surface of the Sun and include the so-called 11-year and 27-day (Carringtonian) cycles of solar activity. The model considerations are quite general because they exclude the specifics of natural systems; physical laws are not used; only the structural aspect is studied. The basis for consideration is the protostructure, i.e. according to the conception, a primary system of relations, which is considered on the numerical axis. The system is represented as a network consisting of nodes, or allowed states, and links, i.e. rules responsible for stability, both of which are set by the protostructure. An order parameter, n, or hierarchically the most significant characteristic of the system, is formed on the basis of two additional relative characteristics. The order parameter and shifts of its positions relative to the initial positions are the basis for the analysis of structural events.
The protostructure has previously been used to analyze the structure of the solar system in the ecliptic plane, where the role of the order parameter, n, is played by the relative angular momentum. In particular, the stages of the Sun’s burning from initial mass to the currently known mass, as well as the relationship of mass with the minimum radius of the Sun and the eccentricity of the Earth’s orbit have been investigated. The nodal complex responsible for the formation of the observed characteristics of the great solar cycle, Halley’s Comet, the asteroid belt, and the Chiron body was also identified. The analyses of already available model constructions, as well as the involvement of several hypotheses allow us to combine these results and present a set of structural scenarios describing the emergence and unfolding of the great solar cycle from its formation to the present. At present, the observed solar radius is 4.649*10-3a.u. When the model solar radius changes within the range of (4
Идентификаторы и классификаторы
Characterization of the situation. The solar system is studied in different fields of knowledge, but the analysis of solar activity [2] is dominated by phenomenology. At present [2], the urgent task is to explain the large solar cycle, a set of physical phenomena registered at the solar surface and including the so-called hidden 11-year and 27-day (Carringtonian) cycles of solar activity. At the same time, on the one hand, the physical models deal with isolated problems and are not sufficiently definite; and on the other hand, there is an opportunity to consider the structural aspect of these phenomena from the positions of [14, 16, 4] in a sufficiently broad context.
Previous results. To study the processes of evolution in a system, which is not endowed with specificity of concrete objects, a protostructure, i.e. a presumably primary system of relations, consisting of cycles and is represented on the numerical axis, has been proposed [4]. On the basis of the protostructure, which defines nodes, or allowed states, the so-called system order parameter, n, was formed [5]; hierarchically, it is its most significant relative characteristic. Within a cycle n, the 1:10 positions are assigned to numbers k=1-10; the normalization to k=3 was chosen as convenient for the application. The protostructure model [5 - 12] given in the appendix allows us to analyze in the ecliptic plane various aspects of the Solar System structure, where the role of n is played by the relative momentum, an important [13] characteristic of several natural systems; the role of k=3 is played by the Earth, for example m3 is the Earth mass, and r3=a.e.
Список литературы
- Alfven H., Arrhenius G. Evolution of the Solar System. – NASA Sp-345, Washington, D.C. – 1976.
- Ivanov-Holodnyj G.S., Chertoprud V.E. Solnechnaja aktivnost’ [Solar activity]. Itogi nauki i tehniki. Ser. Issledovanie kosmicheskogo prostranstva [Results of science and technology. Ser. Space exploration]. M.:VINITI AN SSSR, 1990. Vol. 33. P. 3-99.
- Minsky M. Frames for knowledge representation. N.Y.: Ed. H. Winston, McGraw-Hill, 1975. 76 p.
- Smirnov V.L. Analysis of Discrete Spectra of Evolution Paths for Various Complex Systems. Slozhnye sistemy [Science of complexity]. 2016. No 2 (19). Р.70-83.
- Smirnov V.L. Orderparameter Derivation from Evolution of Non-Spesific Complex Sistem. Slozhnye sistemy [Science of complexity]. 2016. No. 3 (20). P. 79-92.
- Smirnov V.L. Formation of a Complex During Evolution of a Complex Self-Organized System. Slozhnye sistemy [Science of complexity]. 2016. No. 4(21). P. 72-85.
- Smirnov V.L. Interpretation of a Complex Formed in Complex Self-Organized System. Slozhnye sistemy [Science of complexity]. 2016. No. 4(21). P. 86-98.
- Smirnov V.L. Instabilities in the Allowed State Spectrum of a Self-Organized System. Part I. Slozhnye sistemy [Science of complexity]. 2017. No 1(22). P. 65-79.
- Smirnov V.L. Formation of 1/137 Invariant During Evolution of Non-Specific Complex Structure. Slozhnye sistemy [Science of complexity]. 2017. No.4 (25). P. 43-56.
- Smirnov V.L. Evolution of Two Elements of Allowed States Range in Non-Specific Complex System. Slozhnye sistemy [Science of complexity]. 2017. No. 4 (25). P. 57-72.
- Smirnov V.L. Formation of Extreme Speed During the Evolution of Abstract Rtlationship System. Slozhnye sistemy [Science of complexity]. 2020. No. 2(35). P. 31-48.
- Smirnov V.L. Evolution of the leading scale coefficient in abstract system of relations. Slozhnye sistemy [Science of complexity]. 2020. No. 3 (36). P. 54-73.
- Feynman R. The Character of physical laws. A series of lectures recorded by the ВВС at Cornell University USA. L.: Cox and Wyman LTD, 1965. 173 p.
- Haken H. Synergetics. N. Y.: Springer-Verlag, 1983. 356 p.
- Saxena P., Killen R.M., Airapetian V., Petro N.E., Curran N.M., and Mande A.M. Was the Sun a Slow Rotator? Sodium and Potassium Constraints from the Lunar Regolith. The Astrophysical Journal Letters, 876:L16 (10pp), 2019 May 1.
- Haken H., Knyazeva H. Arbitrariness in Nature: Synergetics and Evolutionary Laws of Prohibition // Journal for General Philosophy of Science. – 2000. – Vol.31. – No. 1. – P. 57-73.
Выпуск
- A structural scheme for the origin and development of the Big Solar Cycle is proposed;
- We propose a simple explanation for inertial and non-inertial reference systems, inertial forces and inertial motion of bodies;
- Regularities of a production system development are discussed;
- Artificial acoustical impact inside natural clouds, in particular inside the non-precipitated stratiform clouds, non-precipitating shallow cumulus clouds, and Cu-clouds with drizzle, were analyzed;
- An original method for replacing a large number of pixel blocks in the source image by a relatively small number of the most suitable specially created domain blocks is developed;
- The problems associated with the disposal of different types of autonomous mobile robots are analyzed.
Другие статьи выпуска
Widespread introduction of mobile robotics in various spheres of human activity
makes the problem of mass disposal of expired, outdated and faulty robots topical. When disposing of
each type of mobile robots, it is necessary to take into account peculiarities of its design, composition
of on-board equipment and take into account environmental risks in case of destruction of the robot
structure with its fragments getting into the environment. Depending on the type and purpose of
robots, their disposal and recycling have significant features. This paper analyzes the problems
associated with the disposal of different types of autonomous mobile robots. The main sources of
environmental pollution present in the components of robots: electronic components, accumulator
batteries, constructional materials, connecting cables are considered. The environmental impact of
different types of mobile robots and the prevailing types of waste during their disposal are determined.
Widespread introduction of mobile robotics in various spheres of human activity
makes the problem of mass disposal of expired, outdated and faulty robots topical. When disposing of each type of mobile robots, it is necessary to take into account peculiarities of its design, composition of on-board equipment and take into account environmental risks in case of destruction of the robot structure with its fragments getting into the environment. Depending on the type and purpose of robots, their disposal and recycling have significant features. This paper analyzes the problems associated with the disposal of different types of autonomous mobile robots. The main sources of environmental pollution present in the components of robots: electronic components, accumulator batteries, constructional materials, connecting cables are considered. The environmental impact of different types of mobile robots and the prevailing types of waste during their disposal are determined.
Widespread introduction of mobile robotics in various spheres of human activity
makes the problem of mass disposal of expired, outdated and faulty robots topical. When disposing of each type of mobile robots, it is necessary to take into account peculiarities of its design, composition of on-board equipment and take into account environmental risks in case of destruction of the robot structure with its fragments getting into the environment. Depending on the type and purpose of robots, their disposal and recycling have significant features. This paper analyzes the problems associated with the disposal of different types of autonomous mobile robots. The main sources of environmental pollution present in the components of robots: electronic components, accumulator batteries, constructional materials, connecting cables are considered. The environmental impact of different types of mobile robots and the prevailing types of waste during their disposal are determined.
Widespread introduction of mobile robotics in various spheres of human activity
makes the problem of mass disposal of expired, outdated and faulty robots topical. When disposing of each type of mobile robots, it is necessary to take into account peculiarities of its design, composition of on-board equipment and take into account environmental risks in case of destruction of the robot structure with its fragments getting into the environment. Depending on the type and purpose of robots, their disposal and recycling have significant features. This paper analyzes the problems associated with the disposal of different types of autonomous mobile robots. The main sources of environmental pollution present in the components of robots: electronic components, accumulator batteries, constructional materials, connecting cables are considered. The environmental impact of different types of mobile robots and the prevailing types of waste during their disposal are determined.
The following goals were set within the scientific work: to create a method, an
algorithm and a program for compression of raster (pixel) graphic information using special
mathematical methods, or affine transformations. The main task was to provide a high degree of image compression with a minimum deterioration of image quality. An original method for replacing a large number of pixel blocks in the source image by a relatively small number of the most suitable specially created domain blocks was developed. Affine transformation consists in moving any domain block from a set to any part of the image, while ensuring maximum similarity of source and domain blocks.
To implement the method, an algorithm and a program in the modern and popular Python language have been developed. We have considered the example of image transformation in grayscale of 256x256 pixels using domain blocks created from 4x4 pixel image areas. The result is an image visually indistinguishable from the original image, which requires only 0.3125 of the original information to describe. Calculations were also performed with a smaller number of domain blocks.
The developed method and program proved a high degree of compression of bitmap images with preservation of their quality. It is possible to further improve the described algorithm and the program presented on the author’s site by simultaneous application of different types of affine transformations.
It is shown that the same method can be used not only for image processing, but also for the detection of similarity (fractal properties) in any flow of information.
This paper analyzes artificial acoustical impact inside natural clouds, in particular inside the non-precipitated stratiform clouds, non-precipitating shallow cumulus clouds, and Cu-clouds with drizzle. Optimal power and frequency for acoustical impact were indicated based on properties of natural cloud, such as liquid water content, droplet concentrations, and the average diameter size of a droplet ensemble followed by lognormal or gamma size distributions in the presented consideration. The model is constructed to ensure collisions of neighboring droplets when they vibrate in acoustical field to merge with mass unification, but the process is designed with a minimum required level of acoustic power for comfort realization in practice. Vibration model of suspended droplets with typical size in cloud is analyzed. The optimized acoustic power is near 130 dB, and frequency f 50 – 100 Hz, and detailed characteristics are indicated for each cloud type depending on their parameters. Simple formulas and typical calculations for droplet amplitude are presented in terms of parameters of acoustical field as well as cloud characteristics. The first low-frequency acoustic experiments for clouds are performed and presented. The low-frequency method has shown a promising potential to be used for precipitation enhancement to tackle water shortage problem in the modern world.
Regularities of a production system development are discussed on the basis of the notion that progress in human economic activity is related to advances in the technological use of human effort and energy sources, which are regarded as the most important societal production resources. The concept of substitutive work of equipment P is introduced, which in all respects is equivalent to the efforts of people in production; it can be considered a service of capital, and is regarded as a value-forming factor, along with the traditional production factors. System output (value production) is defined as a function of three variables, two of which are: labour L and substitutive work P, are regarded as active sources of value, which allows us to introduce an energy measure of value, while physical capital K, as a production factor, plays a passive role. Under the assumption that the production system seeks to use all available social resources defined by circumstances external to the system, equations for production factors are formulated; they are also accompanied by equations for the technological characteristics of production equipment. The trajectory of the system development is determined by the characteristics of the system itself and the availability of social resources, which cannot be used completely simultaneously, which leads to a change of modes of development and fluctuations in output, i.e. business cycles. Using the example of the U.S. economy, it is demonstrated that the system of equations is able to describe the observed trajectory of development and output of the production system.
A simple explanation of the most mysterious classical mechanics and theoretical physics concepts - inertial and non-inertial reference systems, the forces of inertia, the motion of bodies by inertia on the basis of a simple vortex model of solids and D’Alembert’s paradox, as well as on the equilibrium conditions of incompressible fluid and the principle of attached masses for potential flows are proposed. A new interpretation of Newton’s three laws is presented on the basis of the resulting model.
Издательство
- Издательство
- ИФСИ
- Регион
- Россия, Москва
- Почтовый адрес
- 140080, Московская область, г. Лыткарино, ул. Парковая, Д. 1, офис 14/А
- Юр. адрес
- 140080, Московская область, г. Лыткарино, ул. Парковая, Д. 1, офис 14/А
- ФИО
- Старцев Вадим Валерьевич (ГЕНЕРАЛЬНЫЙ ДИРЕКТОР)
- E-mail адрес
- systemology@yandex.ru
- Контактный телефон
- +7 (963) 7123301