Modular Principle in the Structural organization and Evolution of Electromechanical Objects

“…But the change of the orientation of the active parts significantly affects the electromagnetic, electromechanical and functional properties of EM-structures-descendants. Genetic principles of mutation and structural replication determine the principles of structural synthesis of multi-element electric machines and electromechanical devices of modular design [14], [15], [16].…”

“…In synthesis algorithms the homeomorphism of chromosomes (14) is realized by procedures of intergeneric chromosomal mutations which leads in changing of the Generic geometry of the corresponding chromosome within a given topological space. The genetically admissible set of intergeneric chromosomal mutations is theoretically determined by the combinatorial space of chromosomes of group 2.2 and is practically limited by their possibility of technical realization of structures-descendants.…”

“…The use of a group of topologically equivalent transformations (continuous deformations) allows the transition from the spatial geometry of the structure of one Genus to the spatial forms of other Homologous Genus. Therefore, the procedures for the synthesis of homologous EM-structures according to model (14) acquire the status of intergeneric mutations which are directly related to the change of the first component of the genetic information of the genetic code. This once again confirms the conclusion about the structural evolution of electromechanical objects occurs not only on the principle of heredity (i.e.…”

Genetic Organization and Evolution of Electromechanical Objects with Adaptive Geometry of Active Zone

“…But the change of the orientation of the active parts significantly affects the electromagnetic, electromechanical and functional properties of EM-structures-descendants. Genetic principles of mutation and structural replication determine the principles of structural synthesis of multi-element electric machines and electromechanical devices of modular design [14], [15], [16].…”

“…In synthesis algorithms the homeomorphism of chromosomes (14) is realized by procedures of intergeneric chromosomal mutations which leads in changing of the Generic geometry of the corresponding chromosome within a given topological space. The genetically admissible set of intergeneric chromosomal mutations is theoretically determined by the combinatorial space of chromosomes of group 2.2 and is practically limited by their possibility of technical realization of structures-descendants.…”

“…The use of a group of topologically equivalent transformations (continuous deformations) allows the transition from the spatial geometry of the structure of one Genus to the spatial forms of other Homologous Genus. Therefore, the procedures for the synthesis of homologous EM-structures according to model (14) acquire the status of intergeneric mutations which are directly related to the change of the first component of the genetic information of the genetic code. This once again confirms the conclusion about the structural evolution of electromechanical objects occurs not only on the principle of heredity (i.e.…”

Genetic Organization and Evolution of Electromechanical Objects with Adaptive Geometry of Active Zone

“…The main provisions of the chromosomal theory of evolution of electromechanics objects were first summarized in the monograph of 2002 [19]. Models and methods of chromosomal hybridization of EM-structures, further development in the works of students and followers [28][29][30][31]. Its main provisions can be summarized by the following conclusions: hybrid EM objects have a genetic nature, because the basis of their structure determines the system-wide principle of crossing the original (parental) electromagnetic chromosomes, the genetic codes of which differ in the components of genetic information; the function of the systemic carrier of universal genetic codes of electromagnetic chromosomes to be crossed performs the periodic structure of the GC of the primary sources of the electromagnetic field (electromagnetic chromosomes); the systemic basis of the structure formation of hybrid EM-structures fulfills the principle of crossing the components of genetic information, which is modeled by the corresponding interbreeding operator in genetic synthesis procedures; the processes of structural hybridization are modeled at the chromosomal level of the structural organization of EM-objects; in accordance with the principle of genetic information saving, synthesized hybrid electromagnetic chromosomes perform the function of generative in relation to the corresponding hybrid Species of EM-objects; system carriers of information are genetic programs endowed with a predictive function in relation to genetically permissible hybrid classes of EM-structures; arbitrary hybrid chromosome performs the function of generative in relation to the corresponding Specie of hybrid EM-objects; hybridization processes can occur at different levels of structural organization of EM systems: chromosomal, intraspecific, intragenic, intergeneric and intersystemic levels; hybrid descendant structures are endowed with emergent properties, they contain new features that are absent in the original structures; the theoretical basis for the analysis and synthesis of hybrid EM-structures are genetic models of convergent type crossings and methods of genetic combinatorics; the reliability of the theoretical provisions of genetic structure formation and the evolution of hybrid EM objects is checked by the evolutionary experiments.…”

The Principle of Hybridization in the Structural Organization and Evolution of Electromechanics Objects