Eastern European Scientific Journal

Key words: modular structure, hyper-spatial formalism method, hyper-cell, topology of cell, symmetric sections, polytopes of 4D space.

Annotation –The possibilities of hyper-spatial formalism method to identify likely features of cell geometry of the modular 3D structures were discussed.The ways to define the image 4D structure into 3D space and define of its basic topology were considered.

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Ivanov VV, Talanov VM. Obtaining of the probable modular cells of structures crystals of semi-right polytopes of 4D space with one inside the pinnacle of their symmetrical projective 3D images: Successes of Modern Natural Science, 2013, №.7; 78-81.

Ivanov VV, Talanov VM. Obtaining of the probable modular cells of crystal structures from Hypercube of 4D space: Successes of Modern Natural Science, 2013, №.6; 64-67.

Ivanov VV, Talanov VM. Obtaining of the probable modular cells of the crystal structures of polytopes of the 4D space with number of cells not more than sixteen: Successes of Modern Natural Science, 2013, №.6; 68-72.

Ivanov VV, Talanov VM. The identification methods of the image of hypercubic P-cell 4D structure and the valid topological transformation of its shells the most symmetrical 3D projections: Successes of Modern Natural Science, 2013, №.12; 49-53.

Ivanov VV, Talanov VM. Probable manifestations mechanisms of the hyper-cubic P-cells into cellular space of lesser dimension: Successes of Modern Natural Science, 2013, №.12; 53-56.

Ivanov VV, Talanov VM. Possible options for the manifestations of structural peculiarities of the 3D P-cells into 2D square net: Successes of Modern Natural Science, 2013, №.12; 56-60.

Ivanov VV. The possible States of the distribution of the modular structures of crystalline, nano-dimensional and fractal objects into volume of anti-frictional composite materials: Modern High Technologies, 2015, № 5; 16-19.

Ivanov VV. Description of the possible structural states of crystalline and nano-dimensional objects and variants for the nature of their site and size-distributions on the surface of composite material or coating through friction and wear: Modern High Technologies, 2015, № 7; 30-33.

Ivanov VV. The possible States of a modular structures of crystalline, nano-dimensional and fractal objects onto surface of anti-frictional composite coatings: Modern High Technologies, 2015, № 8; 24-27.

Ivanov VV. Methodological basis for predicting the inorganic materials with required properties: Successes of Modern Natural Science, 2015, № 11; 35-43.