WO2014181004A1 - Family of circulatory, labyrinthine and modulated systems of circuits - Google Patents

Abstract

The invention relates to a family of systems of labyrinthine and modulated circuits which can be material and computer-simulated, consisting of individual circulatory systems formed by two-dimensional or three-dimensional complementary modules made of a material support of a transparent quality, representing derivations of a translucent, non-transparent, reflective and mixed quality; systems used as boards and platforms for after-dinner games (representative utility), and as sectorial arrangements of competition spaces of a variable scale and tabletop games acting as same, and applications for computers, consoles, mobile telephones, and the like. A close relation of the family is the family of systems to which boards of the traditional games of parchis and chaupar pertain and of which they consist.

Description

 Family of circulatory, labyrinth and modulated circuit systems

-Sector of the Technique:

 International Patent Classification

G06T17 / +

G06T15 / +

G06T19 / +

A63F3 / +

A63F3 / 00

A63F3 / 02

A63F 13/00

 European Patent Classification

G06T17 / 00

G06T19 / 00

A63F3 / 00B3

A63F3 / 00A16

A63F3 / 00L

A63F3 / 02H1 - State of the art:

-The Spanish utility model document ES1012023 U (B ESPAÑA, SA) introduces a desktop game suitable for 2 or more players comprising a board, dice and chips, being the board of the type in which one box is represented by which advance the chips according to the score obtained by the dice and that presents the novelty of understanding some rotating panels that allow changing the course of the chips, thus making the game more difficult. -The Spanish patent document ES2023610 A6 (GOULA, SA) describes, in a similar way to the previous document, a tabletop game board equipped with a path intercepted by rotating disks with sections that can adopt different positions, thus varying the course of travel- . -The document of Spanish utility model ES1070778 U (GERMAN HERNAN VELAZQUEZ) describes a type of parquet board made in such a way that each of the numbered squares that compose it at different height levels is arranged by stepped, either this ascending, descending or a combination in both directions, achieving a three-dimensional effect. -The Spanish patent document ES2130989 A1 (JUAN MANUEL LOSADA) presents a system that from a plurality of piesas assembled together as a puzie allows to form different boards of parchís depending on the number of participants-. US patent document US 51 08111 A (EUGENE BILODEAU) expresses a type of unmodulated two-dimensional circulatory system, monocyclic, multi modal, for infantile use, formed of circulating ducts intersecting compounds of consecutive squares some of them marked with arrows susceptible to vary the address that they point out according to regulations-. US patent document US8079594 B1 (THO AS H. GREENAWALT) discloses a type of circuit game rack arranged in tiers or floors whose ducts connect and disconnect flow paths by rotating pivoting elements actuated by knob-setting. -The document US7766335 B1 (THOMAS H. GRENNAWALT) also refers to a circulatory system at levels, of multiple segmented conduits including dynamic routes, whose transit is affected by hindering of pivoting discs, which depending on its turn operated by knob, directs the transit to certain deviations. US patent document US2002089121 A1 (ALVIN L. BJORNSON) presents a labyrinthine circulatory system of interconnected segmented conduits, composed of a plurality of square boards that are laterally connected to each other by activating or deactivating conduits that end in the center of the sides of the board , according to the position in which it pivots from its central point and as each board relates to the others. - US patent document US2011163500 (WEISTECH TECHNOLOGY CO. LTD.) Describes a system of three-dimensional structure, which corresponds to the application of a monopoly game modality, which has areas where replaceable educational information and a set of levels are provided. where information of travel areas is provided. It comprises an electronic device that provides visual and sound effects. US patent document US7527266 B1 (DOMINIO LAITI) refers to a labyrinthine circulatory system, such as the installed one of several game stations in a play area and multiple rotary locking elements of revolving doors arranged in groups of 3, which revolve around a pivot that is placed in 4 joints of the game stations.

-Descriptive memory:

 "Family of circulatory, labyrinthine and modulated circuit systems", materially feasible and in computer simulations, composed of lineages of individual circulatory systems structurally shaped by complementary modules bi, or three-dimensional invoices in material structure of -quality transparent-, representative of derivations of translucent quality, non-transparent, reflective and of mixtures; useful systems such as boards and platforms for desktop games (representative utility), and as sectoral orderings of competition tracks and board games that serve as these. The family has as its next reference the family of systems of which they are part and which consist of the boards of the traditional parchís and chaupar. The systems are constituted by constant and variable factors.

Constant factors: Circulars systems, constituted by regular unidirectional conduits expressed representatively in the form of sectioned strips that modulate or order in modules the same number of instances that in general keep consecutive, instances that in particular are expressed representatively as a directional moment through the system of conductive codes based on the "arrow" (Figures 1.1, 1.2, 1.3, 3.1, 3.2), their derivatives that mean-crossing of 2 trajectories: in which an instance of both trajectories share a section: (representatively) 2 crossed arrows- (Figures 2.1, 2.2, 2.3, 2.4), -bifurcation- (Figures 4.1, 4.2), and -confluence- (Figures 5.1, 5.2, 5.3); and original icons present according to what in most types of systems, which mean: initial cycle poles (of dynamics systems (: D) - monoccylic (: D3), of mono and polycyclic dynamics according to regulations ( : D4), and of polycyclic dynamics (D5), or waiting table (respective Figures 8, 9, 10), cycle terminal or house (Figure 7), and cyclic record instance (D2) in which line or exit and goal lines (Figures 11, 12, 13) representative of their specular similes, systems of conductive codes adopted, representative of consecutive code systems equally valid as numbering or spelling etc., and combinations or coperations (example: Figures 22, 23, 38, 39) The regular conduits are of 2 types: a -channel channel-of circular character that communicates all the modules and of common route of the cards or circulating agents corresponding by code to each circuit (according to the game mode of the refe rente), and as many - autonomous channels (: arrival boxes) - of each circuit, as a module number, make up each system; autonomous channels that are differentiated with each other with a color, chromatic or color identification code, which come from the common channel from instances marked as bifurcation, and which can lead back to the common channel, also in this instance as confluence, in polycyclic dynamics systems. Regular channels are sectioned naturally giving rise to modulated systems called "primitive" or endowed with irreducible number of modular instances and D1 or continuous rotation, ordered and inscribed in modular sectioned forms (representative of derivative expression forms lacking sections (Representative figures 14, 28, 29), given -the condition- provided by the labyrinthine form, of presenting by module a minimum number such as to show a perceptible effect in the development of a game, estimated at an approximation of 6 (: 5 ¾) - simple crossings of the trajectories of the regular channels by module (: crossings ()) -, in the approach in which two instances appear sharing a same section or box, by physics -intersection- in modules of two-dimensional and three-dimensional transport systems that the report, or in modules of systems of three-dimensional size: by -superposition- of trajectories that take different levels it is observed that they intersect from the zenith point of view, linking 2 instances in a section or box of the transparent modular surface configuration, links in sum that can be assumed as - irregular conduits - that according to the number of dimensional parameters of the system correspond Define which focuses or which conduits of redirection of course and or incidence, whose activation is referred to regulations. This condition is called original conditional order (: OCO) -. -The sections of the regular ducts of the modular surface configuration, are placed at levels in due orderings in the manner of steps and passages in three-dimensional expressions of board games. In types of system of compact or partially distended surface configuration can also be signified as irregular conduits to the instances of different modules but of same identification encrypted in the modular composition and that they find in contact, as the instances identified "5" of modules of types of "gender" bi-modular systems (Figure 23), instances "12" of module of certain types of "gender" poly-modular systems (Figure 35), instances "15A-B" of modules of "versatile" system types of 9 crosses () that report it (Representative Figures 106, 107, 108, 112, 5 113), instances of types of plastic module whose location corresponds where the instances "29A-B" or "29A" and "29B" (representative figures 105, 106, 111, 112) are identified in the types of "plastic" modules of 9 crosses (), of square surface configuration that the one or the reports, and those offered by the coexistence of a system of conductive signs with the coding of modular instances in the expression of quadricular systems except for mono-modular. It should be noted that as well as the types of systems in the family with D1 dynamics , D2, D4 and D5 have in their common channel insta confluence where they receive the flow of autonomous channels, instance type that naturally acts conditionally as a regular focus of incidence; The types of lineage systems called "grid" whose natural dynamics are monocyclic (D3), have instances of confluence but that perceive flow of 2 trajectories of instances5 identified participants of the common channel.

 The immediate deciphering of the location of the stages to be traced by the cards or agents of each circuit, in the labyrinthine network of the common channel, with respect to the corresponding autonomous channels, is offered by means of the resource that involves panels with reading markers diagrams for each module, endowed with as many instruction diagrams as modules count the system, each marked with the characteristic code (: color) of each circuit, indicating the fractional or successive expression, of stages, measured in number of modules, overcome and inherently in it, those that remain to be covered (Figure 6). The family is limited to 4 generic types of resolution of the fundamentals called "lineages" because they have types of polarized circuits systems (: with terminal and initial cycle poles) 5 whose modules are composed of an economic number of instances, this is round the modular composition of the referent (: 26 instances) with up to an upper margin of 6 instances compensated by a higher number of irregular conduits.

Variable factors: -The duplicity of expression that a system presents according to its construction provides the orientation of the circulation of the common channel effectively rotating in one direction or in the opposite, leads to assume: the ambivalent quality of any system: with a disposition of Conductive orientation of the adopted system representative of the other, its mirrorlike reflection (example Figures 15 and 16). Likewise, the adopted approaches or modular forms are assumed: as representative of other formal approaches whose set of complementary similes make up same systems (example Figures 24 and 25, 40, 41, 42 and 43). -According to the number of modules that make up the system: they are generally based on exceptions from bi-modular to octa-modular types, representative of systems made up of a smaller or larger number of modules. For the discrimination according to the number of crosses per module ": the 4 lineages of types of orderings are first discriminated that reflect types of systems that carry the foundations: lineage of system types of 6 crosses module, of 2 genera or "of gender": gender (exclusively) -bi-modular (: BM) - (Representative figures 20, 21), and gender -poly-modular (: PM) - (Representative figures 36, 37); lineage of "quadricular" system types in which mono, bi, tetra and octa-modular systems (representative figures 96, 103) of 10, 6 ½, and averages of 5 ¾ and 9 7/8 crosses (), respectively; lineage of "versatile" module system types of 9 and 10 crosses () (Representative Figures 116, 127); and lineage of types of systems made up of types of modules called "plastics" of 9, 10, 9 ½ and 10 ½ crosses () (representative figures 184, 209, 235). According to the criterion of spatial economy, first of all there are types of configuration systems -substantial surface (: SC) -: (examples: Representative figures 20, 21, 36, 37), in which the fringes in which the regular conduits consist, except Presence of desert space strongholds immanent in systems of 3 of the 4 lineages, are limited longitudinally with each other within the system, more appropriate though not excused for its usefulness in boards or platforms for table games; refers to being the end of a field whose other extreme reference system types of configuration -surface distended (: SD) -, appropriate but not exclusively for its utility as sectoral orderings of competition and related tracks; in which with respect to the compact, the bands narrowing their width inside the system stop limiting with each other, causing the appearance of new instances in section, which reestablish the connection in every situation where a regular channel trajectory before crossed next 2 trajectories in longitudinal contact, now separated. The gender system types - cyclic registration primitives - (Figures 60, 61, 62, 63, 65, 66, 67, 68) of 6-cross modules () of SD configuration, are representative of the other types of systems its surface configuration and the range of types of partially relaxed surface configuration systems. In the sectorial arrangements of three-dimensional racing and related tracks, the change of levels proceeds in the manner of ramps. -According to number of instances make up the module: in the types of module of primitive systems, the sections that appear disproportionately long, are offered to be divided into new sections more proportionate with respect to the general, figuring in general up to module types saturated of sections provided called -Patron- to serve as a basis for the registration of module types from the primitive of their lineage to it; representative also of similar expressions with greater number of instances. Instances, discounting those involved in trajectory crossings, can be highlighted with codes that indicate conditions such as -seguros- expressing themselves as a segmented arrow (Figures 3.1, 3.2), which are optionally adopted as a complement to the shared coincidences with -the type of polarized circuit systems in which the family includes the "Parchís" of 26 modular instances (: 17 in the common channel and 9 in the autonomous channel counting house and waiting table) and its ancestor the Chaupar- and leading to recognize -referent-, such as the modular conformation of the systems, their consistency in regular channels: common and autonomous of each circuit: 1 per module, and because of this part with three-dimensional systems called "universal": of equal modular composition and functional and conditional orders. But the uninterrupted rotational fluidity offered by the arrangement of the channels in the general system types formed by three-dimensional modules, allows alternatives to the modality of monocyclic game dynamics of the referent, being able to print a variety of dynamics: D1, D2, D3, D4 and D5 already transversally related, constituting their representative systems the variable that discriminates types of systems according to the dinamic they print; dynamic modalities that according to the type of system correspond to game modalities that may involve the variation or absence of a resource for the random determination of selective options ("given" or "dice" of 6 faces in the referent) of defined ranges of effect, to venture at the corresponding draw moment of each play. The system types of the "gender" lineage involve these dynamics in representation of the systems of the other lineages that adopt a representative dynamic. In the discrimination of systems according to their dimensionality it is counted: the type of systems of polygonal inscription, circular (representative of elipces), irregular, or starry, conformed by two-dimensional modules; the type of those formed by two-dimensional modules-face or two-dimensional modules-shell or lateral surface cap of systems inscribed in bodies of revolution; the type of those formed by three-dimensional modules; and the type of those formed by three-dimensional modules inscribed in bodies of revolution. In the discrimination of systems according to their dimensionality whose representative sample of the general also falls on the "lineage of types of system of 2 genres": the plane of each type of representative and represented two-dimensional systems, is comprised under the concept of -surface configuration ( : CS) - expression with which also covers the top view of systems of three-dimensional size; CS of polygonal inscription, circular (representative of elipces), irregular, or stellate, two-dimensional systems that require the demarcation of the section of space corresponding to each instance of the 2 involved in each crossing and or that each arrow falls on its particular space of the shared section Representative figures 83, 84, 87, 89, 91. Types of three-dimensional systems include those of surface configuration inscribed in three-dimensional geometric bodies (representative figures 151, 198), and those formed by modules of three-dimensional size (Representative figures 77, 80). The modules of three-dimensional size including the projections at levels of sections of polygonal faces-modules of systems inscribed in polyhedra and pyramids, representative of those of stepped pyramids; and of curved base surface configuration: cylindrical, conical and double conical surface-cap modules, representative of staggered similes and bulls, and sphere-hemisphere-shell modules, representative of those of ellipsoids, consist of orderings at levels of the contents of the surface configuration of the modules, orderings in the vertical that serves to provide fluency and section of particular plane to each instance of the 2 involved in each crossing, behaving without interference of intersections by physical intersection: the -functional ordering (: OFR) - and the -conditional ordering (: OCR) - of the referent (: OFCR) -; representative of systems conformed by three-dimensional modules where the 2 instances involved in each crossing coexist in the same level and section. For the registration of the instances that make up each module of a representative system type, as a rule it is enumerated or digitized in progressive account from where it is appropriate to install the concept, the modular instances of the types of standard systems of each line, of way between punctuation marks "semicolon": to each instance in section in succession of the common channel following with those of the autonomous channel. When an instance is found sharing a section with another, its identifying figures appear together separated by a bar: -; ../ ..; - Where in succession the registration corresponds to an instance that has already been registered sharing a section with another, a closed and empty parenthesis appears between the signs "semicolon": -; (); - Based on the identification of the provided instances that saturate the pattern module, the modular instances of the systems with less generation of instances are identified by means of union with a hyphen: -; -, between the numbers of instances of the pattern that are added to constitute an instance of a type of antecedent system beginning with the primitive system type. In the case of atypical systems with a greater number of modular instances than the pattern, the figure or number identifying the instance of the section to be divided that adds an instance to its channel heads the new figure that is completed followed by the initial literal of the alphabet in the first of them, the consecutive one in the second one and those that were necessary in succession. Particular instances are identified that meet a condition with their number in quotation marks: -; "..."; - In the record, the instances corresponding to the initial and terminal poles of the cycle and the instance indicating bifurcation are identified, the presence of desert space in the module if there is one, the total number of instances and modular sections and the sequence of instances of the autonomous channel. -Generations of series are recorded, understanding by generation the set of system types of the same number of modular instances that are progressively counted from the primitive systems, and by series the different types of system that can be of a generation differentiated by the ordering of their instances, discrimination that is registered with zero generation in the type of system called matrix, which is the simplest of the polarized systems, thus becoming representative of the types of primitive systems, of the system types with rotation dynamics continuous, natural dynamics of competition tracks, ideal printed on SD configuration systems.

Lineage of types of system of genres -bi-modular (: B-M) - and poly-modular (: P-M) of 6 crosses () of configuration SC and SD.

The fusion of the foundations on the requirement of coherence, efficiency and economy shows a first aspect constituted by types of system of 6 crosses (), which offers 2 trunks or complementary genres: genre types of systems (exclusively) bi-modular, monocyclic nature, whose module exchanges its flow exclusively with one another: representative figures 20 and 21, and poly-modular genre, of a polycyclic nature that covers system types from the tri-modular onwards, representatively to the octa-modular type, types whose module exchanges its flow exclusively with modules located on either side of it, so that the system that in sum of replicas of such a module is naturally inscribed in a regular polygon representatively or in a circumference. The type of patriarchal and representative system according to the modular conformation of poly-modular systems, it is the type of tetra-modular system, inscribed in a square, with square module with internal angle from the central point of its square polygon of 90 °: Figures 32 and 33, from where it is appropriate to transfer its contents to modules registered in parallelograms that make up systems composed of another number of modules, whose internal angles are 120 ° in modules of tri-modular systems inscribed in equilateral triangles: Figures 40, 41, 42, 43, 45 and 46; 72 ° in modules of penta-modular systems inscribed in pentagons (regular): Figures 47 and 48; 60 ° in modules of hexa-modular systems inscribed in regular hexagons: Figures 49 and 50; 51 ° 25 ~ in modules of hepta-modular systems inscribed in regular heptagons: Figures 51 and 52; and 45 ° in modules of octa-modular systems inscribed in regular octagons: Figures 51 and 52. In general, SC bi and tetra-modular configuration systems and their modules (representative of the poly-modular genre) are registered: primitives, matrices, universals and patterns representing the other types according to the modular, system composition of each lineage. Poly-modular systems (according to modular system conformation) are recorded from tri to octa-modular, including types of tri-modular systems of modular compositions denominated atypical 1 and 2: Figures 42, 43, 44, 45 and 46, system reprentatives compounds with a greater number of modular instances. The selected systems representative of the lineage, collect as a whole also the diversity of dynamics that the systems according to which they can print, in representation of the other systems of other lineages, which are recorded with the impression of a single representative dynamics. The representative SD system configuration types are presented here, and the orderings in the vertical dimension of the modular contents of systems of compact and distended surface configurations, of representative three-dimensional modules. The encrypted identification of the instances in the modular surface configuration of types of SC configuration master systems are expressed directly in the section of the cell form organized by the module replacing the arrow that describes its function, representative expressions in turn of systems constituted by codes of systems of consecutive codes and those constituted by collaborations of these; and correlatively in the identification of sectors of modules of SD configuration system types, representative.

 -Regular systems of type of system types of the genre -bi-modular (: B-M) - of 6 crosses () of SC configuration

 Registration of the functional instances that make up the module of the primitive system type B-M of configuration SC: Figures 14, 15, 16 and 17

 -; 1/24; 2/14; 3 ; 4/10; 5 ; 6/19; "7-8"; 9/20; (); eleven ; "12"; 13; (); 15/22; "27-16 -17" -25- "26"; 18; (); (); twenty-one ; (); 2. 3 ; (); ED (desert space); -.

n; ...; + n; ... / ...; + n; (); + n; "..."; = 22 instances, -n; ...; + n; ... / ...; + n; "..."; = 16 practical sections. Instances of the bi-modular primitive system module seated in disproportionately large sections, factors that produce diversity according to the number of modular components: 7-8 and 27-16-17-25-26.

Registration of the functional instances that make up the system type module universal BM of SC configuration, 1 ^to Series 2, third generation, D4, OFCR: Figures 18 and 19.

 -; 1/24; 2/14; 3 ; 4/10; 5 ; 6/19; "7"; 8; 9/20; (); eleven ; "12"; 13; (); 15/22; 16; "17"; 18; (); (); twenty-one ; (); 2. 3 ;

(); "25-26"; "27"; ED (desert space) -.

-Polo terminal cycle: 26 -; -Prolling initial of cycle: 27 -; - instance that signals bifurcation: 12-. n; ...; + n; ... / ...; + n; (); + n; "..."; = 26 instances: 17 in the common channel, and 9 in the autonomous channel corresponding to those listed in succession from 18 to 26 plus 27. -n; ...; + n; ... / ...; + n; "..."; =

20 sections.

Record of the instances that make up the module of the system type -pattern- B-M, of SC configuration, single fourth generation series, D4, OCR: Figures 20, 21, 22 and 23.

1 Series. Bi-modular pattern system

 -; 1/24; 2/14; 3 ; 4/10, 5; 6/19; "7"; 8; 9/20; (); eleven ; "12"; 13; (); 15/22; 16; "17"; 18; (); (); twenty-one ; (); 2. 3 ;

(); 25; "26"; "27"; ED (desert space) -.

 -Polo terminal cycle: 26 -; -Prolling initial of cycle: 27 -; - instance that signals bifurcation: 12-. n; ...; + n; ... / ...; + n; (); + n; "..."; = 27 instances: 17 in the common channel, and 10 in the autonomous channel corresponding to those listed in succession from 18 to 26 plus 27. -n; ...; + n; ... / ...; + n; "..."; =

21 sections.

-Systems representative of lineage of system types of the representative P-M gender, of 6 crosses () of SC configuration

 Record of the instances that make up the module of the type of primitive system P-M representative, of configuration SC: Figures 26 and 27, D1 or of continuous rotation, and 28 and 29, D2 or of cyclical registration

-; 1/6; 2/21; 3-4; 5/24; (); "7"; 8/16; 9-10; 11/13; "12"; (); 14; 15/19; (); "17"; 18; (); twenty ; (); 22-23;

 (); "25-26-27"; ED (desert space) -.

n; ...; + n; ... / ...; + n; (); + n; "..."; = 22 instances, -n; ...; + n; ... / ...; + n; "..."; = 16 practical sections. Instances of the poly-modular primitive system module seated in disproportionately large sections, factors that produce diversity according to the number of modular components: 3-4, 9-10, 22-23, 25-26-27.

 Registration of the instances that make up the respective modules of 2 series, without practical difference between them, of the matrix system of representative P-M gender, of configuration SC, D4:

Series 1 or Representative Figure 30:

 -; 1/6; 2/21; 3-4; 5/24; (); "7"; 8/16; 9-10; 11/13; "12"; (); 14; 15/19; (); "17"; 18; (); twenty

; (); 22-23;

 (); "25"; "26-27"; ED; -.

Terminal pole cycle: 25 -; -Prolling initial of cycle: 26-27 -; - instance that signals bifurcation: 12-. Series 2 or Alternative Figures 31 and 32. Type of system object of transformation from which PM system types of SD configuration emerge:

 -; 1/6; 2/21; 3-4; 5/24; (); "7"; 8/16; 9-10; 11/13; "12"; (); 14; 15/19; (); "17"; 18; (); twenty ; (); 22-23;

(); "25-26"; "27"; ED; -.

Terminal pole cycle: 25-26 -; -Prolling initial of cycle: 27 -; - instance that signals bifurcation: 12-. n; ...; + n; ... / ...; + n; (); + n; "..."; = 23 instances, -n; ...; + n; ... / ...; + n; "..."; = 17 practical sections Record of the instances that compose the respective modules of 2 series of third generation, of types of universal systems 1 and 2 representative P-M, OFCR, of configuration SC: Figures 26 and 27

1 ^a Series, Type of system "universal 1" poly-modular: Figures 28 and 29, D3.

 -; 1/6; 2/21; 3 ; 4 ; 5/24; (); "7"; 8/16; 9; 10; 11/13; "12"; (); 14; 15/19; (); "17"; 18; (); twenty

; (); 22; 2. 3 ;

 (); "25"; "26-27"; ED; -.

Terminal pole cycle: 25 -; -Prolling initial of cycle: 26-27 -; - instance that signals bifurcation: 12-. Series 2, type "universal 2" poly-modular system: Figures 30 and 31, D4.

 -; 1/6; 2/21; 3 ; 4 ; 5/24; (); "7"; 8/16; 9; 10; 11/13; "12"; (); 14; 15/19; (); "17"; 18; (); twenty ; (); 22-23;

 (); 25; "26", "27"; EP (peripheral space) and ED; -.

Terminal pole cycle: 26 -; -Prolling initial of cycle: 27 -; - instance that signals bifurcation: 12-. n; ...; + n; ... / ...; + n; (); + n; "..."; = 26 instances, -n; ...; + n; ... / ...; + n; "..."; = 20 practical sections.

Record of the instances that make up the module of the system type -pattern- of the fourth generation, representative P-M, OCR, of the SC configuration: Figures 38, 39; 36 and 37: D5; 44,

45, 52, 53, 54, 55, 56, 57, 58 and 59: D4.

 -; 1/6; 2/21; 3 ; 4 ; 5/24; (); "7"; 8/16; 9; 10; 11/13; "12"; (); 14; 15/19; (); "17"; 18; ();

twenty ; (); 22; 2. 3 ;

 (); 25; "26"; "27"; ED; -.

 -Polo terminal cycle: 26 -; -Prolling initial of cycle: 27 -; - instance that signals bifurcation: 12-. n; ...; + n; ... / ...; + n; (); + n; "..."; = 27 instances: 17 in the common channel, and 10 in the autonomous channel corresponding to those listed in succession from 18 to 27. -.n; ...; + n; ... / ...; + n; "..."; = 21 sections. Mutation of systems of compact surface configuration of both genres to systems of configuration -superficial distended (: SD) -

In the step of type of matrix systems of bi-gen and poly-modular genders of SC configuration to types of primitive systems of cyclic registration (dynamics that corresponds to the utility as sectoral orderings of competition tracks of variable scale) of SD configuration, such Resulting systems are configured with 4 modular instances more than their predecessor, instances that are identified with a number headed by the identification number of the previous instance, followed by the second literal (: B) of the alphabet; the identification number of the previous instance in question appears seconded by the first literal (: A) of the alphabet. Types of systems "of genus ", of semi-relaxed surface configuration, then have from 0 to 3 modular instances more than their predecessor of configuration SC In SD configuration systems, modular sections are defined as sectors given the variable scale of their coverage and the wide field of desert space that opens in relation to the scale and that allows diversity of specific paths of the regular channels on it, the adaptations of the family systems in compact or well-stretched surface configurations, to paths of tracks or circuits of competition or related playful exercises, are therefore a multiple object that in the "two-dimensional conformation" offers modalities of diverse use which are: "systems that expose or that dismiss the exposure of the flow or transit to collisions or confrontations, or deviations in crossings (intersections) of trajectories ";and" systems that avoid the risk of collisions and wrong deviations in the crossing of trajectories "mediating optimization of operability, well referred to regulations and or the adaptation of resources such as iconographic signs, traffic lights, roadblocks, etc., or mechanisms of activation and deactivation of resources or movement. The variable, appropriate for its economy to capture types of systems of three-dimensional modules of SD configuration, is the one that groups orderings in the vertical dimension that consist of 2 levels, and as such, samples of such orders are presented as representative of their number and variety of arrangements with another number of levels.

-Type of systems representative of gender B-M, of SD configuration

As it allows its physiognomy and the natural inclination of utility as competition tracks or platforms of board games that act as these, 3 types of system are shaped according to the dynamics they print: a first type that refers a "gender" system bi-modular of SD configuration of dynamics 3 or of mono-cyclic character, corresponding to that drawn with continuous line of Figures 60 (module) and 61 (system); a second type that refers to a type of system whose dynamics is irregular polycyclic character, expressed in Figure 60 (module) and 61 (system), drawn in a continuous line with the addition of the consecutive sector drawn in broken line identified 27, which connects with the consecutive instance numbered 1 A (sector 1A / 24) of the same module. Figures 61 and 62 in the compendium of its dotted and distended line plots, poses a type of system in which the dynamics are regulated with a monocyclic, irregular polycyclic character. The third type that directs the flow of traffic coming from sector 25-26, surrounding the system externally until connecting in the opposite module, configuring in sector 27-16-17: initial pole of its own circuit; thus finally constituting a type of bi-modular system whose dynamics are naturally polycyclic; Figures: 62 (module) and 63 (system), referred to as a continuous line. Figures 63 and 64 in the compendium of its dotted and distended line plots, poses a type of system in which its dynamics are regulated with irregular and poly-cyclic polycyclic character. The three types of system register their modular instances compared with the ciphers correlated to the sectors expressed in Figure 64.

Registration of the instances that make up the system type 1 module of the BM genre, D3 of SD configuration: Figures 64, 60 and 61:

 -; 1A / 24; 1 B ; 2 / 14A; 3 ; 4/10; 5 ; 6/19 A; "7-8"; 9A / 20; 9B; (); eleven ; "12"; 13; (); 14B; 15/22; "16 -17"; 18; (); 19B; (); twenty-one ; (); 2. 3 ; (); "25-26"; 27; -.

n; ...; + n; ... / ...; + n; (); + n; "..."; = 28 instances: 17 instances in the common channel and 8 in the autonomous channel,

n; ...; + n; ... / ...; + n; "..."; = 22 practical sections.

 Registration of the instances that make up the type 2 module of the gender system B-M, D2 that complies with irregular cycles, of SD configuration: Figures 64, 60 and 61.

 -; 1A / 24; 1 B ; 2 / 14A; 3 ; 4/10, 5; 6/19 A; "7-8"; 9A / 20; 9B; (); eleven ; "12"; 13; (); 14B; 15/22; "16 -17"; 18; (); 19B; (); twenty-one ; (); 2. 3 ; (); "25-26"; -.

 -Instance of cyclic record: 25-26 -; -stance that signals bifurcation: 12-.

n; ...; + n; ... / ...; + n; (); + n; "..."; = 27 instances: 18 instances in the common channel and 9 in the autonomous channel.

n; ...; + n; ... / ...; + n; "..."; = 21 practical sections.

Registration of the instances that make up the type 3 module of the B-M gender system of SD configuration: Figures 64, 62 and 63, D2:

 -; 1A / 24; 1 B ; 2 / 14A; 3 ; 4/10; 5 ; 6/19 A; "7-8"; 9A / 20; 9B; (); eleven ; "12"; 13; (); 14B; 15/22; "16 -17"; 18; (); 19B; (); twenty-one ; (); 2. 3 ; (); 25-26-27; (); (); -.

-Instance of cyclical record: 16-17 -; -stance that signals bifurcation: 12-.

n; ...; + n; ... / ...; + n; (); + n; "..."; = 27 instances: 18 instances in the common channel and 9 in the autonomous channel corresponding to those listed in succession from 18 to 25-26-27. -n; ...; + n; ... / ...; + n; "..."; = 20 practical sections.

 Types of primitive systems of cyclic record, representative of gender P-M, of SD configuration

2 types of representative systems of the same dynamic 2 are registered, differentiated according to modular composition: tri and tetra-modular, respective figures: 65 (module), 66 (system); 67 (module), 68 (system), confronted with the ciphers correlated to the sectors expressed in Figure 69.

 Registration of the instances that make up the type 1 module of the cyclic deregistration primitive system of the genre P-M, D3 of SD configuration: Figures 69, 65, 66, 67 and 68:

 -; 1A 6; 1 B ; 2/21; 3-4; 5A / 24; 5B; (); "7"; 8/16; 9-10; 11/13; "12"; (); 14 TO ; 14B; 15A / 19; 15B; (); 17 "; 18; (); 20; (); 22-23; ();" 25-26 ";" 27 "; ED (desert space) -.

-Instance of cyclic record: 25-26 -; -stance that signals bifurcation: 12-.

n; ...; + n; ... / ...; + n; (); + n; ; = 27 instances, -n; ...; + n; ... / ...; + n; "..."; = 21 practical sections-. Types of systems formed by representative three-dimensional modules The system types representative of the "gender" lineage of SC and SD configuration, formed by modules of three-dimensional size, are indicative of the plurality of alternative coherent types of projections to which can respond a surface configuration of any type of systems, so they are representative of the number of possible coherent orderings in the vertical dimension of the contents of the modular surface configurations of systems of the four lineages.

 Types of "genre" systems B-M and P-M, of SC and SD configurations formed by representative three-dimensional modules.

With criterion in the spatial economy, the representative systems are divided into 2 types: economic in the vertical dimension with modules of 2 levels or plants, and large in the vertical dimension with modules of 5 and 6 levels.

 "Gender" systems B-M of configurations SC and SD formed by modules of three-dimensional economic size in the vertical dimension, representative

The economic disposition in the vertical dimension or of systems that consist of 2 levels, is ideal in the first term for the types of matrices and primary systems of both genders, of large scale and relaxed basic form, as well as their computer simulations; but, secondly, the three-dimensional systems of both genres with this economic provision in the vertical dimension also serve in small-scale material complexes adapted for use as an instrument or basic element of board games, although necessarily counting them with devices or elevating gadgets, that save the difficulty or the impossibility of manual manipulation in the modular instance that occupies section in the low level of those that overlap (in the vertical) in the 6 modular crosses of the trajectories of the channels of the system and others, devices which, like pistons (for example) from the upper level, facilitate the introduction and extraction of the corresponding agents (chips or game pieces) of the circuits. These artifices become unnecessary in representations at larger scales and in computer simulations, which do not have irregular ducts.

 Sorting of modular instances to levels of the type of second generation system "of gender" bi-modular of three-dimensional economic size in the vertical dimension, of SC configuration

 Level 1: instances 4; 5 ; 7; 8; eleven ; 12; 13; 14; fifteen ; 27-16-17; 18; 19; twenty ; twenty-one ; 24; 25-26; -. (Figure 70.1)

 Level 2: instances 1; two ; 3 ; 6; 9; 10; 22; 2. 3 ;-. (Figure 70.2)

Sorting of modular instances in levels of the system of 1 ^to third generation series called -universal- "of the gender" BM, of three-dimensional economic size in the vertical dimension, SC configuration

 Level 1: instances 4; 5 ; 7; 8; eleven ; 12; 13; 14; fifteen ; 16; 17; 18; 19; twenty ; twenty-one ; 24; 25-26; 27; -. (Figure 71.1)

 Level 2: instances 1; two ; 3 ; 6; 9; 10; 22; 2. 3 ;-. (Figure 71.2)

The overhead view of the module and system (of invoice in transparent material) is shown in Figures 18 and 19 respectively.

Sorting of modular instances in levels of the system from 2nd ^to 3rd generation series, "gender" bi-modular, of three-dimensional economic size in the vertical dimension, SC configuration. Level 1: instances 4; 5 ; 7; 8; eleven ; 12; 13; 14; fifteen ; 16-17; 18; 19; twenty ; twenty-one ; 24; 25; 26; 27; -. (Figure 72.1)

 Level 2: instances 1; two ; 3 ; 6; 9; 10; 22; 2. 3 ;-. (Figure 72.2)

Ordering of modular instances in levels of the 4 ^- generation system module called -pattern-, "gender" B-, of three-dimensional economic size in the vertical dimension

 Level 1: instances 4; 5 ; 7; 8; eleven ; 12; 13; 14; fifteen ; 16; 17; 18; 19; twenty ; twenty-one ; 24; 25; 26; 27; -. (Figure 73.1)

 Level 2: instances 1; two ; 3 ; 6; 9; 10; 22; 2. 3 ;-. (Figure 73.2)

The top view of the module and system (of invoice in transparent material) is shown in Figures 20 and 21, 22 and 23.

 Two representative orderings of modular instances in levels of the type of system -primitive of cyclical record- "of gender" B-M, of three-dimensional economic size in the vertical dimension, of SD configuration. We found 2 different optimal alternatives depending on whether we chose sector 9B, in the second level or in the first level. Refer to Figures 62, 63 and 64.

Ordering 1

 Level 1: instances 4; 5 ; 7-8; eleven ; 12; 13; 14 TO ; 14B; fifteen ; 27-16-17; 18; 19A; 19B; twenty ; twenty-one ; 24; 25-26; -.

Level 2: instances 1A; 1 B ; two ; 3 ; 6; 9A; 9B; 10; 22; 2. 3 ;-.

Ordering 2

 Level 1: instances 4; 5 ; 7-8; 9B; eleven ; 12; 13; 14 TO ; 14B; fifteen ; 27-16-17; 18; 19; twenty ; twenty-one ; 24; 25-26; -.

 Level 2: instances 1; two ; 3 ; 6; 9A; 10; 22; 2. 3 ;-.

Ordering of modular instances at system levels -patrón- "of gender" P-M of configuration SC conformed by modules of three-dimensional economic size in the vertical, representative dimension.

 Level 1: instances 1; two ; 3 ; 4 ; eleven ; fifteen ; 16; 17; 22; 2. 3 ; 24; 25; 26; 27; -. (Figures 74.1, of D3) Level 2: instances 5; 6; 7; 8; 9; 10; 12; 13; 14; 18; 19; twenty ; twenty-one ;-. (Figure 74.2)

Confront Figures 36, 37, 38 and 39.

 Sorting of modular instances in system levels -primitive of cyclic record- "of gender" P-M of configuració SD conformed by modules of three-dimensional economic size in the vertical dimension, representative.

 Level 1: instances 1A; 1 B ; two ; 3-4; eleven ; 15A; 15B; 16; 17; 22-23; 24; 25-26; 27; -.

Level 2: instances 5A; 5B; 6; 7; 8; 9 -10; 12; 13; 14 TO ; 14B; 18; 19; twenty ; twenty-one ;- .

 Ordering of modular instances at system levels -patron- "of the genre" B-M of SC and SD configurations made up of modules of three-dimensional size in the vertical dimension, representative

Representative system module. Level 1: instances 2; 17; 26; 27; ED; -. (Figure 75.1)

Level 2: instances 1; 3 ; 16; 19; -. (Figure 75.2)

Level 3: instances 4; fifteen ; 18; twenty ;-. (Figure 75.3)

Level 4: instances 5; 12; 14; twenty-one ;-. (Figure 75.4)

Level 5: instances 6; 7; 11; 13; 22; 25; -. (Figure 75.5)

Level 6: instances 8; 9; 10; 2. 3 ; 24; -. (Figure 75.6)

 The top view of the module and system (of invoice in transparent material) is covered as CS in Figures 20, 21, 22 and 23; The 'Side View' of side faces (4 faces) of the module are presented in Figures 76.1 to 76.4, and its isometric representation in Figure 77. Modular instances of the primitive SD configuration system coded with literal B are placed at the same level as their corresponding instances encrypted with literal A, which correspond to those of the SC configuration matrix system from which it emerges.

 Ordering of modular instances in levels of tetra-modular system -pattern- "of the genus" PM of SC and SD configurations formed by modules of broad three-dimensional size in the vertical dimension, representative, ordering at levels (6 levels) defined as "regular cause" dominant":

 Level 1: instances 5; 6; 10; twenty ; 26; 27; ED; -. (Figure 78.1)

Level 2: instances 4; 7; 9; eleven ; 18; 19; twenty-one ; 22; -. (Figure 78.2)

Level 3: instances 3; 8; 12; 2. 3 ;-. (Figure 78.3)

Level 4: instances 2; 13; 24; -. (Figure 78.4)

 Level 5: instances 1; 14; fifteen ; 16; 25; -. (Figure 78.5)

Level 6: instance 1, -. (Figure 78.6)

 The top view of the module and system (of invoice in transparent material) is covered as CS in Figures 36, 37, 38 and 39; the "side elevations" of side faces (4 faces) of the module are presented in Figures from 79.1 to 79.4; and its isometric presentation in Figure 80. Modular instances of primitive SD configuration system encrypted with literal B, are placed at the same level as their corresponding instances encrypted with literal A, which correspond to those of the configuration system SC where emerges.

 Ordering of modular instances in 6 levels of system -Universal- "of the gender" P-M of configurations SC and SD conformed by modules of three-dimensional size in the vertical dimension, representative, ordering of 6 levels defined as "cause regular dominant", OFCR.

 Level 1: instances 5; 6; 10; twenty ; 26-27; -.

 Levels 2, 3, 4, 5 and 6 each contain the same instances of the standard modular composition, presented immediately above. Instance 25 at level 5 has a terminal pole. The top view of the module and system (of invoice in transparent material) is covered as CS in Figures 28 and 29.

Classification of modular instances in 5 levels defined as "first (1 ^a ) deviation" from the dominant regular cause, or cause alternative regular, tetra-modular system -pattern- of "gender" PM, OCR, representative:

 Level 1: instances 5; 6; 10; twenty ; 26; 27, ED; -.

Level 2: instances 4; 7; 9; eleven ; 18; 19; twenty-one ; 22; -.

Level 3: instances 3; 8; 12; 2. 3 ;-.

Level 4: instances 2; 13; 24; -.

Level 5: instances 1; 14; fifteen ; 16; 17; 25; -.

 The top-down view of the module and system (of invoice in transparent material) is covered as CS in Figures 36, 37, 38 and 39. Modular instances of primitive system of SD configuration encrypted with literal B, are placed at the same level as their corresponding instances encrypted with literal A, which correspond to those of the SC configuration matrix system from which it emerges.

Ordinance of modular instances in 6 levels defined as "Second (2 ^a ) deviation" from the dominant regular cause, from -pattern- systems "of PM gender with OCR, type of modular pattern composition system (representative:

 Level 1: instances 5; 6; 10; twenty ; ED; -.

Level 2: instances 4; 7; 9; eleven ; 18; 19; twenty-one ; 22; -.

 Level 3: instances 3; 8; 12; 2. 3 ;-.

 Level 4: instances 2; 13; 24; -.

 Level 5: instances 1; 14; fifteen ; 16; 25; 26; 27; -.

 Level 6: instance 17; -.

The top-down view of the module and system (of invoice in transparent material) is covered as CS in Figures 36, 37, 38 and 39. Modular instances of primitive system of SD configuration encrypted with literal B, are placed at the same level as their corresponding instances encrypted with literal A, which correspond to those of the SC configuration matrix system from which it emerges. Sorting of modular instances in 5 levels defined as "Second (2 ^a ) deviation" from the dominant regular cause, "patron-tetra-modular" systems of gender PM, OCR.

 Levels 1, 2, 3, 4 and 6 each contain the same instances of the standard modular composition, presented above.

Level 5: instances 1; 14; fifteen ; 16; 25; 26-27; -.

The overhead view of the module and system (of invoice in transparent material) is covered as CS in Figures 36, 37, 38 and 39.

Sorting of modular instances in 5 levels defined as 'ercera (3 ^a ) deviation' from the dominant regular cause, systems with OFCR and OFNP-M and representative conductive arrangement, type of modular composition system representative (representative):

Level 1: instances 5; 6; 10; twenty ; ED; -.

 Level 2: instances 4; 7; 9; eleven ; 18; 19; twenty-one ; 22; -.

 Level 3: instances 3; 8; 12, 23;

 Level 4: instances 2; 13; 24; -.

Level 5: instances 1; 14; fifteen ; 16; 17; 25; 26; 27; -. The overhead view of the module and system (of invoice in transparent material) is covered as CS in Figures 36, 37, 38 and 39.

 Lineage of so-called "grid" intensive systems, of 5 ¾, 6 Vi, 9 7/8 and 10 crosses () per module

Successive strains of system types, of conduits constituted by horizontal and vertical straight paths in the most economic grid of sequence of instances, systems whose common channel, as allowed by the grid condition, follows in principle the wake of the alignment of a star of 6 tips, a model that exhausts its possibilities and manages to accommodate from mono-modular, bi-modular to tetra-modular conformation types, from where, by duplication of contents, it is mutated into octa-modular systems whose common channel, as the condition allows grid, is following the wake of the line of a 10-pointed star. The patriarchal systems of the lineage, product of the correct conjunction and prolongation of their trajectories in the new cell form, of 2 types of twin mono-modular precursor systems without compound crossings of 16 instances and inscribed in the same cell shape, differentiated by directing contrary to the flow of their circuit (Figures 81 and 82), they are primitive twins bi-modular circulatory systems of 13 crosses, representative of each other (Figure 87), which transmits to their offspring primitive systems except the mono-modular: The constitution of system types per pair or pairs of circuits that run in the opposite direction in relation to the identical formal modular approach in which they coincide, types of modular forms these, different from each other in the case of components of tetra and octa-modular systems, in the cell-shaped areas composed of an odd number of sections. For the verification that the modules of the particular types of grid systems are composed with the same particular number of instances and the encrypted identification of these in the adopted modular forms, subject to a mechanism that meshes them in a global context or function, can only register them taking part of successions - cut-off consecurtivas instances, since the modular forms intend to collect a sample that does not always find, of each element of the composition according to which such particular diversity of conformation circuits. Such conditions decipher the position of the instances as components of the circulating flow in a system of conduits, portrayed at a certain moment among others, situating specific cases of some of them in each module (which contribute to making each particular module), transiting different position to the corresponding one of some circuit (example instance 5 of module 1, and 3 of module 2 of the bi-modular system type of Figure 92). This circumstance lends itself to the incorporation if desired, among others, of a particular type of irregular conduits that is offered by adding the encryption of the modular instances to the expression of the system given by conventional. This coexistence offers the opportunity of option in the divergences according to regulations, of selecting the course to which the succession of conductive signs leads or that of consecutive ciphers; also deriving types of "grid" systems whose flow is given by the consecutiveness of code codes of consecutive codes, such as numbering. In the consolidation of the register of modular instances of each module, the modules are numbered according to the convention of the movement of the hands of the clock, and the instances that share sections split by the modular division of the system, identify their partner with a quote ( ^" ) if it is in the module on your right, and 2 ( ^" ) if it is in the module on your left. The presentation of the grid systems focuses on "intensive" systems, which become representative of the extensive systems, which is reduced because the number of instances can be extended indefinitely around the system. The readout marker panels are preferentially externally in front of the previous instance to which it points bifurcation in each module. Types of mono-modular intensive "grid" systems of 10 crosses ()

10 The first descendants of the bi-modular grid-primitive system type are mono-modular primitive systems (Figure 83), obtained from this by dispensing with an autonomous channel and the common channel instance that signals bifurcation that gave access, systems representative and parameter of the other differentiated in directing in opposite way the flow in the common channel and because the second one had encrypted its instances in the common channel in

15 countdown; systems of monocyclic nature, of surface configuration inscribed in a broken shape divisible into 2 parts that keep radial symmetry with each other, surface configuration composed of 20 sections between square and rectangular alvergan 30 instances.

 -Register of component instances of the 2 types of primitive mono-modular "grid" system

 twenty -; one ; 2/10; 3/17; 4/22; 5 ; 6; 7/21; 8/18; 9; (); 11/29; 12/26; "13-14"; 15/25; 16/30; (); ();

 "19-20"; (); (); 23/31; 24; (); (); 27; 28; (); (); (); 32; -. Figure 83

 30 instances settled in 20 sections.

 -Registration of component instances of the representative "mono-modular" master grid (first generation) system, Figures 84 and 85

 25 -; one ; 2/10; 3/17; 4/22; 5 ; 6; 7/21; 8/18; 9; (); 11/29; 12/26; 13; 14; 15/25; 16/30; (); ();

 19; twenty ; (); (); 23/31; 24; (); (); 27; 28; (); (); (); 32; 33; -.

 -Polo terminal cycle: 32 -; -Prolling initial of cycle: 33 -; - instance that signals bifurcation: 28-. n; ...; + n; ... / ...; + n; (); + n; "..."; = 33 instances: 28 in the common channel, and 5 in the autonomous channel corresponding to those listed in succession from 29 to 32 plus 33. -n; ...; + n; ... / ...; + n; "..."; = 30 23 practical sections.

 Types of bi-modular "grid" systems

 Of a monocyclic nature, of unbalanced circuits, of 6 crosses () per module, of surface configuration inscribed in the same broken shape, divided into 2 parts that keep radial symmetry with each other, a circle that allows the formal combination of the circuits and the 35 via subsequent mutations. The lineage of bi-modular intensive systems reaches 23 types of standard systems.

 -Registration of component instances of the 2 types of module forming the primitive bi-modular "grid" system, (Figure 86 and 87)

Module 1 -; one ; 2/4; 3/5 ^" ; (); 5/17; 6; 7; 8/14; 9/13; 10; 11/19 ^" ; 12/18; (); (); "15-16";();(); 11/19 ^' ; twenty ;-.

 Module 2

-; one ; 2/4; 3/17; (); 5/3 ^' ; 6; 7; 8/14; 9/13; 10; 11/19 ^' ; 12/18; (); (); "15-16";();(); 11/19 ^' ; 520; -.

 n; ...; + n; ... / ...; + n; (); + n; "..."; = 19 instances per module: 15 in the common channel, and 4 in the autonomous channel corresponding to those listed in succession from 17 to 20. -n; ...; + n; ... / ...; + n; "..."; = 12 I saw modular sections.

 -Registration of component instances of the 2 module types of the matrix system b-10 modular "grid" (Figures 88 and 89)

 Module 1

-; one ; 2/4; 3/5 ^' ; (); 5/17; 6; 7; 8/14; 9/13; 10; 11/19 ^' ; 12/18; (); (); "15-16";();(); 11/19 ^' ; 20-21; 22A-B; -.

 Module 2

fifteen -; one ; 2/4; 3/17; (); 5/3 ^' ; 6; 7; 8/14; 9/13; 10; 11/19 ^' ; 12/18; (); (); "15-16";();(); 11/19 ^' ;

 20-21; 22A-B; -.

-Polo terminal cycle: 20; -Prolling initial of cycle: 21-; - instance pointing branch: 6-. n; ...; + n; ... / ...; + n; (); + n; "..."; = 20 instances: 15 in the common channel, and 5 in the autonomous channel corresponding to those listed in succession from 17 to 20 plus 21. -n; ...; + n; ... / ...; + n; "..."; = 2013 ^■ ½ modular sections-,

 -Register of component instances of the 2 types of module of the bi-modular system "grid" -pattern- (third generation) (Figures 090, 091 and 092)

 Module 1

-; one ; 2/4; 3/5 ^' ; (); 5/17; 6; 7; 8/14; 9/13; 10; 11/19 ^' ; 12/18; (); (); fifteen ; 16; (); (); 11/19 ^' ; 2520; twenty-one ; 22A; 22B; -.

 Module 2

-; one ; 2/4; 3/17; (); 5/3 ^' ; 6; 7; 8/14; 9/13; 10; 11/19 ^' ; 12/18; (); (); fifteen ; 16; (); (); 11/19 ^' ; twenty ; twenty-one ; 22A; 22B; -.

 -Polo terminal cycle: 21-; -Printer initial cycle: 22A-; - instance that signals bifurcation: 6 -. 30 n; ...; + n; ... / ...; + n; (); + n; "..."; = 23 instances: 17 in the common channel, and 6 in the autonomous channel corresponding to those listed in succession from 17 to 21 plus 22A.

 ; n; ...; + n; ... / ...; + n; "..."; = 16 1/2 modular sections. System composed of 46 instances settled in 33 sections.

-The addition of 2 autonomous canals and their respective instance of common channel pointing 35 bifurcation, assimilating up and down the central horizontal path of the representative representative of the representative bi-modular primitive system type derived in a couple of types of primitive systems tetra-modular twin, one representative of the other, whose trajectories undergo 23 crosses, number equivalent to an average of 5 ¾ crosses () per module, of 64 instances seated in 41 sections, each of its modules has a particular code arrangement of its 16 component instances, inscribed in 2 different cell shapes: 10 sections and 6 crosses (): modules 1 and 3, and 10 ½ sections and 5 ½ crosses (): modules 2 and 4, pairs of gemelos differentiated by the opposite direction in the common channel. Record of component instances of module types of the tetra-modular primitive "grid" system (Figures 93 and 94)

Module 1

-; one ; 2/10 ^"" ; 3/15; 4/10; 5/13; 6/6 ^" ; 7; 8; 9/13; (); (); 12/12 ^" ; (); 14/14 ^' ; (); 16-17; -.

Module 2

-; one ; 2/4; 3/11; (); 5/11; 6/6 ^' ; 7; 8; 9/15; 10; (); 12/12 ^' ; (); 14/14 ^" ; (); 16-17; -.

Module 3

-; one ; 2/10 ^" ; 3/11; 4/6; 5/13; (); 7; 8; 9/15; 10/2 ^' ; (); 12/12 ^" ; (); 14/14 ^' ; (); 16-17; -.

Module 4

-; one ; two ; 3/13; 4/6; 5/11; (); 7; 8; 9/15; 10/2 ^' ; (); 12/12 ^' ; (); 14/14 ^" ; (); 16-17; -.

- instance pointing bifurcation: 8-.

n; ...; + n; ... / ...; + n; (); + n; "..."; = 16 instances: 10 in the common channel, and 6 in the autonomous channel corresponding to those listed in succession from 11 to 16.

 -n; ...; + n; ... /: ..; + n; "..."; = average of 10 1/4 modular sections-. - instance indicating branch: 8 -.

Registration of component instances of module types of the "quadricular" tetra-modular matrix system (Figures 95 and 96)

 Module 1

-; one ; 2/10 ^" ; 3/15; 4/10; 5/13; 6/6 ^" ; 7; 8; 9/13; (); (); 12/12 ^" ; (); 14/14 ^' ; (); 16-17; 18A-B; -. Module 2

-; one ; 2/4; 3/11; (); 5/11; 6/6 ^' ; 7; 8; 9/15; 10; (); 12/12 ^' ; (); 14/14 ^" ; (); 16-17; 18A-B; -. Module 3

-; one ; 2/10 ^" ; 3/11; 4/6; 5/13; (); 7; 8; 9/15; 10/2 ^' ; (); 12/12 ^" ; (); 14/14 ^' ; (); 16-17; 18A-B; -. Module 4

-;one ; two ; 3/13; 4/6; 5/11; (); 7; 8; 9/15; 10/2 ^' ; (); 12/12 ^' ; (); 14/14 ^" ; (); 16-17; 18A-B; -. -Polo terminal of cycle: 16-17-; -Plick initial of cycle: 19A-B-; - instance that signals bifurcation: 8-. ; ...; + n; ... / ...; + n; (); + n; "..."; = 17 modular instances: 10 in the common channel, and 7 in the autonomous channel corresponding to those listed in succession from 11 to 16-17 plus 18A-B.

; n; ...; + n; ... / ...; + n; "..."; = average of 11 1/4 modular sections.

 Record of component instances of module types of the "quadricular" tetra-modular pattern system representative of its mirror image (Figures 97, 98 and 99)

 Module 1

-; one ; 2/10 ^" ; 3/15; 4/10; 5/13; 6/6 ^" ; 7; 8; 9/13; (); (); 12/12 ^" ; (); 14/14 ^' ; (); 16; 17; 18A; 18B; -. Module 2

-; one ; 2/4; 3/11; (); 5/11; 6/6 ^' ; 7; 8; 9/15; 10; (); 12/12 ^' ; (); 14/14 ^" ; (); 16; 17; 18A; 18B; -. Module 3

-; one ; 2/10 ^" ; 3/11; 4/6; 5/13; (); 7; 8; 9/15; 10/2 ^" ; (); 12/12 ^" ; (); 14/14 ^" ; (); 16; 17; 18 ; 18B; -.

Module 4

-;one ; two ; 3/13; 4/6; 5/11; (); 7; 8; 9/15; 10/2 ^" ; (); 12/12 ^' ; (); 14/14 ^" ; (); 16; 17; 18 ; 18B; -. -Polo terminal cycle: 17-; -Prolling initial of cycle: 18A-; - instance pointing bifurcation: 8-. n; ...; + n; ... / ...; + n; (); + n; "..."; = 19 instances: 11 in the common channel, and 9 in the autonomous channel corresponding to those listed in succession from 11 to 17 plus 18A.

 ; n; ...; + n; ... / ...; + n; "..."; = modules 1 and 3: of 13 sections, and modules 2 and 4: of 13 ½ sections; average of 13 1/4 modular sections. -System of 76 instances settled in 53 sections- -With the type of primitive tetra-modular system by object of transformation, by duplicating its paths from the ends of the central horizontal and vertical paths, it is mutated to a pair of mirror systems simulating each other, octa-modular primitives representative of each other, of 79 crosses that equate to an average of 9 7/8 crosses () per module. The composite modules of 24 instances are inscribed in three different cell types (Figures from 100 to 105), one which includes 2 pairs of mirror-like forms, such 4 modules (: 1, 2, 5 and 6) that are rearranged from another way they also respond as 2 pairs of twin modules differentiated by their opposite direction in the common channel; and the two remaining modular cell shapes each circumscribe pairs of twin modules, differentiated one from the other by their opposite direction in the common channel (modules 3 and 7, 4 and 8). Modules 1, 2, 3, 5, 6, and 7, with 10 crosses () are inscribed in 14 sections, and modules 4 and 8 with 9 Vi crosses () are inscribed in 14 Vi sections. The modules fit together on one side, in a way that is shaped in the conformation of the system. The encrypted distribution of the modular instances interpreted in the modular forms, the figures related to at least one consecutive referent and indicates particular to each module.

 Record of component instances of the module types of the representative octa-modular primitive "grid" system (Figures 100 and 101)

With referent in the register of instances of the modules of the matrix and pattern system type at the same time, which appears below, the primitive systems type registers the difference of not having an initial cycle pole: instance 25.

n; ...; + n; ... / ...; + n; (); + n; "..."; = 24 instances: 14 in the common channel, and 10 in the autonomous channel corresponding to those listed in succession from 15 to 24. -System of 192 instances seated in 113 sections- Register of component instances of the module types of the grid system " "matrix at the same time octa-modular pattern representative of its specular simile (Figures 102, 103, 104 and 105)

Module 1 -; one ; 2/8; 3/17; 4/4 ^" ; 5/21; 6/8 ^" ; 7/19 ^' ; (); 9/15; 10/10 ^" ; 11; 12; 13/23; 14/10 ^' ; (); 16/16 ^" ; (); 18/22; 19/9 ^' ; 20/20 ^" ; (); (); (); 24; 25; -.

Module 2

-; one ; 2/8; 3/17; 4/4 ^' ; 5/21; 6/8 ^" ; 7/19 ^" ; (); 9/15; 10/10 ^' ; eleven ; 12; 13/23; 14/10 ^" ; (); 16/16 ^' ; (); 18/22; 19/9 ^" ; 20/20 ^' ; (); (); (); 24; 25; -.

Module 3

-; one ; 2/14; 3/21; 4/8 ^" ; 5/15; 6/6 ^' ; 7/17; 8/6 ^' ; 9/19 ^' ; 10/14 ^' ; 11; 12; 13/23; (); () ; 16/20; (); 18/18 ^" ; 19/7 ^' ; (); (); 22/22 ^" ; (); 24; 25; -.

Module 4

-; one ; 2/14 ^" ; 3/19 ^" ; 4/6 ^" ; 5/17; 6/14; 7/15; 8/4 ^' ; 9/21; 10; 11; 12; 13/23; (); (); 16/20; (); 18 / 18 ^' ; 19/5 ^" ; (); (); 22/22 ^' ; (); 24; 25; -.

Module 5

-; one ; 2/2 ^" ; 3/15; 4/10; 5/19 ^' ; 6/4 ^' ; 7/21; 8/8 ^" ; 9/17; (); eleven ; 12; 13/23; 14/2 ^' ; (); 16/16 ^" ; (); 18/22; 19/3 ^" ; 20/20 ^" ; (); (); (); 24; 25; -.

Module 6

-; one ; 2/2 ^' ; 3/15; 4/10; 5/19 ^" ; 6/4 ^" ; 7/21; 8/8 ^' ; 9/17; (); eleven ; 12; 13/23; 14/2 ^" ; (); 16/16 ^' ; (); 18/22; 19/3 ^" ; 20/20 ^' ; (); (); (); 24; 25; - Module 7

-; one ; 2/14 ^' ; 3/19 ^" ; 4/6 ^' ; 5/17; 6/6 ^" ; 7/15; 8/4 ^" ; 9/21; 10/14; 11; 12; 13/23; (); (); 16/20; (); 18/18 ^" ; 19/5 ^" ; (); (); 22/22 ^" ; (); 24; 25; -.

Module 8

-; one ; 2/14; 3/21; 4/8 ^" ; 5/23; 6; 7/17; 8/6 ^" ; 9/19 ^" ; 10/14 ^" ; eleven ; 12; 13/15; (); (); 16/20; (); 18/18 ^' ; 19/7 ^" ; (); (); 22/22 ^' ; (); 24; 25; -.

 -Polo terminal cycle: 24-; -Prolling initial of cycle: 25-; - instance that signals bifurcation: 12-. n; ...; + n; ... / ...; + n; (); + n; "..."; = 25 instances: 14 in the common channel, and 11 in the autonomous channel corresponding to those listed in succession from 15 to 24 plus 25.

 ; n; ...; + n; ... / ...; + n; "..."; = 15 sections: modules 1, 2, 3, 5, 6, and 7; and 15 ½ sections: modules 4 and 8, weighted 151/8 modular sections. - System with 79 crossings () of 200 instances seated in 121 sections.

-Types of systems generated from the "versatile" module - of 9 crosses (), of Configuration SC

The representative modular approach called "versatile module" (Figure 106), suffers 9 crosses (), and is originally replicated longitudinally in superflange (Figure 107) forming elementally by functionally joining vertical sides of the first and last replicas of the required ones. the superfranja, types of systems of cylindrical configuration SC, and that of joining in addition the horizontal sides, produces types of systems inscribed in body of bull, represented by the type inscribed in cilindo; differentiated in number of component replicas, perfectly fluid to assume any dynamic (Figure 108); representative module that is (Figure 106) according to modular composition -of the fourth generation-, that is: with 6 instances more modular (between which the initial and terminal poles of cycle are counted) than the module of the type of systems -primitive-: Figure 109; and 5 instances less than the module of the representative system type (ninth generation).

 -Register of instances that make up the "versatile" module of 9 crosses (), of the system type -pattern- (ninth generation), D5 (representative), representative, (compare with Figures 110 and 111):

 -; 1A; 1 B ; 2/10; 3 ; 4/19; 5 ; 6/24; 7; 8/21; 9; (); 11/26; 12; 13/16; 14 TO ; 14B; 15A; 15B; (); 17; 18/28; (); twenty ; (); 22/32; 23A; 23B; 23C; (); 25/30; (); 27; (); 29A; 29B; (); 31A; 31 B; 31 C; (); 33A; 33B; - -Polo terminal cycle: 33A-; -Printer initial cycle: 33B-; -stance pointing to fork: 20-, n; ...; + n ;. ,. / ...; + n; (); + n; "..."; = 42 instances: 28 in the common channel, and 14 in the autonomous channel corresponding to those listed in succession from 24 to 33B. -n; ...; + n; ... / ...; + n; "..."; = 33 practical sections.

 -Register instances that make up the "versatile" module of 9 crosses (), of the representative -primitive-system type (Figure 109):

 -; 2/10; 3 ; 4/19; 5 ; 6/24; 7; 8/21; 9; (); 11/26; 12; 13/16; 14A-B-15A-B; (); 17; 18/28; (); twenty ; (); 22/32; 23A-B-C-1A-B; (); 25/30; (); 27; (); 29A-B; (); 31A-B-C; (); 33A-B; -. n; ...; + n; ... / ...; + n; (); + n; "..."; = 31 instances: 21 in the common channel and 10 in the autonomous channel; n; ...; + n; ... / ...; + n; "..."; = 22 practical sections.

Technical precision: the exceptional identification that includes 2 numerals, of the identified section instance 14A-B-15A-B in the registry of the primitive system type, is due to the fact that its component 14A-B can be expressed in contact with its similar instance. of contiguous replication, and to be linked as irregular foci or conduits, or it can be a medium of inter-modular transit exchange present in variables that are exposed later, for which it needs an elementary figure of identity for the registration of the types of the lineages of types of systems covered in such variables.

 -Module type of system Matrix (zero generation): = 33 instances: 22 in the common channel and 11 in the autonomous channel seated in 24 practical sections.

 Technical precision: -The type of primitive system has 2 instances more than the type of system (with cyclic registration) matrix, one more than normal, normality that corresponds to a single division of the section instance identified 33A-B in 33A and 33B: terminal and initial cycle poles respectively, but instance 1 AB of the matrix system that happens to the initial pole of the cycle, appears as part of the instance in section 23A-BC-1A-B in the primitive system type and must be dissolved in 23A-BC and 1A-B in consequence simultaneous.

 -Register instances that make up the "versatile" module of 9 crosses (), of a type (: type 1) of fourth generation system, D5 (representative), representative, Figures

106, 107, 108, 112, 113):

-; 1A; 1 B ; 2/10; 3 ; 4/19; 5 ; 6/24; 7; 8/21; 9; (); 11/26; 12; 13/16; 14A-B; 15A-B; (); 17; 18/28; (); twenty ; (); 22/32; 23A-BC; (); 25/30; (); 27; (); 29A; 29B; (); 31A-B; 31 C; (); 33A; 33B; -

-Polo terminal cycle: 33A-; -Printer initial cycle: 33B-; -stance pointing to fork: 20-, n; ...; + n; ... / ...; + n; (); + n; "..."; = 37 instances: 24 in the common channel and 13 in the autonomous channel corresponding to those listed in succession from 24 to 33B.

; n; ...; + n; ... / ...; + n; "..."; = 28 practical sections.

-Also of the use of the extract of the superflange that in sum has to cover the content of 4 replicas of the representative module, corresponding to the demarcated along 4 equilateral triangles united opposed in pairs laterally (Figure 112), with the due later union of the loose sides by bending with twist on the shared sides, a type of tetra-modular system is incorporated into the body of a tetrahedron (Figure 113), which, since it does not reproduce a single modular shape on the triangular faces, can only project its its contents to the sphere that circumscribes it thus producing types of tetra-modular spherical systems, Figure 123. Otherwise, when tilting the superflange of one or another long side in a closed curve, system types of circular SC configuration are produced. Representative figures 114 and 115, 116 and 117, representative of their congeners from the circular mono-modular type onwards, in the adaptation of the contents between the outer arc and the sides that form an internal angle of: 360 ° to achieve types of mono-modular systems, 180 ° for bi-modular system types, 120 ° for tri-modular systems, 90 ° for type of tetra-modular systems, 72 ° for type of penta-modular systems, 60 ° for type of hexa-modular systems, 51 ° 25 ^' for type of hepta-modular systems, 45 ° for type of octa-modular systems.

 -Also of the inclination in closed curve of one of the sides of the superfranja so that it covers the number of replicas of the versatile module that are needed, in a semicircunference of 254 ° 19 \ CS resulting plane of which joining its straight sides it is transformed into a generic type of configuration SC straight cone, representative of types of systems of conical configuration SC of varying degree of inclination of the lateral surface, and of similar systems of configuration SC cone stepped, representative Figures 118 and 119.

- These types of conical SC configuration systems can transmit their contents to the particular hemispheres that circumscribe them, resulting in hemispherical CS system types conformed by a replica concert of the versatile module of 9 crossovers () hemisphere cap, representative figures 120 and 121.

 -Register instances that make up the "versatile" module of 9 crosses (), of seventh generation system, hexa-modular, D5 (representative), of circular, representative SC configuration (Figures 114, 115):

-; 1 B ; 2/10; 3 ; 4/19; 5 ; 6/24; 7; 8/21; 9; (); 11/26; 12; 13/16; 14A-B; 15A-B; (); 17; 18/28; (); twenty ; (); 22/32; 23A; 23B; 23C; 1A; (); 25/30; (); 27; (); 29A; 29B; (); 31A; 31 B; 31C; (); 33A; 33B; - Cycle terminal pole: 33A; Initial pole of cycle: 33B.

n; ...; + n; ... / ...; + n; (); + n; "..."; = 40 instances: 26 in the common channel and 14. in the autonomous channel; n; ...; + n; ... / ...; + n; "..."; = 31 practical sections. Likewise the module or the set of its replicas that are required of the super strip, can suffer inclination on both sides, split in hemispheres (see Figure 122), and adapt each hemisphere in semicircunferences of 254 ° 33 ~ of internal angle (see Figure 123) comprising the lateral surfaces of a double straight cone (see representative Figure 124) from which the contents are projected to the sphere circumscribing it, reproducing the nucleus of congeners of the spherical system type visualized by the tetrahedron. Figures 125, 126, 127 and 128.

-Register of instances that make up the "versatile" module of 9 crosses (), of the type of third generation systems bi, tri, tetra and penta-modular, D5 (representative), of spherical configuration SC, representative (Figures 125, 126 , 127 and 128):

-; 23A-B-C-1A; 1 B ; 2/10; 3 ; 4/19; 5 ; 6/24; 7; 8/21; 9; (); 11/26; 12; 13/16; 14A-B; 15A-B; (); 17; 18/28; (); twenty ; (); 22/32; (); 25/30; (); 27; (); 29A; 29B; (); 31A-B; 31 C; (); 33A; 33B; - Cycle terminal pole: 33A; Initial pole of cycle: 33B.

n; ...; + n; ... / ...; + n; (); + n; "..."; = 36 instances: 23 in the common channel and 13 in the autonomous channel; n; ...; + n; ... / ...; + n; "..."; = 27 practical sections.

-Variable versatile module with polycyclic dynamics via transfer

 The variation in the representative versatile pattern module, from the flow of the initial pole coming together in the identified instance 23A (see Figure 129), involves the transposition of its terminal pole to the adjacent module in the plasma of monocyclic and polycyclic operating system types via transfer , and the partial conditioning in the numbering that identifies its modular instances with respect to its referent (see Figure 130). The lineage of this variable grows parallel to that of its referent.

 -Registration of instances that make up the "versatile" module of 9 crosses () of polycyclic dynamics via transfer (D5), of the type of system -pattern- (tenth generation) representative, (compare with Figures 130 and 131):

-; 1A; 1 B ; 1 C ; 1 D; 1 E; 2/10; 3 ; 4/19; 5 ; 6/23; 7; 8/21; 9; (); 11/25; 12; 13/16; 14 TO ; 14B; 15A; 15B; (); 17; 18/27; (); twenty ; (); 22/31; (); 24/29; (); 26; (); 28A; 28B; (); 30A; 30B; 30C; (); 32A; 32B; -

-Polo terminal cycle: 32A-; - Initial cycle pole: 32B-; -stance pointing to fork: 20-. n; ...; + n; ... / ...; + n; (); + n; "..."; = 42 instances: 28 in the common channel, and 14 in the autonomous channel corresponding to those in succession listed from 23 to 32B. -n; ...; + n; ... / ...; + n; "..."; = 33 practical sections.

 -Registration of instances that make up the "versatile" module of 9 crosses (), of polycyclic dynamics via transfer of the representative -primitive-system type, (see Figure 132):

-; 1A-B-C-D-E; 2/10; 3 ; 4/19; 5 ; 6/23; 7; 8/21; 9; (); 11/25; 12; 13/16; 14A-B-15A-B; (); 17; 18/27; (); twenty ; (); 22/31; (); 24/29; (); 26; (); 28A-B; (); 30A-B-C; (); 32A-B; - n; ...; + n; ... / ...; + n; (); + n; "..."; = 31 instances: 21 in the common channel and 10 in the autonomous channel; n; ...; + n; ... / ...; + n; "..."; = 22 practical sections.

-Module of system type Matrix (zero generation): 32 instances: 21 in the common channel and 11 in the autonomous channel, seated in 24 sections.

 -Register instances that make up the "versatile" module of 9 crosses (), of polycyclic dynamics via transfer of the system type of eighth generation, D5 (representative), representative (Figures 133, 134, 135 and 136):

 5 -; 1A; 1 B ; 1 C ; 1 D; 1 E; 2/10; 3 ; 4/19; 5 ; 6/23; 7; 8/21; 9; (); 11/25; 12; 13/16; 14A-B; 15A-B; (); 17; 18/27; (); twenty ; (); 22/31; (); 24/29; (); 26; (); 28A; 28B; (); 30A; 30B; 30C; (); 32A; 32B; - Cycle terminal pole: 32A; Initial pole of cycle: 32B.

 n; ...; + n; ... / ...; + n; (); + n; "..."; = 40 instances: 26 in the common channel and 14 in the autonomous channel; n; ...; + n; ... / ...; + n; "..."; = 31 practical sections.

10 -Register instances that make up the "versatile" module of 9 crosses (), of polycyclic dynamics via transfer of the type of fourth generation system, D5 (representative), representative, (Figures 137, 138):

 -; 1A-B-C-D; 1 E; 2/10; 3 ; 4/19; 5 ; 6/24; 7; 8/21; 9; (); 11/25; 12; 13/16; 14A-B; 15A-B; (); 17; 18/27; (); twenty ; (); 22/31; (); 24/29; (); 26; (); 28A; 28B; (); 30A-B; 30C; (); 33A; 15 33B; - -Polo terminal cycle: 33A-; -Printer initial cycle: 33B-.

 n; ...; + n; ... / ...; + n; (); + n; "..."; = 36 instances: 23 in the common channel and 13 in the autonomous channel; n; ...; + n; ... / ...; + n; "..."; = 27 practical sections.

 -Classes of "versatile" module - of 10 crosses (), and types of systems they generate.

-The first class (class 1) of variations that translate into more complex labyrinth systems, 20 that are offered from versatile and versatile systems of polycyclic dynamics via transfer, -formed by odd number of modules and with instance in sector 14A -B (assume in this situation identified simply as -instance 14) -, is that even pointing in the same sense that leads (the clockwise in the context of the system), now directs its flow to the instance 14 of contiguous module, resulting in own sector 25 the crossing to register -14/14 ^' - by reason of the restoration of the flow that previously led to the instance 15A or 15A-B that consequently simultaneous now comes from instance 14 of the preceding module , ordering that involves the course of 2 revolutions per cycle. (Figure 139).

 -Registration of instances that make up the "versatile" module of 10 crosses () class 1, 30 of the system type -Patron- (seventh generation) of modular configuration odd number.

 Confront Figures 139 and 140:

-; 1A; 1 B ; 2/10; 3 ; 4/19; 5 ; 6/24; 7; 8/21; 9; (); 11/26; 12; 13/16; 14/14 ^" ; 15A; 15B; (); 17; 18/28; (); 20; (); 22/32; 23A; 23B; 23C; (); 25/30; (); 27; () 29A; 29B; (); 31A; 31 B; 31 C; (); 33A; 33B; -.

35 -Polo terminal cycle: 33A-; -Printer initial cycle: 33B-; Instance pointing branch: 20 n; ...; + n; ... / ...; + n; (); + n; "..."; = 41 + 1 (: 14 ^" ) = 42 instances: 28 in the common channel, and 14 in the autonomous channel corresponding to those listed from 24 to 33B -n; ...; + n; ... / ... ; + n; "..."; = 32 practical sections.

-Register instances that make up the "versatile" module of 10 crosses () class 1, of the type of system -primitive- of modular configuration odd, representative number (Figure 141):

-; 1A-B; 2/10; 3 ; 4/19; 5 ; 6/24; 7; 8/21; 9; (); 11/26; 12; 13/16; 14/14 ^' ; 15A-B; (); 17; 18/28; (); twenty ; (); 22/32; 23A-BC; (); 25/30; (); 27; (); 29A-B; (); 31A-BC; (); 33A-B; -. 5 n; ...; + n; ... / ...; + n; (); + n; "..."; = 33 + 1 (: 14 ^' ) = 34 instances: 24 in the common channel and 10 in the autonomous channel; n; ...; + n; ... / ...; + n; "..."; = 23 practical sections.

 -Module of system type-matrix (zero generation): 35 instances: 24 in the common channel and 11 in the autonomous channel, seated in 24 sections.

 -Registration of instances that make up the "versatile" module of 10 crosses () class 101, of the type of system -of second generation-, tri-modular, of spherical SC configuration, representative, Figures 142 and 143.

 (representative of the hepta-modular congenere module of Figure 144):

-; 1B; 2/10; 3; 4/19; 5; 6/24; 7; 8/21; 9; (); 11/26; 12; 13/16; 14/14 ^' ; 15A-B; (); 17; 18/28; (); twenty ; (); 22/32; 23A-BC-1A; (); 25/30; (); 27; (); 29A; 29B; (); 31A-B; 31C; (); 33A 15; 33B; - Cycle terminal pole: 33A; Initial cycle pole: 33B-.

n; ...; + n; ... / ...; + n; (); + n; "..."; = 36 + 1 (: 14 ^" ) = 37 instances: 24 in the common channel and 13 in the autonomous channel; n; ...; + n; ... / ...; + n;" ... "; = 27 practical sections.

 -Register instances that make up the "versatile" module of 10 crosses () class 1, of the sixth generation system type, hepta-modular, circular SC configuration, D5 20 (representative), representative, - (compare with Figures 145 and 146):

-; 1B; 2/10; 3; 4/19; 5; 6/24; 7; 8/21; 9; (); 11/26; 12; 13/16; 14/14 ^' ; 15A-B; (); 17; 18/28; (); twenty ; (); 22/32; 23A; 23B; 23C; 1A; (); 25/30; (); 27; (); 29A; 29B; (); 31A; 31B; 31C; (); 33A; 33B; - Cycle terminal pole: 33A; Initial cycle pole: 33B -.

n; ...; + n; ... / ...; + n; (); + n; "..."; = 40 + 1 (: 14 ^" ) = 41 instances: 27 in the common channel and 14 in the channel

25 autonomous; n; ...; + n; ... / ...; + n; "..."; = 31 practical sections.

-Registration of instances that make up the "versatile" module of 10 crosses () class 1, of polycyclic dynamics via transfer of the system type -pattern- (eighth generation) of modular configuration odd, representative number (compare with Figures 147 and 148) : -; 1A; 1 B ; 1 C ; 1D; 1E; 2/10; 3 ; 4/19; 5 ; 6/23; 7; 8/21; 9; (); 11/25; 12; 13/16; 14/14 ^' ;

3015A; 15B; (); 17; 18/27; (); twenty ; (); 22/31; (); 24/29; (); 26; (); 28A; 28B; (); 30A; 30B; 30C; (); 32A; 32B; -

-Polo terminal cycle: 32A-; - Initial cycle pole: 32B-; - Instance pointing bifurcation: 20-. n; ...; + n; ... / ...; + n; (); + n; "..."; = 41 + 1 (: 14 ^" ) = 42 instances: 26 in the common channel, and 16 in the autonomous channel corresponding to those in succession enumerated from 23 to 32B. -N; ...; + n; ... / ...; + n; "..."; 35 = 32 practical sections.

 -Registration of instances that make up the "versatile" module of 10 crosses () class 1, of polycyclic dynamics via transfer of the system type -primitive- of modular configuration odd, representative number (Figure 149):

-; 1A-BCDE; 2/10; 3 ; 4/19; 5 ; 6/23; 7; 8/21; 9; (); 11/25; 12; 13/16; 14/14 ^' ; 15A-B; (); 17; 18/27; (); twenty ; (); 22/31; (); 24/29; (); 26; (); 28A-B; (); 30A-BC; (); 32A-B; -. n; ...; + n; ... / ...; + n; (); + n; "..."; = 32 + 1 (: 14 ^" ) = 33 instances: 23 in the common channel and 10 in the autonomous channel.

 -Module of system type-matrix (zero generation): 34 instances: 23 in the common channel and 11 in the autonomous channel, seated in 24 sections.

 -Registration of instances that make up the "versatile" module of 10 crosses () class 1, of polycyclic dynamics via transfer of the type of third generation system, penta-modular, CS spherical, representative. (Figures 150 and 151):

-; 1A-BCD; 1 E; 2/10; 3 ; 4/19; 5 ; 6/23; 7; 8/21; 9; (); 11/25; 12; 13/16; 14/14 ^' ; 15A-B; (); 17; 18/27; (); twenty ; (); 22/31; (); 24/29; (); 26; (); 28A; 28B; (); 30A-B; 30C; (); 32A; 32B; - Cycle terminal pole: 32A; Initial cycle pole: 32B

n; ...; + n; ... / ...; + n; (); + n; "..."; = 36 + 1 (: 14 ^" ) = 37 instances: 24 in the common channel and 13 in the autonomous channel; n; ...; + n; ... / ...; + n;" ... "; = 27 practical sections.

 -Register of instances that make up the "versatile" module of 10 crosses () class 1, of polycyclic dynamics via transfer, of the seventh generation, hepta-modular system type of circular, representative SC configuration. (Figures 152 and 153):

-; 1A; 1 B ; 1 C ; 1 D; 1 E; 2/10; 3 ; 4/19; 5 ; 6/23; 7; 8/21; 9; (); 11/25; 12; 13/16; 14/14 ^' ; 15A-B; (); 17; 18/27; (); twenty ; (); 22/31; (); 24/29; (); 26; (); 28A; 28B; (); 30A; 30B; 30C; (); 32A; 32B; - Cycle terminal pole: 32A; Initial cycle pole: 32B-.

n; ...; + n; ... / ...; + n; (); + n; "..."; = 40 + 1 (: 14 ^' ) = 41 instances: 27 in the common channel and 14 in the autonomous channel; n; ...; + n; ... / ...; + n; "..."; = 31 practical sections.

-For types of circular CS systems of versatile and versatile module of polycyclic dynamics via transfer, of the type of system tri and penta-modular, of 9 and 10 crosses (), if you want, favors the distension that presents this critical sector 14A-B and 14/14 ^' , the arrangement of the environment in the following manner in which 1 or 2 new instances are defined in the sector:

class 2: -...; 13/16; 14 TO ; 14B; 14C; 15A or 15A-B; ...- (see Figures 155 and 156).

class 3: -...; 13/16; 14 TO ; 14B / 14ET; 14C; 15A or 15A-B; ...- (see Figures 161 and 162).

• Register of instances that make up the "versatile" module of 9 crosses () class 2, of the representative -pattern- (tenth generation) type, (compare with Figures 154 and 155):

 -; 1A; 1 B ; 2/10; 3 ; 4/19; 5 ; 6/24; 7; 8/21; 9; (); 11/26; 12; 13/16; 14 TO ; 14B; 14C; 15A; 15B; (); 17; 18/28; (); twenty ; (); 22/32; 23A; 23B; 23C; (); 25/30; (); 27; (); 29A; 29B; (); 31A; 31 B; 31 C; (); 33A; 33B; -

-Polo terminal cycle: 33A-; -Printer initial cycle: 33B-; - instance that signals bifurcation: 20-. n; ...; + n; ... / ...; + n; (); + n; "..."; = 43 instances: 29 in the common channel, and 14 in the autonomous channel corresponding to those listed in succession from 24 to 33B. -n; ...; + n; ... / ...; + n; "..."; = 34 practical sections-.

-Registration of instances that make up the "versatile" module of 9 crosses () class 2, of the representative -primitive-system type: -; 2/10; 3 ; 4/19; 5 ; 6/24; 7; 8/21; 9; (); 11/26; 12; 13/16; 14A-BC-15A-B; (); 17; 18/28;

(); twenty ; (); 22/32; 23A-B-C-1A-B; (); 25/30; (); 27; (); 29A-B; (); 31A-B-C; (); 33A-B; -. n; ...; + n; ... / ...; + n; (); + n; "..."; = 31 instances: 21 in the common channel and 10 in the autonomous channel; n; ...; + n; ... / ...; + n; "..."; = 22 practical sections.

-Module of system type-matrix (zero generation) = 33 instances: 22 in the common channel and

11 in the autonomous channel; n; ...; + n; ... / ...; + n; "..."; = 24 practical sections.

 -Register instances that make up the "versatile" module of 9 crosses () class

2, -fifth generation-, tri-modular, D5 (representative), of circular, representative SC configuration (Figures 156, 157):

-; 1 B ; 2/10; 3 ; 4/19; 5 ; 6/24; 7; 8/21; 9; (); 11/26; 12; 13/16; 14 TO ; 14B; 14C; 15A-B; ();

17; 18/28; (); twenty ; (); 22/32; 23A-B-C-1A; (); 25/30; (); 27; (); 29A; 29B; (); 31A; 31 B;

31 C; (); 33A; 33B; - Cycle terminal pole: 33A; Initial cycle pole: 33B-.

n; ...; + n; ... / ...; + n; (); + n; "..."; = 39 instances: 25 in the common channel and 14 in the autonomous channel; n; ...; + n; ... / ...; + n; "..."; = 30 practical sections.

-Register instances that make up the "versatile" module of 9 crosses () class

2 of polycyclic dynamics via transfer, of the type of system -pattern- (eleventh generation) representative, (compare with Figures 154 and 155):

 -; 1A; 1 B ; 1 C ; 1 D; 1 E; 2/10; 3 ; 4/19; 5 ; 6/23; 7; 8/21; 9; (); 11/25; 12; 13/16; 14 TO ; 14B; 14C; 15A; 15B; (); 17; 18/27; (); twenty ; (); 22/31; (); 24/29; (); 26; (); 28A; 28B; (); 30A; 30B; 30C; (); 32A; 32B; -.

 -Polo terminal cycle: 32A-; - Initial cycle pole: 32B-; -stance pointing to fork: 20-. n; ...; + n; ... / ...; + n; (); + n; "..."; = 43 instances: 29 in the common channel and 14 in the autonomous channel corresponding to those in succession enumerated from 23 to 32B. -n; ...; + n; ... / ...; + n; "..."; = 32 practical sections-.

 -Register instances that make up the "versatile" module of 9 crosses () class 2, of polycyclic dynamics via transfer, of the type of system -primitive-:

 -; 1A-B-C-D-E; 2/10; 3 ; 4/19; 5 ; 6/23; 7; 8/21; 9; (); 11/25; 12; 13/16; 14A-B-C-15A-B; (); 17; 18/27; (); twenty ; (); 22/31; (); 24/29; (); 26; (); 28A-B; (); 30A-B-C; (); 32A-B; -. n; ...; + n; ... / ...; + n; (); + n; "..."; = 31 instances: 21 in the common channel and 10 in the autonomous channel; n; ...; + n; ... / ...; + n; "..."; = 22 practical sections.

 -Module type of system-matrix (zero generation): 32 instances: 21 in the common channel and 11 in the autonomous channel, seated in 23 sections.

 -Registration of instances that make up the "versatile" module of 9 crossings () class 2, of polycyclic dynamics via transfer, of the tenth generation system type, of circular, representative SC configuration (Figures 158 and 159):

 -; 1A; 1 B ; 1 C ; 1 D; 1 E; 2/10; 3 ; 4/19; 5 ; 6/23; 7; 8/21; 9; (); 11/25; 12; 13/16; 14 TO ; 14B; 14C; 15A-B; (); 17; 18/27; (); twenty ; (); 22/31; (); 24/29; (); 26; (); 28A; 28B; (); 30A; 30B; 30C; (); 32A; 32B; - Cycle terminal pole: 32A; Initial cycle pole: 32B-.

n; ...; + n; ... / ...; + n; (); + n; "..."; = 42 instances: 28 in the common channel and 14 in the autonomous channel; n; ...; + n; ... / ...; + n; "..."; = 31 practical sections.

 -Register of instances that make up the "versatile" module of 10 crosses () class 3, of the system type -pattern- (eighth generation), of plural modular configuration odd number:

5 -; 1A; 1 B ; 2/10; 3 ; 4/19; 5 ; 6/24; 7; 8/21; 9; (); 11/26; 12; 13/16; 14 TO ; 14B / 14B ^' ; 14C; 15A; 15B; (); 17; 18/28; (); twenty ; (); 22/32; 23A; 23B; 23C; (); 25/30; (); 27; (); 29A; 29B; (); 31A; 31 B; 31C; (); 33A; 33B; -.

 -Polo terminal cycle: 33A-; -Printer initial cycle: 33B-; -Instance that signals bifurcation: 20-. n; ...; + n; ... / ...; + n; (); + n; "..."; = 43 + 1 (: 14B ~) = 44 instances: 30 in the common channel and 14 in the 10 autonomous channel corresponding wings in succession enumerated from 24 to 33B- -n; ...; + n; ... / ...; + n; "..."; = 33 practical sections-.

 -Register of instances that make up the "versatile" module of 10 crosses () class 3, of the type of system -primitive- of modular conformation odd, representative number:

-; 1A-B; 2/10; 3 ; 4/19; 5 ; 6/24; 7; 8/21; 9; (); 11/26; 12; 13/16; 14 TO ; 14B / 14B ^' ; 14C-15A-B 15; (); 17; 18/28; (); twenty ; (); 22/32; 23A-BC; (); 25/30; (); 27; (); 29A-B; (); 31A-BC; (); 33A-B; -.

n; ...; + n; ... / ...; + n; (); + n; "..."; = 34 + 1 (: 14B ^' ) = 35 instances: 25 in the common channel and 10 in the autonomous channel; n; ...; + n; ... / ...; + n; "..."; = 23 practical sections.

 -Module of system type-matrix (zero generation): 36 instances: 25 in the common channel and 20 in the autonomous channel, settled in 25 sections.

 -Register of instances that make up the "versatile" module of 10 crosses () class 3, of system type -of fourth generation- tri-modular, D5 (representative), of circular SC configuration, (Figures 162 and 163):

 -; 1 B ; 2/10; 3 ; 4/19; 5 ; 6/24; 7; 8/21; 9; (); 11/26; 12; 13/16; 14 TO ; 14B714B; 14C; 15A-B 25; (); 17; 18/28; (); twenty ; (); 22/32; 23A-B-C-1A; (); 25/30; (); 27; (); 29A; 29B; (); 31A;

 31 B; 31 C; (); 33A; 33B; - Cycle terminal pole: 33A; Initial cycle pole: 33B-.

n; ...; + n; ... / ...; + n; (); + n; "..."; = 39 + 1 (: 14B ^' ) = 40 instances: 26 in the common channel and 14 in the autonomous channel; n; ...; + n; ... / ...; + n; "..."; = 30 practical sections.

 -Register of instances that make up the "versatile" module of 10 crosses () class 3, 30 of polycyclic dynamics via transfer, of the type of system -pattern- (ninth generation) representative:

 -; 1A; 1 B ; 1 C ; 1 D; 1 E; 2/10; 3 ; 4/19; 5 ; 6/23; 7; 8/21; 9; (); 11/25; 12; 13/16; 14 TO ; 14B714B; 14C; 15A; 15B; (); 17; 18/27; (); twenty ; (); 22/31; (); 24/29; (); 26; (); 28A; 28B; (); 30A; 30B; 30C; (); 32A; 32B; -.

35 -Polo terminal of cycle: 32A -; - Initial pole of cycle: 32B-; -stance pointing to fork: 20-. n; ...; + n; ... / ...; + n; (); + n; "..."; = 43 + 1 (: 14B ^' ) = 44 instances: 30 in the common channel and 14 in the autonomous channel corresponding to those in succession enumerated from 23 to 32B. -n; ...; + n; ... / ...; + n; "..."; = 34 practical sections.

-Register instances that make up the "versatile" module of 10 crosses () class 3 of polycyclic dynamics via transfer, of the representative -primitive-system type:

-; 1A-B-C-D-E; 2/10; 3 ; 4/19; 5 ; 6/23; 7; 8/21; 9; (); 11/25; 12; 13/16; 14 TO ; 14B / 14B-; 14C-15A-B; (); 17; 18/27; (); twenty ; (); 22/31; (); 24/29; (); 26; (); 28A-B; (); 30A-B-C; (); 32A-B; -.

n; ...; + n; ... / ...; + n; (); + n; "..."; = 33 + 1 (: 14B ^" ) = 34 instances: 24 in the common channel and 10 in the autonomous channel; n; ...; + n; ... / ...; + n;" ... "; = 24 practical sections.

 -Module type of system-matrix (zero generation): 35 instances: 24 in the common channel and 11 in the autonomous channel, seated in 25 sections.

 -Registration of instances that make up the "versatile" module of 10 class 3 crossings, of polycyclic dynamics via transfer, of system type -of eighth generation-, tri- modular, of circular, representative SC configuration (Figures 164 and 165) :

-; 1A; 1 B ; 1 C ; 1 D; 1 E; 2/10; 3 ; 4/19; 5 ; 6/23; 7; 8/21; 9; (); 11/25; 12; 13/16; 14 TO ; 14B / 14B ^' ; 14C; 15A-B; (); 17; 18/27; (); twenty ; (); 22/31; (); 24/29; (); 26; (); 28A; 28B; (); 30A; 30B; 30C; (); 32A; 32B; -. Terminal pole cycle: 32A; Initial pole of cycle: 32B.

n; ...; + n; ... / ...; + n; (); + n; "..."; = 42 + 1 (: 14B ^" ) = 43 instances: 29 in the common channel and 14 in the autonomous channel, n; ...; + n; ... / ...; + n;" ... "; = 33 practical sections.

- Plastic modules 1 and 2 of 9 and 10 crosses () respectively, and 1 and 2 of 9 ½ and 10 ¹ A crosses (), respectively, of types of SC configuration systems

 The pipeline of a generic type of module called -plastic-, offers the double alternative of location of the branch pointing to bifurcation, an alternative of which involves a crossing section (), thus behaving module types 1 and 2, of 9 and 10 crosses (), respectively, that identify their instances in a partially different way but that register in parallel their relatives and those of their offspring that evolve to the point of partial mergers with their respective specular similies in binomials, a type of which involves the addition of one more section in which flow crossing occurs between the two, which means the mutation to plastic module types 1 and 2 of 9 Vi and 10 Vi crosses () respectively. This modular frame is shaped to fit both a square and a triangular CS (see representative figures 166, 167, 168, 169, 170, 171, 172 and 173), which claim independent records given the greater capacity of the second for contain sections provided intrinsically instances; conforming from one and another inscriptions in sum, types of systems of diverse variety of forms of flat surface configurations, from which it evolves to pyramidal and polyhedral, both which in turn project their contents to bodies of curved surface configurations of types of systems of SC configuration of generic spherical denomination (representative of the ellipsoid) conformed by modules cap of sphere or of hemisphere.

-Register of component instances of plastic module 1, -pattern-, of 9 crosses (), and its primitive and matrix ancestors, square SC configuration, Figures 168 and 174. -; one ; 2/12; 3A; 3B; 3C; 3D; 4/13; 5/24; 6; 7/17; 8; 9/19; 10/30; 11A; 11 B; 11 C; (); (); 14 TO ; 14B; 15/22; 16/26; (); 18; (); 20/28; 21A; 21 B; 21 C; 21 D; (); 2. 3 ; (); 25; (); 27; (); 29A ; 29B; (); 31A; 31 B; ED.

 -Polo terminal cycle: 31A-; -Prolling initial of cycle: 31 B-; - Instance that signals bifurcation: 23-. n; ...; + n; ... / ...; + n; (); + n; "..."; = 42 instances: 33 in the common channel, and 9 in the autonomous channel: succession of enumerated instances from 25 to 31 B. -n; ...; + n; ... / ...; + n; "..."; = 33 practical sections. 5 -Primitive system-module: 31 instances: 24 in the common channel and 7 in the autonomous channel, seated in 22 sections, Figure 166.

 -Matrix-system module (zero generation):

 -; one ; 2/12; "3A-B-C-D"; 4/13; 5/24; 6; 7/17; 8; 9/19; 10/30; "11A-B-C"; (); (); 14A-B; 15/22; 16/26; (); 18; (); 20/28; "21A-B-C-D"; (); 2. 3 ; (); 25; (); 27; (); 29A-B; (); 31A; 31 B; ED. 10 n; ...; + n; ... / ...; + n; (); + n; "..."; = 32 instances: 24 in the common channel and 8 in the autonomous channel; n; ...; + n; ... / ...; + n; "..."; = 23 practical sections.

 -Register instances that make up the plastic module 1, -pattern-, of 9 crosses (), and its primitive and matrix ancestors, configuration SC equilateral triangle, contrast with Figures 169 and 176.

 fifteen -; one ; 2/12; 3A; 3B; 3C; 3D; 3E; 3F; 3G; 3H; 3Í; 4/13; 5/24; 6; 7/17; 8; 9/19; 10/30; 11A;

 11 B; 11 C; 11 D; 11 E; (); (); 14 TO ; 14B; 15/22; 16/26; (); 18; (); 20/28; 21A; 21 B; 21 C; (); 2. 3 ; (); 25; (); 27; (); 29A; 29B; (); 31 A; 31 B; ED-.

 -Polo terminal cycle: 31A-; -Prolling initial of cycle: 31 B-; - Instance that signals bifurcation: 23-. n; ...; + n; ... / ...; + n; (); + n; "..."; = 48 instances: 39 in the common channel, and 9 in the autonomous channel: 20 succession of enumerated instances from 25 to 31B. -n; ...; + n; ... / ...; + n; "..."; = 39 practical sections.

 -System module -primitive-: 31 instances: 24 in the common channel and 7 in the autonomous channel, seated in 22 sections, Figure 167.

 -Matrix-system module (zero generation):

 -; one ; 2/12; "3A-B-C-D-E-F-G-H-I"; 4/13; 5/24; 6; 7/17; 8; 9/19; 10/30; "11A-B-C-D-E"; (); (); 25 14A-B; 15/22; 16/26; (); 18; (); 20/28; "21A-B-C"; (); 2. 3 ; (); 25; (); 27; (); 29A-B; (); 31A; 31 B; ED-.

 n; ...; + n; ... / ...; + n; (); + n; "..."; = 32 instances: 24 in the common channel and 8 in the autonomous channel; n; ...; + n; ... / ...; + n; "...";

 = 23 practical sections.

30 -Register instances that make up the plastic module 1 of 9 crossovers (), SC configuration isosceles triangle, type-first generation-octa-modular system, SC octagonal configuration, contrast with Figure 193.

 -; one ; 2/12; "3A-B-C-D-E-F-G-H-I"; 4/13; 5/24; 6; 7/17; 8; 9/19; 10/30; "11A-B-C-D-E"; (); (); 14 TO ; 14B; 15/22; 16/26; (); 18; (); 20/28; "21A-B-C"; (); 2. 3 ; (); 25; (); 27; (); 29A-B; (); 35 31 A; 31 B; ED-.

 n; ...; + n; ... / ...; + n; (); + n; "..."; = 33 instances: 25 in the common channel and 8 in the autonomous channel; n; ...; + n; ... / ...; + n; "..."; = 23 practical sections.

-Register instances that make up the plastic module 2, -pattern-, of 10 crosses (), and its primitive and matrix ancestors, SC square configuration, Figures 172 and 175. -; 1; 2/12; 3A; 3B; 3C; 3D; 4/13; 5/25; 6; 7/18; 8; 9/20; 10/32; 11A; 11B; 11C; (); (); 14; fifteen ; 16/23; 17/28; (); 19; (); 21/30; 22A, 22B, 22C; 22D; 24/26; (); (); 27; (); 29; (); 31 A; 31 B; (); 33A; 33B; ED-. -Polo terminal cycle: 33A-; -Printer initial of cycle: 33B; instance that signals bifurcation: 14-.

n; ...; + n; ... / ...; + n; (); + n; "..."; = 42 instances: 32 in the common channel, and 10 in the autonomous channel corresponding to those in succession listed from 26 to 33B.

n; ...; + n; ... / ...; + n; "..."; = 33 practical sections.

 -System module -primitive-: 33 instances: 25 in the common channel and 8 in the autonomous channel, seated in 23 sections, Figure 170.

-Matrix-system module (zero generation):

 -; one ; 2/12; "3A-B-C-D"; 4/13; 5/25; 6; 7/18; 8; 9/20; 10/32; "11A-B-C"; (); (); 14; fifteen ; 16/23;

17/28; (); 19; (); 21/30; "22A-B-C-D"; 24/26; (); (); 27; (); 29; (); 31A-B; (); 33A; 33B; ED-. n; ...; + n; ... / ...; + n; (); + n; "..."; = 34 instances: 25 in the common channel and 9 in the autonomous channel; n; ...; + n; ... / ...; + n; "..."; = 23 practical sections.

 -Register instances that make up the plastic module 2, -pattern-, of 10 crosses

(), and its primitive and matrix ancestors, configuration SC equilateral triangle, Figures 173 and 177.

 -; one ; 2/12; 3A; 3B; 3C; 3D; 3E; 3F; 3G; 3H; 3Í; 4/13; 5/25; 6; 7/18; 8; 9/20; 10/32; 11A; 11B; 11C; 11D; 11E; (); (); 14; fifteen; 16/23; 17/28; (); 19; (); 21/30; 22A; 22B; 22C; 24/26; (); (); 27; (); 29; (); 31 A; 31 B; (); 33A; 33B; ED-.

 Terminal cycle pole: 33A; Initial cycle pole: 33B; instance that signals bifurcation: 14 -. n; ...; + n; ... / ...; + n; (); + n; "..."; = 48 instances: 38 in the common channel, and 10 in the autonomous channel corresponding to those listed in succession from 26 to 33B. -n; ...; + n; ... / ...; + n; "..."; = 38 practical sections.

-System module -primitive-: 33 instances: 25 in the common channel and 8 in the autonomous channel, seated in 23 sections, Figure 171.

-Matrix-system module (zero generation):

 -; one ; 2/12; "3A-B-C-D-E-F-G-H-Í"; 4/13; 5/25; 6; 7/18; 8; 9/20; 10/32; "11A-B-C-D-E"; (); (); 14; fifteen ; 16/23; 17/28; (); 19; (); 21/30; "22A-B-C"; 24/26; (); (); 27; (); 29; (); 31A-B; (); 33A; 33B; ED-.

n; ...; + n; ... / ...; + n; (); + n; "..."; = 34 instances: 25 in the common channel and 9 in the autonomous channel; n; ...; + n; ... / ...; + n; "..."; = 23 practical sections.

 -Types of systems inscribed in types of configuration SC polygonal, irregular, pyramidal, hemispherical, starry, polyhedral, hemispherical and spherical, coming from the plastic modules of configuration SC square and triangular 1 and 2 of 9 and 10 crosses () and 9 Vi and 10 Vi respectively

-The types of plastic module 1 and 2 of square CS that are representatively encompassed according to modular composition between the primitive and pattern systems, object of Figures 166, 168 (compare with Figures 170, 172, 174, 175), conform elementally with 4 replicas in function (Representative figure 178), types of tetra-modular systems inscribed in square polygons (see Figure 179) from which the nucleus of their congeners inscribed in corresponding polygon types is inferred, through (as has been applied repeatedly) the appropriate variation of the internal angle of the module for example the module of Figure 180, plural function conformer of the penta-modular system type of Figure 181 that with the tetra-modular of Figure 179 are representative of congeners counting from the mono- modular (Figure 182), and of lineages of congeners. -A plurality of 3 replicas of a particular type of the plastic modules 1 or 2 of square CS, likewise can be aligned and adjusted functionally, opposed to the alignment of a trio formed by its specular similes (counting in

10 sum 6) sharing sides and connected alternating the flow from one side to another side of the road that make up the instances of transit between modules (Figure 183 representative of both types of plastic module), resulting CS that by means of the union of loose sides and total bending of the sides in contact as axis, manages to incorporate types of cubic SC configuration systems, (see Figure 184 representative of types of cubic systems of plastic modules),

15 cubic body that, although perfectly functional, is also suitable for projecting the contents of its faces into caps of the sphere that circumscribes it (representative figures 185 and 186), constituting (generalising) types of hex-modular spherical systems with source ordering in cubic SC configuration system types, see Representative Figures 187 and 188.

 Also, from any particular one of the types of plastic modules 1 and 2 of square SC configuration, their contents can be transferred to a shell comprised between meridians of a sphere or an ellipsoid whose angle between meridians depends on the number of modules that make up the system: 360 ° / n ° of modules, types of cap module (Figure 189) whose due multiplicity of replications in joint function constitute the nucleus of congeners

25 of types of spherical CS systems (representative) and elpsoids, coming (generalizing) from the plastic modules (representative figures 190 and 191).

 -6 replicas of any particular one of the plastic modules 1 and 2 of the SC equilateral triangle configuration, can be ordered elementally forming a type of hexagonal, hexa-modular configuration system SC (representative Figure 192), from which the core of

30 their congeners inscribed in corresponding polygons by means of the suitable reordering of the contents to isosceles triangles whose disparity angle (internal angle of the module in the type of system), varies as it has been seen, according to the number of modules that conform the type of system : 360 ° / n ° of modules, for example the type of octa-modular system of Figure 193 that with the hexa-modular of Figure 192 and the bi-modular of irregular SC configuration of the Figure

35 194, are representative of congeners counting from the mono-modular type, and lineages of congeners).

-As in the constitution of previous polygonal system types, with same sides in common around the central point, a number of 3, 4 and 5 replicas of any particular of the. plastic modules of configuration SC equilateral triangle, make up surface configurations particular such (representative figures 195 and 196) that through the union of loose sides and total bending of the sides shared as axis, is achieved the incorporation of types of pyramidal SC configuration systems, 3, 4 and 5 face modules ( Representative figures 197 and 198), representative of congeners and similar system types of SC step pyramid configuration. In function to obtain types of pyramidal SC configuration systems hexa modular, hecta and octa-modular, and or a particular degree of inclination of the faces of the pyramid that is intended, such plastic module can transfer its contents to one of isosceles triangle shape that in due plural function of replicas it agrees.

 -These types of pyramidal SC configuration systems can transfer the content of their module faces, to hemisphere cap modules (representative of the semielipsoid) that circumscribes them (representative Figure 199), constituting types of hemispherical systems (Representative Figures 200 and 201). ), among which bi-modular systems can be included by transferring the contents from the hemisphere's hemisphere cap module to both sides of a hemisphere.

-The variation that involves only modular types of modular conformation system even number from hexa-modular onwards, relative to the association of any type of plastic module 1

0 2 of CS equilateral triangle with its specular simulation -in which transit of the flow is made between them-, it is captured by a partial spatial fusion of both types of opposed modules, product of the assimilation in a single alignment (which appears traced in dashed line in Figures 203, 204, 206 and 207), which in binomials of primitive system types and matrices among others corresponds to the non-connected transit instances between modules: 3A-BCDEF-GH and 3 ^' (see Figure 202 ), rearrangement that distributes asymmetrically such common space so that each type of module requires particular registers of modular instances (see Figures 203, 204 and 205, and 206, 207 and 208).

 -Register of modular instances of the binomial comformado by the plastic module 1, -pattern-, of 9 crosses (), SC configuration, partially fused with its functional specular simile; and its predecessors: primitive and matrix, to count with Figures 203 and 205.

-Module plastic 1 of 9 crosses (), pattern, member 1 of its modular binomial: -; V; 2712 ^' ; 3 ^' ; 4/13; 5/24; 6; 7/17; 8; 9/19; 10/30; 11A; 11 B; 11C; 11 D; 11 E; (); (); 14 TO ; 14B; 15/22; 16/26; (); 18; (); 20/28; 21A; 21 B; 21 C; (); 2. 3 ; (); 25; (); 27; (); 29A; 29B; (); 31A; 31 B; ED-.

-Polo terminal cycle: 31 A ^' -; -Initial cycle start: 31 B ^' -; - instance pointing branch: 23 -. n; ...; + n; ... / ...; + n; (); + n; "..."; = 40 instances: 31 in the common channel, and 9 in the autonomous channel corresponding to those in succession enumerated from 25 to 31 B. -n; ...; + n; ... / ...; + n; "..."; = 31 practical sections.

 -Simil functional specular of asymmetric modular composition with respect to the plastic module

1 of 9 crosses (), pattern; integrant 2 of modular binomial:

-; one ; 2/12; 3A; 3B; 3C; 3D; 3E; 3F; 3G; 3H; 4713 ^' ; 5724 ^' ; 6 ^' ; 7717 ^' ; 8 ^' ; 9719 ^' ; 10730 ^' ; 11A ^' ; 11B ^" ; 11C ^" ; 11D ^" ; 11E ^" ; (); (); 14Α ^' ; 14Β ^' ; 15722 ^" ; 16726 ^' ; (); 18 ^" ; (); 20728 ^' ; 21Α ^' ; 21Β ^' ; 21C; (); 23 ^" ; (); 25 ^' ; (); 27 ^" ; (); 29Α ^" -Β ^" ; (); 31 Α ^" ; 31 Β ^" ; ED ^' .-.

 -System module -primitive-: 31 instances: 24 in the common channel and 7 in the autonomous channel, seated in 22 sections, Figure 204.

-Module plastic 1 of 9 crosses (), -matrix-, member 1 of its modular binomial:

-; 1 ^" ; 2712 ^" ; 3 ^" ; 4/13; 5/24; 6; 7/17; 8; 9/19; 10/30; 11A-BCDE; (); (); 14A-B; 15/22; 16/26; ); 18; (); 20/28; 21A-BC; (); 23; (); 25; (); 27; (); 29A-B; (); 31A; 31B; ED-.

-Polo terminal of cycle: 31 A ^" -; -Polo initial of cycle: 31 B ^' -; -stance that signals bifurcation: 23 -. N; ...; + n; ... / ...; + n ; (); + n;; = 32 instances: 23 in the common channel, and 9 in the autonomous channel corresponding to those in succession enumerated from 25 to 31 B. -n; ...; + n; ... / ...; + n; "..."; = 23 practical sections.

 Functional specular mirror of asymmetric modular composition with respect to the plastic module

1 of 9 crosses (), -matrix-; integrant 2 of modular binomial:

-; one ; 2/12; 3A-BCDEFGH; 4713 ^' ; 5724 ^" ; 6 ^" ; 7717 ^" ; 8 ^" ; 9719 ^" ; 10730 ^" ; 11A ^" -B ^' -C ^' -D ^' -E ^" ; (); (); 14A ^" -B ^" ; 15722 ^" ; 16726 ^' ; ().; 18 ^" ; (); 20728 ^" ; 21A ^" -B ^' -C ^" ; (); 23 ^' ; (); 25 ^' ; (); 27 ^" ; (); 29A ^" -B ^" ; (); 31 A ^" ; 31 B ^" ; ED ^" -.

-Polo terminal cycle: 31 A-; -Prolling initial of cycle: 31 B-; -stance pointing to fork: 23 ^' -. n; ...; + n; ... / ...; + n; (); + n; "..."; = 32 instances: 23 in the common channel, and 9 in the autonomous channel corresponding to those in succession listed from 25 to 31 B. -n; ...; + n; ... / ...; + n; "..."; = 23 practical sections. Figures 210 and 211, 216 and 217.

 -Register of modular instances of the modular binomial conformed by the plastic module 2, -pattern-, of 10 crosses (), SC configuration, partially fused with its functional specular simile; and from their primitive and matrix ancestors, verify with Figures 206 and 208.

-Module plastic 2 of 10 crosses (), pattern, member 1 of its modular binomial:

-; 1 ^' ; 2712 ^' ; 3 ^" ; 4/13; 5/25; 6; 7/18; 8; 9/20; 10/32; 11A; 11B; 11C; 11D; 11E; (); (); 14 ; 15; 16/23; 17/28; (); 19; (); 21/30; 22A; 22B; 22C; (); 24/26; (); (); 27; (); 29; ); 31A; 31B; (); 33A; 33B; ED-.

-Polo terminal cycle: 33A ^' -; -Printer initial of cycle: 33B ^" -; -stance that signals branch: 14-. N; ...; + n; ... / ...; + n; (); + n;" ... "; = 41 instances: 31 in the common channel, and 10 in the autonomous channel corresponding to those in succession enumerated from 26 to 33B. - n; ...; + n; ... / ...; + n; " ... "; = 31 practical sections.

 -System module -primitive-: 33 instances: 25 in the common channel and 8 in the autonomous channel, seated in 23 sections, Figure 207.

-Simil functional specular of asymmetric modular composition with respect to the plastic module

2 of 10 crosses (), pattern; integrant 2 of modular binomial:

-; one ; 2/12; 3A; 3B; 3C; 3D; 3E; 3F; 3G; 3H; 4713 ^" ; 5725 ^' ; 6 ^" ; 7718 ^" ; 8 ^' ; 9720 ^' ; 10732 ^" ; 11A ^" ; 11B ^" ; 11C ^" ; 11D ^" ; 11E ^" ; (); (.); 14 ^" ; 15 ^" ; 16723 ^" ; 17728 ^" ; (); 19 ^" ; (); 21730 ^" ; 22A ^" ; 22B ^" ; 22C ^" ; (); 24726 ^" ; (); (); 27 ^" ; (); 29 ^" ; (); 31A ^" ; 31 B ^' ; (); 33A ^" ; 33B ^" ; ED.-. -Polo terminal cycle: 33A -; -Printer initial cycle: 33B-; -stance pointing to fork: 14 ^' -. n; ...; + n; ... / ...; + n; (); + n; "..."; = 48 instances: 38 in the common channel, and 10 in the autonomous channel corresponding to those in succession listed from 26 ^" to 33B ^" . - n; ...; + n; ... / ...; + n; "..."; = 38 practical sections.

-Module type of system -primitive-: 33 instances: 25 in the common channel and 8 in the autonomous channel, seated in 22 sections.

 -Module plastic 2 of 10 crosses (), matrix, member 1 of its modular binomial:

-; 1 ^" ; 2712 ^" ; 3 ^' ; 4/13; 5/25; 6; 7/18; 8; 9/20; 10/32; 11A-BCDE; (); (); 14; fifteen ; 16/23; 17/28; (); 19; (); 21/30; 22A-BC; (); 24/26; (); (); 27; (); 29; (); 31A-B; (); 33A; 33B; ED.-. -Polo terminal of cycle: 33A ^" -; -Polo initial of cycle: 33B ^" -; - instance that signals bifurcation: 14 -. n; ...; + n; ... / ...; + n; (); + n; "..."; = 34 instances: 25 in the common channel, and 9 in the autonomous channel corresponding to those in succession listed from 26 to 33B. -n; ...; + n; ... / ...; + n; "..."; = 24 practical sections.

 -Simil functional specular of asymmetric modular composition with respect to the plastic module 2 of 10 crosses (), pattern; integrant 2 of modular binomial:

-; one ; 2/12; 3A-BCDEFGH; 4713 ^" ; 5725 ^" ; 6 ^" ; 7718 ^" ; 8 ^" ; 9720 ^" ; 10732 ^" ; 11A ^" -B ^" -C ^" -D ^" -E ^" ; (); (); 14 ^" ; 15 ^" ; 16723 ^" ; 17728 ^" ; (); 19 ^" ; (); 21730 ^" ; 22A ^" -B ^" -C ^" ; (); 24726 ^" ; (); (); 27 ^" ; (); 29 ^" ; (); 31A ^" -B ^" ; (); 33A ^" ; 33B ^" ; ED.-.

-Polo terminal cycle: 33A -; -Printer initial cycle: 33B-; -stance pointing to fork: 14 ^' -. n; ...; + n; ... / ...; + n; (); + n; "..."; = 34 instances: 25 in the common channel and 9 in the autonomous channel corresponding to those in succession listed from 26 ^' to 33B ^" ). -N; ...; + n; ... / ...; + n; "..."; = 24 practical sections, Figures 209, 218 and 219.

-That type of binomials gives rise in the first place to the fact that the CS resulting from the functional association of 6 modular binomials sharing a central point, plasma elementally types of dodeca-moduiar systems of SC configuration of 6-star star: Figure 209, type of multi-modular system revealed since it is inferred from strains of congeners, of SC-shaped configuration of which it is part, types of systems that are captured by, first, the adaptation of the internal angle of the module's internal modular binomial (angle with vertex in the central point of the starry configuration), according to the number of binomials that make up the type of system: 360 ° / n ° of modular binomials, and second thanks to the content distribution of the modules of the representative binomial to binomials of modules of complementary convex and concave inscription forms no longer triangular, but with the modular content shared in alignment, tracing a convenient curve trajectory (representative figures 210 and 211), which closes circularly in the context of the system. Secondly, to which functionally connected 3 modular units of this nature in a CS as shown in Figure 212, binomials by whose folded in between the alignment of generic identification instances: -3- intended for transit between modules , and the realization of the proper maneuver of union of the loose sides and total bending of the shared sides as axes, the generic initial CS results in the expression of types of irregular hexahedral SC configuration systems, conformed by 3 binomials composed of a plastic module 1 or 2 face of regular hexahedron partially fused with its (as for the functional aspect) corresponding specular simulation (see Figure 213); same binomials that associated in number of 4 (see Figure 214), likewise give rise to types of regular octahedral SC configuration systems (see Figure 215). These 5 types of configuration system SC hexa and octa-modular are respectively representative of types of SC configuration systems irregular eneahedron of 6 triangular and 3 rectangular sides, and irregular dodecahedron of 8 triangular and 4 rectangular sides, which are achieved by opting in the building exercise by folding the binomials functionally connected now bordering side and side of the alignment of instances of generic encrypted identification -3-, which

10 are framed on rectangular faces after the total doubled end of the sides shared as axes and due to union of the loose sides of the initial generic flat SC configuration, resulting, practical system types, not their referents as small-scale material platforms. But the types of configuration systems SC irregular hexahedron and regular octahedron, likewise can transfer their contents to the spheres (representative of ellipsoids) that

15 circumscribe producing types of spherical congeneric systems from the irregular hexahedron and the regular octahedron (see Figures 216, 217, 218 and 219), from which the existence of other conspecifics of their lineages are inferred, which types of spherical systems are bi -modular and tetra-modular impossible in the form of a polyhedron, which are captured by transferring the contents of the binomial sphere cap of its generic congener: to a sphere, and to each face

20 of a sphere respectively. -The alternative to the construction described above is the mutation to types of plastic modules 1 and 2 of 9 Vi and 10 Vi crosses () respectively, constituted with binomials of plastic modules 1 or 2 of CS equilateral triangle, and its corresponding specular counterpoint without merging, only sharing a new section in which there is a crossing of trajectories involving transit instances between binonios (Figures 220,

25 221 and 222, 223, 224 and 225). The maneuver achieves that the flow goes from the module from one hemisphere to the next in the opposite hemisphere and so on, so that in order to complete a cycle, 2 revolutions must be carried out, and such ordering is only functional for types of modular conformation system even number that its division by two results in odd numbers, such in principle as, hexa-modular and deca-modular.

 30 -Register of modular instances of the modular binomial conformed by the plastic module 1, -pattern-, of 9 Ví crossovers (), SC configuration, associated with its functional specular simile; and its predecessors: primitive and matrix, SC configuration, is contrasted with Figures 220 and 222.

-Module plastic 1 of 9 ¹ /> crosses (), pattern, member 1 of modular binomial:

35 -; one ; 2/13; 3/3 ^" ; 4A; 4B; 4C; 4D; 4E; 4F; 5/14; 6/25; 7; 8/18; 9; 10/20; 11/31; 12A; 12B;

 12C; 12D; 12E; (); (); 15A; 15B; 16/23; 17/27; (); 19; (); 21/29; 22A; 22B; 22C; (); 24; (); 26; (); 28; (); 30A; 30B; (); 32A; 32B; ED -.

-Simil functional specular of plastic module 1 of 9 1/2 crosses (), -pattern-, member 2 of modular binomial: -; 1 ^" ; 2713 ^" ; 373; 4A ^" ; 4B ^" ; 4C ^" ; 4D ^" ; 4E ^" ; 4F; 5714 ^" ; 6725 ^" ; 7 ^" ; 8718 ^" ; 9 ^' ; 10720 ^" ; 11731 ^' ; 12Α ^' ; 12Β ^' ; 12C; 12D ^' ; 12Ε ^' ; (); (); 15Α ^' ; 15Β ^' ; 16723 ^" ; 17727 ^" ; (); 19 ^" ; (); 21729 ^" ; 22Α ^" ; 22Β ^" ; 22C ^" ; (); 24 ^" ; (); 26 ^" ; (); 28 ^" ; (); 30Α ^" ; 30Β ^" ; (); 32Α ^" ; 32Β ^" ; ED ^" .-.

 Specular module and simile of system -pattern-:

5 Cycle terminal pole: 32A (32A ^" ); Initial cycle pole: 32B (32B ^" ); instance that signals branch: 24 (24 ^" ).

 n; ...; + n; ... / ...; + n; (); + n; "..."; = 46 instances: 37 in the common channel, and 9 in the autonomous channel corresponding to the succession instances listed from 26 to 32B. - n; ...; + n; ... / ...; + n; "..."; = 36 practical sections.

10 -System module -primitive-: 32 instances: 25 in the common channel and 7 in the autonomous channel, seated in 22 sections, Figure 221.

 -Module plastic 1 of 9 Vi crosses (), matrix, member 1 of modular binomial:

-; one ; 2/13; 3/3 ^" ; 4A-BCDEF; 5/14; 6/25; 7; 8/18; 9; 10/20; 11/31; 12A-BCDE; (); (); 15A-B; 16/23 ; 17/27; (); 19; (); 21/29; 22A-BC; (); 24; (); 26; (); 28; (); 30A-B; (); 15 32A; 32B ; ED -.

 -Simil functional specular of plastic module 1 of 9 1/2 crosses (), matrix, integrant 2 of modular binomial:

-; 1 ^" ; 2713 ^" ; 373; 4A ^" -B ^" -C ^" -D ^" -E ^" -F ^" ; 5714 ^" ; 6725 ^" ; 7 ^" ; 8718 ^" ; 9 ^" ; 10720 ^" ; 11731 ^" ; 12A -B ^" C ^" - D ^' -E ^" ; (); (); 15A ^' -B ^" ; 16723 ^" ; 17727 ^" ; (); 19 ^" ; (); 21729 ^" ; 22A ^" -B ^" -C ^" ; (); 24 ^" ; (); 26 ^" ; (); 28 ^" ; 20 (); 30A ^" -B ^" ; (); 32A ^" ; 32B ^" ; ED ^" .-.

Cycle terminal pole: 32A (32A ^' ); Initial cycle pole: 32B (32B ^" ); instance signaling fork: 24 (24 ^" ).

n; ...; + n; ... / ...; + n; (); + n; "..."; = 33 instances: 25 in the common channel and 8 in the autonomous channel corresponding to those in succession listed from 26 (26 ^" ) to 32B (32B ^" ).

 25; n; ...; + n; ... / ...; + n; "..."; = 23 practical sections. Figures 226 and 227, 232 and 233.

 -Register of modular instances of the modular binomial conformed by the plastic module 2, -pattern-, of 10 1/2 crosses (), SC configuration, associated with its functional specular simile; and of its primitive and matrix ancestors, it is contrasted with Figures 223 and 225. - Plastic module 2 of 10 1/2 crosses (), pattern, member 1 of modular binomial:

30 -; one ; 2/13; 3/3 ^" ; 4A; 4B; 4C; 4D; 4E; 4F; 5/14; 6/26; 7; 8/19; 9; 10/21; 11/33; 1212A; 12B; 12C; 12D; 12E ;); (); 15; 16; 17/24; 18/29; (); 20; (); 22/31; 23A; 23B; 23C; (); 25/27; (); 28; ); 30; (); 32A; 32B; (); 34A; 34B; ED.

 Simil specular of plastic module 2 of 10 1/2 crossings (), -pattern-, integrant 2 of modular binomial:

35 -; 1 ^" ; 2713 ^" ; 373; 4A ^" ; 4B ^" ; 4C; 4D ^" ; 4E ^" ; 4F ^" ; 5714 ^" ; 6726 ^" ; 7 ^" ; 8719 ^" ; 9 ^" ; 10721 ^" ; 11733 ^" ; 12A ^" ;

12B ^" ; 12C; 12D ^" ; 12E ^" ; (); (); 15 ^" ; 16 ^' ; 17724 ^" ; 18729 ^" ; (); 20 ^" ; (); 22731 ^" ; 23A ^" ; 23B ^" ; 23C ^" ; (); 25727 ^" ; (); 28 ^" ; (); 30 ^" ; (); 32A ^" ; 32B ^" ; (); 34A ^" ; 34B ^" ; ED ^' -.

Cycle terminal pole: 34A (34A ^" ); Initial cycle pole: 34B (34Β ^' ), bifurcation indicating instance: 15 (15 ^" ). n; ...; + n; ... / ...; + n; (); + n; "..."; = 46 instances: 36 in the common channel, and 10 in the autonomous channel corresponding to those listed in succession from 27 to 34B.

 ; n; ...; + n; ... / ...; + n; "..."; = 35 practical sections.

 -System module -primitive-: 34 instances: 26 in the common channel and 8 in the autonomous channel, 5 settled in 23 sections, Figure 224.

 -Module plastic 2 of 10 1/2 crosses (), -matrix-, member 1 of modular binomial:

-; one ; 2/13; 3/3 ^' ; 4A-BCDEF; 5/14; 6/26; 7; 8/19; 9; 10/21; 11/33; 12A-BCDE; (); (); fifteen ; 16; 17/24; 18/29; (); twenty ; (); 22/31; 23A-BC; (); 25/27; (); 28; (); 30; (); 32A-B; (); 34A; 34B; ED.

 10 Specular simulate of plastic module 2 of 10 1/2 crosses (), -matrix-, component 2 of modular binomial:

-; 1 ^" ; 2713 ^' ; 373; 4A ^' -B ^' -C ^" -D ^' -E ^' -F; 5714 ^' ; 6726 ^' ; 7 ^' ; 8719 ^' ; 9 ^' ; 10721 ^' ; 11733 ^' ; 12A ^" -B ^' -C- D ^' -E ^' ; (); (); 15 ^' ; 16 ^' ; 17724 ^' ; 18729 ^" ; (); 20 ^' ; (); 22731 ^" ; 23A ^' -23B ^' -C; (); 25727 ^' ; (); 28 ^' ; (); 30 ^" ; (); 32A ^' -B ^' ; (); 34A ^' ; 34B ^' ; ED ^' -.

15 35 instances: 26 in the common channel and 9 in the autonomous, seated in 24 sections, Figures 228 and 229, 234 and 235.

 -To produce types of SC (flat) exa and deca-modular star configuration systems formed by replicas of this type of modular binomial, the internal angle of the modules of the binomials to be placed filling the interior of the star with vertex at the point center of

20 it depends on the number of binomials that make it up: 120 ° in types of hexa-modular systems or made up of 3 binomials, and 72 ° in deca-modular or made up of 5 modular binomials. Likewise, the interior modules then necessarily conform the distribution of their contents in a convex manner, inscribed between the sides that leave the vertex and a curve cut by the shared section that registers crossing, curve that closes circularly

25 in the context of the system, such a state on which the concave shape assumed in the distribution of its contents by the external modules of the binomials, modules that act as points of the star (representative figures 226, 227, 228 and 229). -Functionally connected 3 or 5 modular binomials formed by the plastic module 1 of 9 Vz crossings or the plastic module 2 of 10 Vz crossings, of CS equilateral triangle, together with

30 its corresponding specular simile in a planar CS (Representative Figure 230); by folding by the delineation of the component modules of the binomials as axis (that dissociates them and that only affects and without transcendence to the section shared by them that registers crossing), and the realization of the proper maneuver of union of the loose sides and total bending of shared sides as axes, the initial CS derives in types of six-sided SC configuration systems

35 irregular and irregular decayed, conformed by 3 and 5 binomials respectively, composed in turn by a plastic module 1 of 9 V. crosses () or plastic module 2 of 10 ¹ Λ crosses () face (equilateral triangle) of irregular hexahedron or fine irregular decanter, together with its corresponding specular simile (see Figure 231).

-These types of polyhedral SC configuration systems can also project their contained to the spheres (representative of the ellipsoids) circumscribing them, producing types of hexa and deca-modular systems of spherical SC configuration, formed by modular binomials with a sphere cap composed of the plastic module 1 of 9 VΣ crosses () or the module plastic 2 of 10 ¹ Λ crosses (), of curved surface configurations, associated with their respective specular similes (Representative Figures 232, 233, 234 and 235). Of these it is inferred, because in the spherical shape its plasma becomes possible, the incorporation of the respective bi-modular congeners, represented by the representatives, by means of the transfer of the contents of a modular binomial sphere cap of such characteristics, generic, to a generic sphere.

-The representative figures of the types of cylindrical, conical, pyramidal, hemispherical and spherical exposed systems, which are seen defined in the exteriority or convexity of the body or object, are representative of appreciations of said systems defined in the interiority or concavity of the body or object.

 Material realization of bi and three-dimensional systems in the service of board games

Two-dimensional systems: by polychrome printing on an apt surface, of the surface configuration with all its signs and icons of each system. Three-dimensional systems: by injection of transparent material: vitreous, plastic, acrylic (methacrylate) or recinoso, in liquid state, in molds that reproduce the structural body or parts of it, of each system: in which are compacted base, walls, supports , and against footprints, with the horizontal support of the sections and passages that conform the surface configuration of the levels, body on which already solidified adhere properly colored transparent adhesives. They refer to the sections, icons and signs that together express fully each system.

Realization of computer simulations of three-dimensional systems serving games and video-table games and virtual competition tracks

Once the data of all the elements of each design have been entered into a 3D simulation computer program, and the process of abstraction has been carried out that converts the logic and regulations of the relevant game modality into computational logic, the programming language that adapt in the implementation process to function in coordination with random lottery execution programs and execution of selected movement options. The result will be programming of individual modalities and multimodal game or competition programs applicable for use in the console, controls or keyboard and screen, mobile phones, etc.

Description of the Figures

Abbreviations used: CS: surface configuration; D1: dynamic with character of continuous rotation; D2: dynamics of cyclic registration; D3: dynamics of monocyclic character; D4: dynamics of mono and polycyclic nature according to regulations; D5: dynamics of polycyclic character; (genus) BM: (genre) bi-modular; (genus) P-: (genus) poly-modular; (configuration) SC: (configuration) compact surface; (configuration) SD: (configuration) surface distended; OCO: original conditional ordering (of the family); OCR: conditional ordering reference; OFR: functional ordering reference; OFCR: functional and conditional ordering reference; ("crossings) ()": (crosses) of trajectories of regular channels per module.

Figure 1.1 and 1.2: Icon, symbol of the "arrow" that indicates direction, composed of tip and shaft, expresses a moment or channel component instance of a circulatory system.

Figure 1.3: Icon, symbol of the "arrow" that points direction, composed of tip, shaft and feathered; expresses a disproportionately long section instance, component of a circulatory system channel.

 Figure 2.1, 2.2, 2.3 and 2.4: intersecting arrows, which mean instances in intersection or superimposed (in section or sector), by crossing the trajectories of the circulatory channels to which they belong.

 Figures 3.1 and 3.2: Segmented arrow that gives to mean instance where a "condition" according to regulations is established, as it is for example, that of serving as "insurance" of incorporating an imported referential conditional ordering (OCR).

Figures 4.1 and 4.2: Segmented arrow (which dictates therefore condition according to regulations) composed of 2 points and a shaft, which gives to mean instance of "bifurcation" of the circulation.

Figures 5.1 and 5.2: Arrow with a tip and 2 sticks that gives to mean instance of "confluence" of the circulation.

 Figure 5.3: Arrow with a tip and 2 sticks, one of which is drawn in a dashed line, which means to indicate an instance of confluence depending on whether regulations allow it.

 Figure 6: Diagram panel of representative readings, typical of module type of tetra-modular system.

 Figure 7: Icon that indicates "terminal cycle pole" of circulatory systems whose dynamics are of a mono-cyclic nature or of cyclic registration and transfer, in systems of the bi- modular genre that can assume a regular polycyclic dynamic.

 Figure 8: Icon that gives to mean instance "initial pole of cycle" or house of color or of circuit, of circulatory systems whose dynamics is of mono-cyclic character.

 Figure 9: Icon that gives to mean "initial cycle pole" of circulatory systems whose dynamics are polycyclic in character.

Figure 10: Icons that signify "initial cycle pole" of circulatory systems whose dynamics are polycyclic or mono-cyclic.

 Figure 11: Icon that signifies "instance of cyclic registration" of circulatory systems of both genders, and at the same time -polo transfer- of circulatory systems of the bi-modular genre whose dynamics is irregular poly-cyclical character.

Figure 12: Icon that signifies "cyclic record instance" that serves as the initial pole of cycle and terminal pole of cycle "of circulatory systems of both genders whose dynamics is polycyclic in character.

Figure 13: Icon that gives to mean instance of the common channel that contains the section that serves as the initial pole of the cycle of systems of the bi-modular genre whose dynamics are of a polycyclic nature irregular.

 Figure 14: CS of primitive system type "of gender" B-M, constituted simply with conductive signs, abstracted from its sectioned simile (Figure 15).

Figure 15: CS of primitive system type "gender" B-M of SC configuration. Figure 16: CS of primitive system type "of gender" B-M of SC configuration, in alternative conductive orientation, or mirror specimen of Figure 15.

Figure 17: CS of primitive system type "of gender" B-M of configuration SC.

Figure 18: SC configuration of representative matrix system type module "of gender" B-M, (meets irregular cycles) D2.

Figure 19: CS of representative matrix system "of gender" B-M, (meets irregular cycles) D2, of SC configuration.

 Figure 20: CS of the "genre" pattern system type module B-M of SC configuration.

Figure 21: CS of type "genus" pattern system B-M of SC configuration.

Figure 22: Encrypted identification of instances of the "gender" standard system module BM, as well as CS of the "gender" standard system type module BM, whose flow is given by the consecutive numbering of consecutive code system numbers of the numbering, representative of similar systems of its lineage and of the lineages of systems conformed by types of "versatile" and "plastic" module, SC configuration.

 Figure 23: Encrypted identification of instances of the "genus" standard system type BM, together with CS of the "genre" standard system type module BM, whose flow is given by the consecutiveness of consecutive code system numerals of the numbering, SC configuration.

 Figure 24: alternative modular approach of representative system "of gender" B-M, of SC configuration.

Figure 25: (complementary to Figure 24) alternative modular approach of representative system "of gender" B-M, of SC configuration, whose instances in succession of their regular conduits are expressed adopting the system of consecutive codes of the numbering. Figure 26: CS of module type of primitive modular tetra-modular system "of gender" P-M, of configuration SC, D1.

Figure 27: CS of representative tetra-modular primitive system type "of gender" P-M, configuration SC, D1.

 Figure 28: CS of primitive system module tetra-modular, not sectioned, representative "of gender" P-M, configuration SC, D2.

 Figure 29: CS of type of primitive system tetra-modular, not sectioned, representative "of gender" P-M, configuration SC, D2.

 Figure 30: CS module type module representative tetra-modular matrix system "of gender" P-M, of configuration SC, D4.

Figure 31: CS of the tetra-modular matrix system type, representative of "gender" PM, configuration SC, D4. Figure 32: CS of representative system type "Universal 1", or 1 ^to third generation series, "of gender" PM, of configuration SC, D3.

Figure 33: CS type "Universal 1" representative, or 1 ^to series of third generation, "gender" PM, SC configuration, D3 system.

Figure 34: CS module representative type 2, or 2 ^to series of third generation, "gender" PM, SC configuration, D5 universal system.

Figure 35: CS of representative universal system type 2, or 2 ^to third generation series, "of gender" PM, of configuration SC, D5.

 Figure 36: CS of module type -pattern- tetra-modular, fourth generation, representative "of gender" P-M, of configuration SC, D5.

 Figure 37: System-type CS-tetra-modular pattern, fourth generation, representative "gender" P-M, configuration SC, D5.

 Figure 38: Encrypted identification of instances of tetra-modular pattern system module, representative of "gender" PM, and simultaneously: CS of model module of "genus" model system PM, whose flow is given by the consecutiveness of numerals of the system of consecutive codes of the numbering, SC configuration.

 Figure 39: Encrypted identification of instances of the "gender" standard system type PM, as well as CS of the "gender" standard system type module PM, whose flow is given by the consecutive numbering of consecutive code system numbers of the numbering, SC configuration.

 Figure 40: alternative modular (triangular) approach of representative system, SC configuration, "gender" P-M.

 Figure 41: (complementary to Figure 40) alternative modular (triangular) approach of representative system, of configuration SC, "of gender" PM, whose instances in succession of their regular channels are expressed adopting fundamentally the system of consecutive codes of the numbering .

 Figure 42: (complementary to Figure 40) alternative modular approach (triangular) octa-modular system, SC configuration, "gender" P-M.

 Figure 43: (complementary to Figure 40) alternative modular (triangular) approach of octa-modular system, of SC configuration, "of gender" PM, whose instances in succession of its regular channels are expressed adopting fundamentally the system of consecutive codes of the numbering

 Figure 44: CS of module type -pattern- tri-modular, fourth generation, representative "of gender" P-M, of configuration SC, D5.

Figure 45: CS-type system -pattern- tri-modular, fourth generation, representative "gender" P-M, configuration SC, D5.

Figure 46: CS of module type of tri-modular system -atypical 1-, of fifth generation, representative of "gender" PM, according to modular composition denominated atypical 1, tri-modular, of configuration SC, D3. Figure 47: CS of module type of tri-modular system -atypical 1-, of fifth generation, representative of "gender" PM, according to modular composition called atypical 1, tri-modular, of configuration SC, D3, whose instances vary of the typical constitution, they are numbered and literal.

Figure 48: CS of type of tri-modular system - typical 1-, of fifth generation, representative "of gender" P-M, according to modular composition called atypical 1, tri-modular, of configuration SC, D3.

 Figure 49: CS of module type of tri-modular system -ypical 2-, of sixth generation, representative "of gender" P-M, according to modular composition called atypical 2, of configuration SC, D3.

 Figure 50: CS of module type of tri-modular system -atypical 2-, of sixth generation, representative of "gender" PM, according to modular composition denominated atypical 2, of configuration SC, D3, whose instances that vary from the typical constitution , they are encrypted with numerical and literal. Figure 51: CS of type of tri-modular system -ypical 2-, of sixth generation, representative "of gender" P-M, according to modular composition denominated atypical 2, of configuration SC, D3.

Figure 52: CS of system type module -patron-penta-modular, of fourth generation, representative "of gender" P-M, of configuration SC, D5.

 Figure 53: CS of system type -patron-penta-modular, of fourth generation, representative "of gender" P-M, configuration SC, D5.

Figure 54: System type module -pattern- hexa-modular module CS, of the fourth generation, representative of "gender" P-M, of configuration SC, D5.

 Figure 55: CS of system type -patron- hexa-modular, of fourth generation, representative "of gender" P-M, configuration SC, D5.

 Figure 56: System type module -pattern- hepta-modular CS, of fourth generation, representative "of gender" P-M, of configuration SC, D5.

 Figure 57: System-type CS -pattern hepta-modular, fourth generation, representative "of gender" P-M, configuration SC, D5.

 Figure 58: CS of module system -pattern- octa-modular, fourth generation, representative "of gender" P-M, of configuration SC, D5.

Figure 59: CS of system type -pattern- octa-modular, of fourth generation, representative of "gender" P-M, configuration SC, D5.

 Figure 60: CS of module of type of primitive system of cyclic record "of gender" BM, configuration SD, D3 with respect to delineation in continuous line, and D5 that fulfills irregular cycles with respect to the set delineated with continuous line and discontinuous

Figure 61: CS of type of primitive system of cyclic record "of gender" B-M, configuration SD, D3 with respect to delineation in solid line, and D2 in io relative to the set delineated with continuous and discontinuous line.

Figure 62: CS of module of type of primitive system of cyclical record "of gender" BM, configuration SD, D5 with respect to delineation in continuous line, and D5 that fulfills cycles regular or irregular according to regulations regarding the set drawn with continuous and discontinuous line.

 Figure 63: CS of type of primitive system of cyclic record "of gender" BM, configuration SD, D3 with respect to delineation in a continuous line, and D5 that complies with regular or irregular cycles according to regulations in relation to the outlined set with continuous and discontinuous line. Figure 64: Encrypted identification of instances of primitive systems of cyclic "gender" registration B-M, SD configuration, corresponding to Figures 60, 61, 62 and 63.

Figure 65: CS of module of type of primitive system of cyclical register tri-modular "of gender" P-M, configuration SD, (D2).

Figure 66: CS of the primitive system type of cyclic recording, tri-modular "of gender" P-M, SD configuration.

 Figure 67: CS of module type of primitive system of tetra-modular cyclic register "of gender" P-M, configuration SD, (D2).

 Figure 68: CS of primitive system type D2, tetra-modular "of gender" P-M, SD configuration. Figure 69: Ciphered identification of instances of primitive systems of cyclic "gender" P-M register, SD configuration, corresponding to Figures 65, 66, 67 and 68.

Figure 70.1: CS of level 1 (of 2) of module of type of system "of gender" B-M of second generation (25 instances), of configuration SC, of three-dimensional bearing economic in the vertical dimension, D3. It is complemented with Figure 70.2 that corresponds to level 2.

Figure 70.2: CS of level 2 (of 2) of module of type of system "of gender" B-M of second generation (25 instances), of configuration SC, of three-dimensional bearing economic in the vertical dimension, D3. It is complemented with Figure 70.1 that corresponds to level 2.

Figure 71.1: CS of level 1 (of 2) of module of type of system "of sort" B-M, first series of third generation denominated -Universal-, of configuration SC, of three-dimensional economic bearing in the vertical dimension, D3. It is complemented with Figure 71.2 that corresponds to level 2; the top view of the module (of invoice in transparent material) is shown in Figure 18; the zenith view of the type of system to which such a module corresponds is shown in Figure 19. Figure 71.2: CS level 2 (of 2) of type of system of "gender" system BM, first series of third generation called -Universal -, of SC configuration, of economic tridimensional bearing in the vertical dimension, D3. It is complemented with Figure 71.1 that corresponds to level 1; the top view of the module (of invoice in transparent material) is shown in Figure 18; the top-down view of the type of system to which such a module corresponds is represented in Figure 19. Figure 72.1: CS of level 1 (of 2) of type of system module "of gender" BM, of second series of third generation, of SC configuration, of economic three-dimensional size in the vertical dimension, D3. It is complemented with Figure 72.2 that corresponds to level 2.

 Figure 72.2: CS of level 2 (of 2) of module of type of system "of sort" B-M, of second series of third generation, of configuration SC, of three-dimensional bearing economic in the vertical dimension, D3. It is complemented with Figure 72.1 that corresponds to level 1.

Figure 73.1: CS of level 1 (of 2) of module type of "gender" system BM, of fourth generation called -Patron-, of SC configuration, of economic three-dimensional bearing in the vertical dimension, D3. It is complemented with Figure 73.2 that corresponds to level 2; the top view of the module (of invoice in transparent material) is represented in Figures 20 and 22; the zenith view of the type of system to which such a module corresponds is represented in Figures 21 and 23.

 Figure 73.2: CS of level 2 (of 2) of module of type of system "of gender" B-M, fourth generation named -Patron-, of configuration SC, of three-dimensional economic bearing in the vertical dimension, D3. It is complemented with Figure 73.1 that corresponds to level 1; the top view of the module (of invoice in transparent material) is represented in Figures 20 and 22; the zenith view of the type of system to which such a module corresponds is represented in Figures 21 and 23.

 Figure 74.1: CS of level 1 (of 2) of the module of system type -Patron- tetra-modular "of gender" P-, and D3, configurations SC and SD, of regular cause of economic three-dimensional bearing in the vertical dimension, representative cause. It is complemented with Figure 74.2 that corresponds to level 2; the top view of the module (of invoice in transparent material) is represented in Figures 36 and 38; the zenith view of the type of system to which such a module corresponds is represented in Figures 37 and 39.

 Figure 74.2: CS of level 2 (of 2) of the module of system type -Patron- tetra-modular "of gender" PM, and D3, configurations SC and SD, of regular cause of economic three-dimensional bearing in the vertical dimension, cause representative. It is complemented with Figure 74.1 that corresponds to level 1; the top view of the module (of invoice in transparent material) is represented in Figures 36 and 38; the overhead view of the type of system corresponding to such a module is represented in Figures 37 and 39.

 Figure 75.1: CS of level 1 of 6, in progressive order from 1 (bottom) to 6 (top) of system module -pattern- "of gender" B-M, of broad three-dimensional bearing in the vertical dimension, D3, SC configuration. It is complemented with Figures from 75.2 to 75.6; the top view of the module and system (of invoice in transparent material) is covered as CS in Figures 20, 21, 22 and 23; the elevation views "of side faces (4 faces) of the module are presented in Figures 76.1 to 76.4, and the isometric representation of the system in Figure 77.

 Figure 75.2: CS of level 2 of 6, in progressive order from 1 (below) to 6 (above) of system module -pattern- "of gender" B-M, of broad three-dimensional bearing in the vertical dimension, D3, SC configuration. It is complemented with Figures 75.1, and from 75.3 to 75.6. (Other characteristics are taught in the explanation of Figure 75.1).

 Figure 75.3: CS of level 3 of 6, in progressive order from 1 (bottom) to 6 (top) of system module -pattern- "of gender" B-M, of broad three-dimensional bearing in the vertical dimension, D3, SC configuration. It is complemented with Figures 75.1, 75.2 and 75.4 to 75.6. (Other characteristics are taught in the explanation of Figure 75.1).

Figure 75.4: CS of level 4 of 6, in progressive order from 1 (bottom) to 6 (top) of system module -pattern- "of gender" BM, of broad three-dimensional bearing in the vertical dimension, D3, SC configuration. It is complemented with Figures from 75.1 to 75.3, and 75.5 and 75.6. (Other characteristics are taught in the explanation of Figure 75.1).

 Figure 75.5: CS of level 5 of 6, in progressive order from 1 (below) to 6 (above) of system module -pattern- "of gender" B-M, of broad three-dimensional bearing in the vertical dimension, D3, configuration SC. It is complemented with Figures 75.1 through 75.4 and 75.6 (Other features are taught in the explanation of Figure 75.1).

Figure 75.6: CS of level 6 of 6, in progressive order from 1 (bottom) to 6 (top) of system module -pattern- "of gender" B-M, of broad three-dimensional bearing in the vertical dimension, D3, SC configuration. It is complemented with Figures from 75.1 to 75.5 (Other features are taught in the explanation of Figure 75.1).

Figure 76.1: Front view of the right interior side of "views of elevations" of lateral faces (4 faces) of system type module -pattern- "of gender" BM, of a three-dimensional arrangement in the vertical dimension of 6 levels , of SC configuration, with height measurement from level to level: 1, 5X (where X corresponds to the side measurement of a square section of the system); expressed for an elevation of its sections and dividing walls and of support in transparent material. It is complemented with Figures 76.2: left inside face, 76.3: right outside face, and 76.4: left outside face. The top view of the module and the corresponding system (of invoice in transparent material) are shown in Figures 20 and 21, and 22 and 23 respectively; the distribution of the modular instances in the 6 levels of their size, and isometric representation are defined in Figures from 75.1 to 75.6; and 77.

Figure 76.2: Front view of the left inside face of "side views" of side faces (4 faces) of the system type module -pattern- BM, of a three-dimensional order in the vertical dimension of 6 levels, SC configuration . It is complemented with Figures 76.1: inner right face, 76.3: outer right face, and 76.4: left outer face. (Other characteristics are taught in the explanation of Figure 76.1).

Figure 76.3: Front view of the right outer face of "side elevations" of lateral faces (4 faces) of the system type module -pattern-BM, of a wide three-dimensional order in the vertical dimension of 6 levels, of SC configuration . It is complemented with Figures 76.1: inner right face, 76.2: left inner face, and 76.4: left outer face. (Other characteristics are taught in the explanation of Figure 76.1).

Figure 76.4: Front view of left outer face of "side views" of side faces (4 faces) of system type module -pattern-BM, of three-dimensional order in the vertical dimension of 6 levels, of SC configuration . It is complemented with Figures 76.1: interior right side, 76.2: interior left side, and 76.4: interior left side. (Other characteristics are taught in the explanation of Figure 76.1).

Figure 77: Isometric representation in opaque material of type of standard system - "of gender" BM, of three-dimensional order in the vertical dimension of 6 levels, of SC configuration, with approximate measurement of height from level to level: 1X ( where "X" corresponds to the side measurement of a square section of the system). The overhead view of the module and the corresponding system (of invoice in transparent material) are shown in Figures 20 and 21, and 22 and 23 respectively; the distribution of the modular instances in the 6 levels of their size, are defined in Figures from 75.1 to 75.6; the elevation views "of lateral faces (4 faces) of the module are presented in Figures 76.1 to 76.4.

 Figure 78.1: CS of level 1 of 6, in progressive order from 1 (below) to 6 (above) of module of 5 system -pattern- "of gender" PM, of broad three-dimensional bearing in the vertical dimension of 6 representative levels, D3, SC configuration. It is complemented with Figures from 78.2 to 78.6; the top view of the module and system (of invoice in transparent material) is covered as CS in Figures 36, 37, 38 and 39; the views of elevations: Figures from 79.1 to 79.4; and the isometric presentation of the system in Figure 80.

10 Figure 78.2: CS of level 2 of 6, in progressive order from 1 (bottom) to 6 (top) of system module -pattern- "of gender" PM, of broad three-dimensional bearing in the vertical dimension of 6 representative levels, D3, SC configuration. It is complemented with Figures 78.1 and 78.3 to 78.6. (Other characteristics are taught in the explanation of Figure 78.1).

 Figure 078.3: CS of level 3 of 6, in progressive order from 1 (below) to 6 (above) of module of 15 system -pattern- "of gender" PM, of broad three-dimensional bearing in the vertical dimension of 6 representative levels, D3, SC configuration. It is complemented with Figures 78.1 and 78.2, and

78.4 to 78.6. (Other characteristics are taught in the explanation of Figure 78.1).

 Figure 78.4: CS of level 4 of 6, in progressive order from 1 (bottom) to 6 (top) of system module -pattern- "of gender" PM, of broad three-dimensional bearing in the vertical dimension of 6 20 representative levels, D3, SC configuration. It is complemented with Figures 78.1 and 78.3, and

78.5 and 78.6. (Other characteristics are taught in the explanation of Figure 78.1).

 Figure 78.5: CS of level 5 of 6, in progressive order from 1 (bottom) to 6 (top) of system module -pattern- "of gender" PM, of broad three-dimensional bearing in the vertical dimension of 6 representative levels, D3 , SC configuration. It is complemented with Figures from 78.1 to 78.4, and

25 78.6. (Other characteristics are taught in the explanation of Figure 78.1).

 Figure 78.6: CS of level 6 of 6, in progressive order from 1 (below) to 6 (above) of system module -pattern- "gender" PM, of broad three-dimensional bearing in the vertical dimension of 6 representative levels, D3 , SC configuration. It is complemented with Figures from 78.1 to 78.5. (Other characteristics are taught in the explanation of Figure 78.1).

 30 Figure 79.1: Front view of the right interior face of "elevations views" of lateral faces (4 faces) of module type of tetra-modular system -pattern- "of gender" PM, with a wide three-dimensional arrangement in the dimension vertical of 6 representative levels, of SC configuration, with height measurement from level to level: 1, 5X (where X corresponds to the side measurement of a square section of the system); expressed for a survey of its sections and walls

35 dividers and support in transparent material. It is complemented with Figures of 72.2:

left inside face, 79.3: right outer face, and 79.4: left outside face. The top view of the module and the corresponding system (of invoice in transparent material) are represented in Figures 36, 37 and 38, 39 respectively; the distribution of the modular instances in the 6 levels of their size, are defined in Figures from 78.1 to 78.6; and its isometric representation in Figure 80

 Figure 79.2: Front view of the left interior side of "elevations views" of lateral faces (4 faces) of module type of tetra-modular system -pattern- "of gender" PM, with a wide three-dimensional arrangement in the vertical dimension of 6 Representative levels of SC configuration. It is complemented with Figures of 72.1: inner right face, 79.3: outer right face, and 79.4: left outer face. (Other characteristics are taught in the explanation of Figure 79.1). Figure 79.3: Front view of the right exterior face of "elevation views" of lateral faces (4 faces) of module type of tetra-modular system -pattern- "of gender" PM, of three-dimensional order in the vertical dimension of 6 Representative levels of SC configuration. It is complemented with Figures 79.1: interior right side, 79.2: interior left side, and 79.4: exterior left side. (Other characteristics are taught in the explanation of Figure 79.1). Figure 79.4: Front view of left outer face of "side elevations" of lateral faces (4 faces) of module type of tetra-modular system -pattern- "of gender" PM, of wide three-dimensional ordering in the vertical dimension of 6 representative levels, of SC configuration, with height measurement from level to level: 1, 5X (where X corresponds to the side measurement of a square section of the system); expressed for an elevation of its sections and dividing walls and of support in transparent material. It is complemented with Figures 79.1: interior right side, 79.2: interior left side, and 79.3: exterior right side. (Other characteristics are taught in the explanation of Figure 79.1).

Figure 80: Isometric presentation in transparent material of type of tetra-modular system -pattern- "of gender" PM, of three-dimensional order in the vertical dimension of 6 representative levels, of SC configuration, with approximate measurement of height of level at level: 1X (where "X" corresponds to the side measurement of a square section of the system). The zenith view of the module and the corresponding system (of invoice in transparent material) are represented in Figures 36, 37 and 38 and 39 respectively; the distribution of the modular instances in the 6 levels of their size, are defined in Figures from 78.1 to 78.6; Elevation views "of side faces (4 faces) of the module are presented in Figures from 79.1 to 79.4.

Figure 81: CS of type of systems without twin primitive crosses A and B, precursors of the lineage of types of "grid" systems, differentiated by directing the flow of their circuit in an opposite way, whose conjunction that in adjustment rectifies prolonging their conduits, generates primitive bi-modular grid systems.

 Figure 82: Form of opposing conjunction of the twin systems A and B to achieve the bi-modular primitive "grid" system.

 Figure 83: CS of type of primitive system mono-modular "grid" representative, of 10 crosses (), 30 instances settled in 20 sections.

 Figure 84: CS of the representative mono-modular "grid" model system type, of 10 crosses (), 33 instances seated in 23 sections.

Figure 85: coded identification of instances of a representative "grid" mono-modular model system, as well as a type of mono-modular standard grid systems, whose flow is given by the consecutivity of numerals of the system of consecutive codes of the numbering, SC configuration.

 Figure 86: CS of modules 1 and 2, shapers of the representative bi-modular "grid" system, of 6 1/2 crosses (), of 19 instances in the 12 1/2 modular sections, of representative dynamics.

Figure 87: CS of two-dimensional bi-modular primitive system type (representative of three-dimensional of same root), of modules of 6 1/2 crossings () per module, of 19 instances seated in 12 1/2 modular sections, of natural monocyclic dynamics.

Figure 88: CS of modules 1 and 2, shapers of the "bi-modular" bi-modular matrix system type of modules of 6 1/2 crossings () per module, of 20 modular instances seated in 13 1/2 modular sections, representative dynamics .

 Figure 89: CS of bi-modular "bi-modular" matrix system type (representative of three-dimensional of same root) of modules of 6 1/2 crossings () per module, of modules of 20 modular instances seated in 13 1/2 sections modular, representative dynamics. Figure 90: CS of modules 1 and 2, shapers of the bi-modular two-dimensional "grid" model system (representative of three-dimensional of the same root) of 6 1/2 crosses (), of 23 instances seated in 16 1/2 sections modular, representative dynamics.

Figure 91: CS of bi-modular "grid" pattern system of modules of 6 1/2 crosses (), of modules that identify its 23 modular instances seated in 16 1/2 modular sections, of representative dynamics. System composed of 46 instances settled in 33 sections. Figure 92: Encrypted identification of instances of modules 1 and 2 of the type of bi- modular "grid" standard system at the same time as modules 1 and 2 components of type of bi- modular grid systems whose flow is given by the consecutiveness of numerals of the system of consecutive codes of the numbering, configuration SC.

Figure 93: CS of modules 1 and 2, 3 and 4, shapers of the primitive tetra-modular system type "grid" of modules of 6 1/4 crosses (), of 16 1/2 instances settled in 10 V * modular sections , representative dynamics.

 Figure 94: CS of the tetra-modular primitive system "grid" of modules of 5 3/4 crosses (), of 16 modular instances settled on an average of 10 ¼ modular sections, representative dynamics.

Figure 95: CS of modules 1 and 2, 3 and 4, shapers of the tetra-modular matrix system "grid" of modules of 5 3/4 crosses (), of 17 1/2 instances settled in an average of 11 ¹ Λ sections modular, representative dynamics.

 Figure 96: CS of tetra-modular matrix system "grid" of modules of 5 3/4 crosses (), of modules of 17 1/2 modular instances seated in an average of 11 ¼ modular sections, of representative dynamics.

Figure 97: CS of modules 1, 2, 3 and 4, shapers of the tetra-modular matrix system "grid" of modules of 5 3/4 crosses (), of 19 1/2. Instances settled on an average of 13 VA modular sections, representative dynamics. Figure 98: CS of tetra-modular matrix system "grid" of modules of 5 3/4 crosses (), of modules of 19 1/2 modular instances seated in an average of 13 Vi modular sections, of representative dynamics.

 Figure 99: Encrypted identification of instances of modules 1, 2, 3 and 4 of the tetra-modular grid pattern system, together with modules 1, 2, 3 and 4 system type formers representing tetra-modular grid pattern whose flow is given by the consecutiveness of numerals of the system of consecutive codes of the numbering, SC configuration.

 Figure 100: CS of modules 1, 2, 3, 4, 5, 6, 7 and 8 conformers of the primitive modular octa-modular system of modules with an average of 9 7/8 crosses (), of 24 instances settled on an average of 14 1/8 modular sections, representative dynamics.

 Figure 101: CS of octa-modular "grid" primitive system of modules of 79 crossings equivalent to an average of 9 7/8 crossings () per module, of modules of 24 installed instances in an average of 14 1/8 modular sections, representative dynamics.

Figure 102: CS of modules 1, 2, 3, 4, 5, 6, 7 and 8 conformers of the matrix and pattern system at the same time octa-modular "grid" of modules of 11 1/8 crosses (), of 25 1 / 4 instances settled in 15 1/8 modular sections, representative dynamics.

 Figure 103: CS of matrix system and pattern at the same time, octa-modular "grid" of 200 instances seated in 121 sections, modules of an average of 9 7/8 crosses (), of 25 instances settled on an average of 15 1 / 8 modular sections, representative dynamics.

Figure 104: encrypted identification of instances of modules 1, 2, 3, 4, 5, 6, 7 and 8 shapers of the octa-modular "grid" pattern system.

 Figure 105: encrypted identification of instances of modules 1, 2, 3, 4, 5, 6, 7 and 8 forming the type of octa-modular "grid" pattern system, as well as the type of octa-modular pattern representative system " grid whose flow is given by the consecutiveness of numerals of the system of consecutive codes of the numbering, representative of similar "quadricular" systems bi and tetra-modular configuration SC.

 Figure 106: CS of "versatile" module of 9 crosses (), representative, type 1 (among several) of fourth generation, representative superfine shaper and conformation expressions of cylindrical systems and bulls.

Figure 107: CS of representative superfluous, conformed by plural concert of type of "versatile" module type 1, of fourth generation.

 Figure 108: Isometric view of type of tetra-modular system, D5 (representative), of cylindrical configuration SC, conformed by joint function of replicas of the module "versatile", type 1, of 9 crosses (), of fourth generation.

Figure 109: CS of the "versatile" primitive module of 9 crosses (), representative.

Figure 110: CS of "versatile" module of 9 crosses (), representative pattern.

Figure 111: Presentation of the encrypted identification of instances, relative to the sector occupied by the "versatile" module of 9 crosses (), -pattern- representative.

Figure 112: CS corresponding to superfluous portion covering 4 equilateral triangles fitting in total the content of 4 replicas of the "versatile" module of 9 crosses (), of type 1 of fourth, generation.

 Figure 113: Isometric view of type of SC configuration system regular tetrahedron representative, consisting of the compendium of 4 functionally connected replicas of the "versatile" module of 9 crosses (), type 1 of fourth, generation.

Figure 114: CS of "versatile" module of 9 crossovers () of type 2 of seventh generation, typical of hexa-modular system type, D5 (representative), of circular SC configuration.

Figure 115: CS of hexa-modular system type, D5 (representative), of circular configuration SC conformed by concert of 6 replicas of the module "versatile" of 9 crosses (), of type 2 of seventh generation, representative together with the type of system of Figure 117 of congeners. Figure 116: CS of "versatile" module of 9 crosses (), of type 2 of seventh generation, of hepta-modular system, D5 (representative), of circular CS.

 Figure 117: CS of the hepta-modular system type, D5 (representative), of circular SC configuration formed by concert of replicas of the "versatile" module of 9 crosses (), of type 2 of seventh generation, representative with the type of system of Figure 115 of congeners. Figure 118: Isometric type of conical SC bi-modular configuration system, of polycyclic dynamics via transfer, formed by concert of replicas of the "versatile" module of 9 crosses (), of polycyclic dynamics via transfer, of type 2 of seventh generation , representative with the type of system of Figure 119 of congeners.

Figure 119: Isometric type of configuration system SC conical penta-modular, of polycyclic dynamics via transfer, conformant in concert of replicas of the module "versatile" of 9 crosses (), of type 2 of seventh generation, of polycyclic dynamics via transfer , representative with the system of Figure 118 of congeners.

 Figure 120: Front view of "versatile" module of 9 crossovers () hemisphere cap, D5 (representative), which in concert of 4 replicas conforms the type of seven-generation system tetra-modular configuration SC semiesférjca, representative.

 Figure 121: Front view of seven-generation tetra-modular system type, SC hemispherical configuration, D5 (representative), made up of 4 replicas of the "versatile" module of 9 crosses () Hemisphere cap, representative.

Figure 122: CS of versatile module type of 9 crosses (), of 3rd. generation), expressed in hemispheres.

 Figure 123: Contents of the bi-modular system type conformed by dual concert of the "versatile" module of 9 crosses (), representative third generation inscribed in the CS of the lateral faces of a double straight cone.

Figure 124: Isometric type of bi-modular system of configuration SC double straight cone, conformed by plural concert of the module "versatile" of third generation, representative of congeners.

Figure 125: Face (repeated on the spherical reverse) of spherical SC configuration systems, bi-modular and expression at the same time of "versatile" module of 9 crosses (), third generation, representative.

 Figure 126: Spherical tri-modular system type face formed by plural concert of the versatile module of 9 crosses (), third generation, reprentative.

Figure 127: Face (repeated on the spherical reverse side) of spherical, tetra-modular CS systems conformed by plural concert of the "versatile" module of 9 crosses (), of third generation. Figure 128: Spherical, penta-modular CS system face conformed by 5 replicas of the "versatile" module of 9 crosses (), representative tertiary, representative with systems of Figures 124, 125, 126 and 127 of mono, hexa systems , hepta and octa-modular congeners. Figure 129: CS of representative type of "versatile" module of 9 crosses (), of polycyclic dynamics via transfer, of type 1 of seventh generation, shaper of types of cylindrical systems.

 Figure 130: Presentation of encrypted identification of instances, relative to the sector that occupy the "versatile" module of 9 crosses (), of polycyclic dynamics via transfer, of the type of representative, representative system.

Figure 131: CS of "versatile" module of 9 crosses (), of polycyclic dynamics via transfer, representative pattern.

 Figure 132: CS of "versatile" module of 9 crosses (), of polycyclic dynamics via transfer, representative primitive.

 Figure 133: CS of "versatile" module of 9 crosses (), of polycyclic dynamics via transfer, of the eighth generation system type, hexa-modular, of circular SC configuration, representative. Figure 134: CS of hexa-modular system type, of polycyclic dynamics via transfer, of representative eighth generation, conformed by concert of 6 replicas of the "versatile" module of 9 crosses (), of eighth generation, of polycyclic dynamics via transfer.

Figure 135: CS of "versatile" module of 9 crosses (), of polycyclic dynamics via transfer, of eighth generation, of the hepta-modular system type, of circular, representative SC configuration.

 Figure 136: CS of the hepta-modular system type, of circular SC configuration, formed by a concert of 7 replicas of the "versatile" module of 9 crosses (), of polycyclic dynamics via transfer, of the eighth generation.

Figure 137: Face (repeated on the spherical reverse side) of spherical CS systems, bi- modular and expression at the same time of "versatile" module of 9 crosses (), of polycyclic dynamics via transfer, of fourth generation, representative.

 Figure 138: Face of spherical CS system type, penta-modular of "versatile" module of 9 crosses (), of polycyclic dynamics via transfer, of fourth generation, which with that of Figure 137 is representative of those of congeners.

 Figure 139: Presentation of encrypted identification of instances, relative to the sector that occupy the module "versatile" class 1 of 10 crosses (), of the type of modular pattern system of plural, odd, representative conformation (compare with Figure 140).

Figure 140: CS of "versatile" module class 1 of 10 crosses (), of the standard system type of odd, representative plural modular conformation.

 Figure 141: CS of the "versatile" module class 1 of 10 crosses (), of the primitive system type of plural, odd, representative modular conformation.

 Figure 142: CS of "versatile" module spherical cap, of 10 crosses () class 1, of second generation, D5 (representative), of type of tri-modular systems, of spherical SC configuration, representative.

 Figure 143: Tri-modular system type face, D5 (representative), SC spherical configuration, tri-modular, "versatile" module class 1 of 10 crosses () class 1, second generation, representative.

Figure 144: Face of penta-modular systems type, D5 (representative), of spherical SC configuration, of "versatile" module of 10 crosses () class 1, representative second generation. Figure 145: CS of "versatile" module of 10 crosses () class 1, of sixth generation, of system type, hepta-modular, D5 (representative), of circular CS, representative.

Figure 146: CS of hepta-modular system type, D5 (representative), of circular SC configuration, of "versatile" module of 10 crosses () class 1, of sixth generation, representative. Figure 147: Presentation of encrypted identification of instances, correlative with the sector that occupy the "versatile" module of 10 crosses () class 1, of polycyclic dynamics via transfer, of the type of system -pattern- of plural modular conformation odd, representative ( compare with Figure 148).

Figure 148: CS of "versatile" module of 10 crosses () class 1, -pattern- of polycyclic dynamics via transfer, of the type of modular pattern system of plural odd, representative conformation (compare with Figure 147).

 Figure 149: CS of "versatile" module of 10 crosses () class 1, -of polycyclic dynamics via transfer, of the primitive system type of modular plural odd, representative conformation. Figure 150: "Versatile" module of 10 crossovers () Class 1 sphere cap, of polycyclic dynamics via third generation transfer, of the penta-modular system type SC spherical configuration, representative.

 Figure 151: Face of penta-modular system type, of SC spherical configuration, of "versatile" module of 10 crosses () class 1, of third generation, of polycyclic dynamics via transfer, representative.

 Figure 152: CS of "versatile" module of 10 crosses () class 1 of polycyclic dynamics via seventh generation transfer, of the hepta-modular system type, of circular SC configuration, representative.

 Figure 153: CS system type compact circular, hepta-modular, module "versatile" dynamic polycyclic via transfer, 10 crosses () class 1, fifth generation, representative.

Figure 154: Presentation of encrypted identification of instances: -...; 14 TO ; 14B; 14C correlated with the sector they occupy in the module, -a replace- with the instance in critical sector identified 14A-B of the "versatile" module of 9 crosses () of a first generation system type that discriminate it, and of the "versatile" module of 9 crosses () of polycyclic dynamics via transfer of a type of first generation system that thus discriminates it; for the registration of types of "versatile" module of 9 crosses () class 2, -pattern-, and versatile module of 9 crosses () of polycyclic dynamics via class 2 transfer, parton- (compare with Figure 155).

Figure 155: Position occupied in the module, of the instances identified: ...; 14A; 14B; 14C that substitute the one occupied by the critical sector 14A-B of the "versatile" module of 9 crossings () -of the first generation-, and of the versatile module of 9 crossings () of polycyclic dynamics via transfer -of first generation-, of 9 crosses () class 1, for the registration of types of "versatile" module of 9 crosses () class 2, -pattern-, and versatile module of 9 crosses () of polycyclic dynamics via transfer class 2, -pattern- (complements Figure 154).

 Figure 156: CS of "versatile" module of 9 crosses () class 2, of fifth generation, of type of tri-modular system, D5 (representative), of circular configuration SC, representative.

Figure 157: CS of tri-modular system type, D5 (representative) of circular SC configuration, formed by replication concert of the "versatile" module of 9 crosses () class 2, of fifth generation, representative.

 Figure 158: CS of "versatile" module of 9 crosses () of polycyclic dynamics via transfer, class 2, of tenth generation, of type of tri-modular system, of circular SC configuration, representative.

 Figure 159: Type of tri-modular system, D5 (representative), of circular compact CS, conformed by concert of 3 replicas of the "versatile" module of 9 crosses (), of polycyclic dynamics via transfer, class 2, of tenth generation, representative.

Figure 160: Presentation of encrypted identification of instances: 14A; 14B / 14B ^" ; 14C relative to the sector they occupy in the module, -a replace- by the critical sector instances identified 14/14 ^" of the "versatile" module of 9 crosses () class 1, of the first type of system generation that discriminates this way, and of the versatile module of 9 crosses () of polycyclic dynamics via transfer, class 1, of the type of first generation system that thus discriminates them; for the registration of types of "versatile" module of 10 crosses () class 3, -pattern-, and "versatile" module of 10 crosses () of polycyclic dynamics via class 3 transfer, partón- (compare with Figure 161).

Figure 161: Position they occupy in the module, of the instances identified ...; 14 TO ; 14B / 14B ^' ; 14C; ..., which replace those occupied by the critical sector 14/14 ^' of the "versatile" module of 10 crosses () class 1, -of the first generation-, and of the "versatile" module of 9 crosses () of polycystic dynamics via first-generation transfer, class 1, for the registration of types of "versatile" module of 10 crosses () class 3, -pattern-, and "versatile" module of 10 crosses () of polycyclic dynamics via transfer class 3, -pattern- (compare with Figure 154).

 Figure 162: CS of "versatile" module of 10 crosses () class 3, of fourth generation, shaper of tri-modular system type, D5 (representative), of circular SC configuration, tri- modular, representative.

Figure 163: CS of tri-modular system type, D5 (representative), of circular SC configuration, conformed by concert of 3 replicas of the "versatile" module of 10 crosses () class 3, of the fourth generation; representative.

 Figure 164: CS of "versatile" module of 10 crosses () class 3, of polycyclic dynamics via transfer, of eighth generation, of type of tri-modular system, of circular SC configuration, representative.

 Figure 165: CS of tri-modular system type, of circular SC configuration, formed by concert of 3 replicas of the "versatile" module of 10 crosses () class 3, of polycyclic dynamics via transfer, of eighth generation, representative.

 Figure 166: Module "plastic" 1 of 9 crosses () of CS square, primitive, representative. Figure 167: Module "plastic" 1 of 9 crosses () of CS triangular, primitive, representative.

Figure 168: Module "plastic" 1 of 9 crosses () of CS square, pattern, representative.

Figure 169: Module "plastic" 1 of 9 crosses () of CS triangular, pattern, representative.

Figure 170: Module "plastic" 2 of 10 crosses () of CS square, primitive, representative.

Figure 171: Module "plastic" 2 out of 10 crosses () of CS triangular, primitive, representative. Figure 172: Module "plastic" 2 of 10 crosses () of CS square, pattern, representative.

Figure 173: Module "plastic" 2 of 10 crosses () of CS triangular, pattern, representative.

Figure 174: Presentation of the encrypted identification of instances, relative to the sector occupied by the "plastic" module 1, of the SC configuration of 9 crosses (), of the representative, standard system type (compare with Figure 168).

Figure 175: Presentation of the encrypted identification of instances, relative to the sector occupied by the "plastic" module 2 of the SC configuration of 10 crosses (), of the representative, standard system type (compare Figure 172).

 Figure 176: Presentation of encrypted identification of instances, relative to the sector occupied by the "plastic" module 1 of triangular SC configuration of 9 crosses (), of the representative system type, representative (compare with Figure 169).

 Figure 177: Presentation of the encrypted identification of instances, relative to the sector occupied by the "plastic" module 2 of triangular SC configuration of 10 crosses (), of the representative system type, representative (compare with Figure 173).

 Figure 178: "Plastic" module 1 of 9 crosses (), of square SC configuration, typical of a tetra-modular matrix system, polygonal (square), representative for plastic module systems 2 of 10 crosses () and lineages of congeners of both types.

 Figure 179: Type of tetra-modular matrix system, polygonal (square), of "plastic" module 1 of

9 crosses (), of SC square configuration, representative of plastic module systems

2 and of lineages of congeners of both types.

Figure 180: CS of "plastic" module 2 of 10 crossings () matrix, typical of the penta-modular polygonal (pentagonal) matrix system type, representative of plastic module systems 1 of

9 crosses (), and lineages of congeners of both types.

Figure 181: System type penta-modular matrix, polygonal (pentagonal), module "plastic" 2 out of 10 crosses () of configuration SC square of origin, representative of systems of module "plastic" 1 of 9 crosses (), and of lineages of congeners of both types.

Figure 182: Type of mono-modular matrix system, polygonal (irregular), of "plastic" module 2 of 10 crosses (), of square SC configuration of origin, representative of "plastic" module systems 1 of 9 crosses (), and of lineages of congeners of both types.

Figure 183: Configuration SC conformed by 3 replicas of the module "plastic" 1 of 9 crosses (), matrix, D5 (representative), and 3 replicas of its specular simile, representative of similar conformation with the module "plastic" 2 of 10 crosses (); antecedent stage of the incorporation of cubic SC configuration system types.

 Figure 184: Isometric view of type of configuration system SC cubica hexa-modular, module "plastic" 1 of 9 crosses (), matrix, D5, representative of the type of simile systems formed by replicas of the plastic module 2 and its simile speculate.

 Figure 185: View of "plastic" module 1 of 9 crossovers () sphere cap, typical of hexa-modular system type, D5 (representative), of order from the type of cubic SC configuration systems.

Figure 186: View of "plastic" module 2 of 10 crossovers () sphere cap, typical of hexa-modular system type, D5 (representative), of sorting from the type of cubic SC configuration systems.

 Figure 187: CS of spherical system type, matrix, hexa-modular, D5 (representative), of order coming from the type of cubic SC configuration systems, formed by conjunction of three replicas of the binomial composed of the "plastic" module 1 of 9 crosses () sphere cap and its specular simile.

 Figure 188: CS of spherical system type, matrix, hexa-modular, D5 (representative), of sorting from the type of cubic SC configuration systems, formed by conjunction of three binomials composed of the "plastic" module 2 of 10 crossovers () sphere cap and its specular simile.

 Figure 189: CS front view of "plastic" module 2 out of 10 crossovers () spherical cap, typical of tetra-modular matrix spherical system type, D5, representative of plastic sphere cap module 1 of 9 crossovers () and of lineages of congenours.

 Figure 190: CS of spherical system type, matrix, tri-modular, D5 (representative), conformed by replicas of the "plastic" sphere cap module 1 of 9 crosses (), representative of congener lineages.

 Figure 191: CS of spherical system type, matrix, tetra-modular, D5 (representative), conformed by replicas of the "plastic" sphere cap module 2 of 10 crosses (), representative of congener lineages.

Figure 192: CS of plastic system type 2 of 10 crosses (), matrix, D5, hexa-modular configuration SC equilateral triangle, representative of those of congeners.

Figure 193: CS of primary system type, octa-modular, D5 (representative), of octagonal SC configuration consisting of 8 replicas of "plastic" module 1 of 9 crosses () of configuration SC isosceles triangle, variation with origin in equilateral triangle , representative of those of congeners.

 Figure 194: CS of type of matrix system, bi-modular, D5 (representative), of irregular SC configuration conformed by 2 replicas of module "plastic" 2 of 10 crosses (), of SC configuration originally equilateral triangle, representative of congeners.

Figure 195: Configuration SC conformed by 3 replicas of module "plastic" 1 of 9 crosses (), matrix, D5 (representative), of configuration SC equilateral triangle, previous form of the constitution of type of tri-modular system of configuration pyramidal SC , representative.

Figure 196: Configuration SC conformed by 4 replicas of module "plastic" 2 of 10 crosses (), matrix, D5 (representative), of configuration SC equilateral triangle, previous form of the constitution of type of tetra-modular system of configuration pyramidal SC , representative. Figure 197: Isometric view of type of matrix system, tri-modular, D5, of pyramidal SC configuration (pyramid of 3 faces), conformed by 3 replicas of module "plastic" 1 of 9 crosses (), representative of congeners.

 Figure 198: Isometric view of type of matrix system, tetra-moduiar, D5, of pyramidal SC configuration (pyramid of 4 faces), conformed by 4 replicas of module "plastic" 2 of 10 crosses (), representative of congeners.

 Figure 199: Front view of "plastic" module 2 of 10 crosses () hemisphere cap, typical of the tetra-modular matrix system type, D5 (representative), of SC hemispherical configuration, representative of congeners.

Figure 200: Front face view of type of tri-modular matrix system, D5 (representative), of SC hemispherical configuration, formed by 3 replicas of "plastic" module 1 of 9 crosses () hemisphere cap, representative of congeners.

 Figure 201: Front face view of type of tetra-moduiar matrix system, D5 (representative), of SC hemispherical configuration, formed by 4 replicas of "plastic" module 2 of 10 crosses () hemisphere cap, representative of congeners.

 Figure 202: Configuration SC parallelogram corresponding to modular binomial conformed by: a module "plastic" 1 of 9 crosses (), matrix, D5 (representative), of SC configuration equilateral triangle, and its specular simulation; in which they share the space destined to the transit instances of the flow between modules, a binomial that in number of 6 replicas in a joint function make up elementally the type of dodeca-modular system of SC configuration (star of 6 points), representative of binomials conformed by the plastic module 2 of 10 crosses (), and its specular simulation.

 Figure 203: CS of module "plastic" 1 of 9 crosses () pattern, D5 (representative), of original SC configuration equilateral triangle, conformer with its specular simulation of a modular binomial type in which the stretches of the common channel of both destined from triangular precursors, to the transit between modules. The shared sections are drawn in dashed line.

Figure 204: CS of module "plastic" 1 of 9 crosses () primitive, D5 (representative), of original SC configuration equilateral triangle, conformer with its specular simulation of a type of modular binomial in which the sections of the common channel of both destined from triangular precursors to the transit between modules merge into one. The shared sections are drawn in dashed line.

 Figure 205: Presentation of encrypted identification of instances, relative to the sector that occupy the module "plastic" 1, of 9 crosses, pattern, modular binomial component with its specular simulation, bimómio in which transit of the flow between both modules is performed components. Figure 206: CS of module "plastic" 2 of 10 crosses (), pattern, D5 (representative), of original SC configuration equilateral triangle, conformer with its specular simulation of a type of modular binomial in which the sections merge into one of the common channel of both destined from triangular precursors to the transit between modules. The shared sections are drawn in dashed line.

 Figure 207: CS of module "plastic" 2 of 10 crosses () primitive, D5 (representative), of original SC configuration equilateral triangle, conformer with its specular simulation of a type of modular binomial in which the sections of the common channel of both destined from triangular precursors to the transit between modules. The shared sections are drawn in dashed line.

 Figure 208: Presentation of encrypted identification of instances, relative to the sector occupied by the "plastic" module 2 of 10 crosses (), modular binomial component with its specular simulation, bimómio in which flow is carried out between both component modules ^ Figure 209: Type of dodeca-modular system, matrix, of star-shaped SC configuration (star of 6 points), D5 (representative), made up of 6 modular binomials formed in turn by 1 "plastic" module 2 of 10 crosses ( ) matrix, D5 (representative), of SC configuration equilateral triangle, with its specular simulation, representative of congeners, dodeca-modular system types of binomials of base plastic module 1 of 9 crosses (), and together with the one corresponding to the Figure 228, of types of multi-modular systems.

 Figure 210: Rhomboid SC configuration corresponding to modular binomial conformed by a "plastic" module 1 of 9 crosses () matrix, D5 (representative), of SC configuration of equilateral triangle origin partially fused with its functionally simulate specular, binomial that in concert with 4 replicas conform elementally the type of octa-modular system of starred SC configuration (star of 4 points), representative for binomials formed by the plastic module 2 of 10 crosses (), and its specular simulation.

 Figure 211: Type of octa-modular system, matrix, of star-shaped SC configuration (4-pointed star), D5 (representative), formed by 4 modular binomials shaped in turn by a "plastic" module 1 of 9 crosses () matrix, D5 (representative), of configuration SC equilateral triangle partially fused with its functionally similarly specular formally asymmetric, configuration romboid SC, representative of congeners, and for octa-modular system types of binomials of base plastic module 2 of 10 crosses () .

Figure 212: Irregular surface configuration corresponding to the partial functional union _. of 3 modular binomials of configuration SC parallelogram, binomials composed by the module "plastic" 1 of 9 crosses () matrix, of SC configuration originally equilateral triangle, partially fused with its, in terms of functional aspect specular, formally asymmetric; Surface configuration prior raw material for the incorporation of types of SC configuration system irregular, representative hexahedron.

Figure 213: Hieometric view of hexa-modular matrix system type, D5 (representative), of irregular SC hexahedral configuration, formed by the CS of 3 replicas connected in function, of the binomial type composed of the type "plastic" module 2 out of 10 crosses () in partial fusion with its functional formally asymmetric specular simile, representative of system types of irregular six-sided SC configuration, conformed by binomials of plastic module 1 of 9 crosses () and 2 of 10 crosses () in partial fusion with their respective specified specular similes.

 Figure 214: Irregular surface configuration corresponding to the partial functional union of 4 modular binomials of SC parallelogram configuration, binomials in which transit is carried out between its 2 partially fused components: the "plastic" module 2 SC configuration matrix originally equilateral triangle, and its functionally mirrorlike simile; Surface configuration prior raw material for the incorporation of regular, representative octahedron SC configuration system types.

 Figure 215: Isometric view of type of octa-modular matrix system, D5 (representative), of regular octahedron SC configuration, formed by 4 replicas (Figure 213), of the modular binomial type composed of the "plastic" module 2 of 10 crosses (), fused to its functionally simulate mirror, representative of irregular hexagon SC configuration system types, formed of binomials of plastic module 1 of 9 crosses () and 2 of 10 crosses () in partial fusion with their respective specified specular similes.

Figure 216: Front view of the modular binomial sphere shell made up of the "plastic" module 1 of 9 crossovers () fused pacially with its functionally similar mirror, of curved SC configuration, binomial that in the number of 3 replicates conforms the type of hexa system - SC spherical configuration module.

 Figure 217: Front face view of type of SC spherical configuration system, hexa-modular matrix, D5 (representative), formed by 3 modular binomials, sphere cap formed by the "plastic" module 1 of 9 crosses () partially fused with its similiar specular.

 Figure 218: Front view of the modular binomial sphere shell formed by the "plastic" module 1 of 9 crossovers () partially fused with its functionally simulated specular, of curved SC configuration (Figure 215), which binomial in number of 4 replicas functionally connected conforms the type of octa-modular system of spherical SC configuration.

Figure 219: Front face view of type of SC spherical configuration system, hexa-modular matrix, D5 (representative), formed by concert of 4 replicas of the modular binomial sphere shell formed by the "plastic" module 1 of 9 crosses ( ), partially fused with its specular simile. Figure 220: Module "plastic" 1 of 9 1/2 crosses (), pattern, D5 (representative), of configuration SC equilateral triangle, conformador with its specular simulation of the type of modular binomial in which they share a section in which it produces crossing of the transit trajectories between binomials to opposite emitter modules.

Figure 221: Module "plastic" 1 of 9 1/2 crosses (), primitive, D5 (representative), of SC configuration equilateral triangle, conformer with its specular simulation of the type of modular binomial in which they share a section in which it produces crossing of the transit trajectories between binomials to opposite emitter modules.

 Figure 222: Presentation of the encrypted identification of instances, relative to the sector occupied by the "plastic" module 1 of 9 1/2 crosses (), modular binomial component with its specular simulation, bimómio in which they share a section in which Crossing of the transit paths between binomials to opposite emitter modules occurs.

Figure 223: CS of module "plastic" 2 of 10 1/2 crosses (), pattern, D5 (representative), of SC configuration equilateral triangle, conformer with its specular simulation of a type of modular binomial in which they share a section in the one that occurs crossing of the trajectories of transit between binomials to modules of opposite emisferios.

 Figure 224: CS of module "plastic" 2 of 10 1/2 crosses (), primitive, D5 (representative), of original SC configuration equilateral triangle, conformer with its specular simulation of a type of binomial modularen the share a section in the that there is a crossing of the trajectories of transit between binomials to modules of opposite emitters.

 Figure 225: Presentation of the encrypted identification of instances, relative to the sector occupied by the "plastic" module 2 of 10 1/2 crossings (), composed of a modular binomial with its functionally specular simulation, bimómio in which they share a section in the that there is a crossing of the trajectories of transit between binomials to modules of opposite emitters. Figure 226: Modular binomial CS conformed by the plastic module 1 of 9 1/2 crossings (), matrix, of CS of equilateral triangle origin, together with its functionally specular simulation whose internal angle is 120 °; conformador in number of 3 replicas of the type of hexa-modular matrix system, D5 (representative), of SC configuration flat, star of 3 points, representative. Figure 227: Type of matrix system, hexa-modular, D5 (representative), of SC configuration 3-star star plan, formed by 3 replicas of the modular binomial composed of the plastic module 1 of 9 1/2 crosses (), matrix of crosses (), of CS of equilateral triangle origin, together with its complementary, representative specular simile.

Figure 228: Modular binomial CS conformed by the plastic module 2 of 10 1/2 crosses (), matrix, of CS of equilateral triangle origin, together with its complementary specular simile whose internal angle is 72 °; conformador in number of 5 replicas of the deca-modular matrix system type, D5 (representative), of flat SC configuration, 5-pointed star, representative. Figure 229: Type of matrix system, deca-modular, D5 (representative), with a 5-star star-shaped SC configuration, consisting of 5 modular binomial replicas composed of the plastic module 2 with 10 1/2 crossings (), matrix, of CS of equilateral triangle origin, together with its mirror image complementary, representative.

 Figure 230: Flat SC configuration consisting of 3 modular binomials formed by plastic module 1 of 9 1/2 crosses (), matrix, of CS equilateral triangle, together with its specular simulation, necessary raw material for the incorporation of types of systems hexa-modular configuration SC hexahedron irregular, representative.

Figure 231: Isometric view of hexa-modular matrix system type, of irregular SC hexahedron configuration, conformed by 3 binomials composed by plastic module 2 of 10 1/2 crosses (), matrix, of CS equilateral triangle, together with its simile speculate, representative. Figure 232: Front view of plastic module 1 of 9 1/2 crosses (), of modular binomial sphere cap, component with its mirror-like modular binomial that in number of 3 functionally connected replicas conforms the type of hexa-modular system of plastic module 1 of 9 1/2 crossings (), of 2 revolutions per cycle, of spherical SC configuration.

Figure 233: Front face view of type of spherical SC configuration system, hexa-modular matrix, D5 (representative), of 2 revolutions per cycle, formed by 3 modular binomials of sphere, formed in turn by the plastic module 1 of 9 1/2 crosses () along with its specular mirror.

 Figure 234: Front view of plastic module 2 of 10 1/2 crossings of modular binomial sphere cap, component with its modular simulation of the modular binomial that in number of 3 functionally connected replicas conforms the type of hexa-modular system, of plastic module 2 of 10 1/2 crosses (), of 2 revolutions per cycle, of spherical SC configuration.

 Figure 235: Front face view of type of spherical SC configuration system, hexa-modular matrix, D5 (representative), of 2 revolutions per cycle, formed by 3 modular binomials of sphere, formed in turn by the plastic module 2 of 10 1/2 crosses () along with its specular mirror.

Claims

-Reclaims

 1.-The broad spectrum that covers 4 generic types of coherent orderings called "lineages" that involve constant factors and are the result of a combination of variable factors, exposed by surface configurations of systems representative of the variables, their represented, and derivations; the first generic type of which is recorded here as double trunk or consisting of two types or complementary genera; named lineages: lineage of types of "genus" systems b and poly modular, Figures 14, 17, 21, 22, 23, 27, 29, 31, 33, 35, 37, 39, 45, 48, 51, 53 , 55, 57, 59, 61, 66, 68; Lineage of types of "grid" systems, Figures 83, 84, 85, 87, 89, 91, 94, 96, 98, 101, 103, 105; Lineage of type of systems conformed by types of modules called "versatile", Figures 108, 113, 115, 117, 118, 119, 121, 124, 125, 126, 127, 128, 134, 136, 137, 138, 143, 144, 146, 151, 153, 157, 159, 163, 165; and lineage of types of systems made up of types of modules called "plastics", Figures 179, 181, 182, 184, 187, 188, 190, 191, 192, 193, 194, 197, 198, 200, 201, 209, 211 , 213, 215, 217, 219, 227, 229, 231, 233, 235.

2.-The forms, manners and guidelines as shown by the representative systems, are representative of other forms, ways and guidelines that in any dimensional disposition they express or contain-

3. - The spectrum that encompasses the variety of coherent arrangements in the vertical dimension of the modular contents, is illustrated and represented in the first place by specific modular arrangements in the vertical, of types of systems of 6 crosses that consist of: two levels or Plants: Figures 70.1 and 70.2; 71.1 and 71.2; 72.1 and 72.2; 73.1 and 73.2; 74.1 and 74.2; five levels: Figures 81.1 to 81.5; 83.1 to 83.5; up to the economic limit of six levels: Figures 75.1 to 75.6; 78.1 to 78.6; 82.1 to 82.6; complemented by views of elevations: Figures 76.1 to 76.4 and 79.1 to 79.4; isometric projection: Figure 77); and photography: Figure 80, and o through encrypted records; referring to that all two-dimensional expression of modules and systems that conform, coinciding with the zenith view of modules and systems that are of transparent three-dimensional shape, share the same -surface configuration-, and are represented by it.

 4. -The ideal expressions among others of two-dimensional system types, represented by figurations that respond to the concept of "surface configurations" of system types of the 4 lineages, with which system types of the various dimensions and delivery are covered. dimensional, have as direct exponents to the mono and bi-modular quadratic system types: Figures 83, 84, 87, 89 and 91; they are directly representative of the corresponding ideal figurations of the types of bi-modular systems remaining in their lineage, and those of the two-dimensional system types of the other lineages.

5.-The form of expression on its convexity, of representative systems inscribed in geometric bodies, is representative of its expression in the concavity of said bodies.

6.-the quality of ambivalent of any system: with a disposition of conductive orientation of the adopted system representative of the other, its mirror-like reflection - (example: Figures 15 and 16).

7.-The approaches or modular forms adopted: they are representative of other formal modular approaches that make up the same types of exposed systems- (example: Figures 24 and 25, 40, 41, 42 and 43).

 8. -icon which means: terminal pole of cycle or house of color (Figure 7); Initial poles of cycle or 5 standby of systems that print D3, D4 and D5 respectively (Figures 8, 9, 10), and cyclic record instance (: signal that marks output and goal) (Figures 11, 12, 13) ; representative of their mirror-like similes

9. -They generally appear with recurrence of exceptions, from types of bimodal to octa-modular systems, representative of systems conformed by smaller or greater number of

10 modules.

 10.-In general, except for exceptions, there are even types of module saturated with proportional sections, called -Patron-, as the basis for the registration of module types since the primitive of their lineage; representative of derivations composed by greater number of instances.

 15 11.-The types of primitive systems of "gender" cyclic record: Figures 60, 61, 62, 63, 65, 66, 67, 68 of SD configuration, are representative of the other types of systems of their surface configuration and of the range of types of partially distended surface configuration systems of the 4 lineages.

 12.-The family includes derived systems with only some key instances signed with code 20 conductive-.

 13.-The family includes non-sectioned derivative systems, with instances only represented by conductive signs and or consecutive systems or systems (examples: Figures 14, 28, 29).

14.-The family includes derived systems, with instances represented with consecutive codes, such as numbering and spelling and combinations or cooperations (example: Figures 22,

25 23, 38, 39) -.

 15.-The family includes extreme derived systems, which do not have panels with read-mark charts.

 16.-The family includes derived three-dimensional systems, of material structure or computer simulation, of quality: non-transparent, translucent, reflective and mixtures.

 30 17.-The family includes non-registered derivative systems, which consist of a greater or lesser number of crosses () per module-.

 18.-The family includes types of system inscribed in forms and bodies that are manifest and logically justified but not registered directly by figures, although they are encrypted, and those represented manifest, logically and justifiably by others that are figuratively and / or indirectly exposed in the descriptive memory.