CN102724237A - ICT technical support design for market allocation unit of global value chain - Google Patents

Abstract

The present invention is the 482nd one among an invention cluster that is generally titled as a global value chain network technology support system (known as DCN/IIL (VC)) and includes 600 inventions, wherein the invention patent cluster is submitted by the applicant Li Zongcheng to the State Intellectual Property Office of the People's Republic of China through an electronic system in September, 2011. The invention relates to an ICT technical support design for a market allocation unit of a global value chain. As a novel technology, the provided design is characterized in that: on the basis of establishment of a new logic foundation, a new mathematic foundation and a new scientific foundation, with an internet user as a center and then a multi-level global value chain (GVC) as a center as well as with computer aided system and internet-based connection and coordination of a cognitive system and a practice system as main lines of a high-level intelligent integrated system (HIIS) evolution process, the design is realized by establishing a basic model, a normal form and an equation system of network configuration dynamics as well as a basic model, a normal form and an equation system of game organization synergetics, so that a cloud computing system can be transformed into a heaven and earth computing system gathering and encompassing every thing.

Description

ICT technical support design of global value chain market configuration unit

Technical Field

The applicant proposes a "global value chain network technology support system [ DCN/IIL (VCSE) ], which comprises 600 patents including the invention, the global value chain system (GVC) is taken as a core, connection and coordination of natural intelligence and artificial intelligence based on a computer and a network thereof are taken as a main line of a General Intelligent Integrated System (GIIS) upgrading process, a brand-new logic foundation, a brand-new mathematical foundation, a brand-new scientific foundation and a brand-new technical foundation and a brand-new engineering foundation are established, a relatively closed and relatively static 'resource pool' -cloud computing network is injected with soul, intelligence and life, a global intelligent integrated collaborative network computer system (CS/HSN (GII)) is established, and the global Internet is created into a technical support system which has the nature of life and ecological holographic collaborative organization. On the basis, a global value chain system (GVC) is taken as a core, connection and coordination of a cognitive system and a practice system based on a computer aided system and the Internet are taken as a main line of an evolution process of a high-grade intelligent integrated system (HIIS), an intelligent integrated scientific and technical system (IIS & IIT) based on a completely new scientific theory of a meta-system (MS) is established, a novel global Internet endowed with life vitality is integrated with a logistics network, an energy network, a financial network and a knowledge network which are scattered at each department of all fields of the world, global value chain system engineering is vigorously carried out, and a global intelligent integrated dynamic convergence network system (DCN/HII (GVC)) with the real life and ecological holographic synergetic organization property is established, so that an intelligent integrated network, a life Internet and an ecological operation network are built. By implementing a global value chain system engineering technology cluster to develop a general strategy, which is called as a 'open the earth' plan by the inventor, an overlooked 'cloud' computing system is transformed into a 'heaven and earth' computing system which can be used for connecting everything and runs through longitude and latitude.

The invention mainly aims to provide a configuration unit design basis for global value chain market configuration through a brand-new logic basis, a mathematic basis, a scientific basis and a brand-new technical basis and engineering basis.

All the mathematical models referred to in this description have original innovations.

The invention belongs to the field of network technical support facing global value chain market configuration, market organization and market management (MA/GVC), is an intelligent integrated technical foundation facing global value chain and further facing a global value chain market configuration system, and is a key for guiding people, organizations and organizations from ever-variable 'cloud' (computing system) to 'heaven and earth' (brand-new computing system) converging everything.

The MA/GVC is a solution of global value chain system engineering, which introduces the service strategy and operation mode of global value chain into the whole internal and external association system of global value chain market configuration using information system as backbone by means of new information technology and network technology, it is not only the technology change, but also the comprehensive integration and configuration of all the related processes of personnel, fund, logistics, manufacturing and global value chain organization across regions or countries.

The MA/GVC is global value chain configuration software which integrates material resource configuration (logistics), human resource configuration (people flow), capital resource configuration (money flow) and information resource configuration (information flow) related to the inside and the outside aiming at the global value chain market configuration. Next generation longitudinal association department, transverse association department and Value Resource Planning (VRP) software are described through DIM analysis of rule designers, system integrators and module generators facing the internal and external association of global value chain market configuration and SHF analysis of final consumers, social regulatory agencies, relatives at home and abroad, which are provided by the inventor. It will contain the global value chain market configuration internal and external associated user/service system architecture, using graphical user interface, application open system production. In addition to existing standard functionality, it includes other characteristics such as quality of correlation inside and outside the global value chain market configuration, process operational configuration, and regulatory reporting of correlation inside and outside the global value chain market configuration. In particular, the underlying technology employed by the MA/GVC will provide the global value chain market with both internal and external associated independence of both user software and hardware to make it easier to upgrade. The key to MA/GVC is that all users associated inside and outside the global value chain market configuration can tailor their applications and thus have natural ease of use.

Background

In recent years, the integration of three networks in the ICT industry and the cloud computing network technology have been greatly promoted in China and abroad. Grids attempt to achieve a comprehensive sharing of resources on the internet, including information resources, data resources, computing resources, software resources, and the like.

However, at present, the fusion of three networks in the ICT industry is in danger of losing life, the innovativeness of the cloud computing technology is seriously insufficient, the application of the cloud computing is limited, and the development of the cloud computing system is in an embarrassing situation of being hot and cold in industry. With the rapid development of computer technology and network technology, financial innovation and increasing financial risk, market competition is further aggravated, the competition space and range of the global value chain are further expanded, and the integration of global economy is continuously promoted. The twenty-first 90 s are mainly oriented to the idea of overall allocation of resources in the global value chain, and then gradually develop into an allocation idea how to effectively utilize and allocate the whole resources. In this situation, the inventors first proposed a conceptual report of MA/GVC.

On the basis of establishing a connecting set based on an intelligent integrated economy multi-attribute measurement space, a connecting operator based on an intelligent integrated economy multi-rule measurement matrix, a connecting relation based on intelligent integrated economy multi-factor variable-weight synthesis and a connecting function based on an intelligent integrated economy manifold system, the inventor provides a brand new network system, namely a global dynamic connecting network, which takes an information network as a platform and integrates a logistics network, a knowledge network and a financial network into a whole; further, a brand-new computing system including cloud computing and grid computing, namely a 'heaven and earth' computing mode facing knowledge resource allocation, physical resource allocation and financial resource allocation, is developed and established; further, a new operating system, namely a holographic cooperative operating system (OS/HSO), which is a new operating system that is integrated with various cognitive operations and practical operations by using a computer operating system and an Internet operating system as keys, is developed and established.

The invention provides a global value chain dynamic convergence network system DCN/IIL (VCSE), which is a global open network system which integrates a logistics network (MN), an energy flow network (EN), an Information Network (IN), a Financial Network (FN) and a Knowledge Network (KN) into a whole and provides comprehensive integrated service IN the whole field, the whole system and the whole process, wherein the global Value Chain System (VCS) is from a product value chain PVC (PVC) and a global value chain GVC, to an industrial value chain IVC and a regional value chain RVC, to a national value chain NVC and a global value chain GVC) as a core, and the three networks of a telecommunication network (MCN), a computer network (WWW) and a Broadcast Television Network (BTN) are integrated into a main technical support.

The invention provides a global dynamic convergence network to be developed and established and a world computing and holographic cooperative operation System (OS/HSO for short), which is a complete complex System. The heaven and earth computing aims to integrate a plurality of relatively low-cost computing entities into a complete intelligent integrated system with strong computing power through a logistics, knowledge and financial total-convergence network supported by an information network, and distribute the strong computing power to external and internal terminal users of the information network by means of brand-new business modes such as SaaS/HSO, PaaS/HSO, IaaS/HSO, MSP/HSO and the like inside and outside the information network.

The concept of global dynamic convergence network computing can be regarded as an application mode which integrates and interpenetrates a logistics network, a knowledge network and a financial network by taking an information network as a platform. Global dynamic convergence network computing is not only oriented to computers and information networks, but also to logistics networks, knowledge networks, and financial networks. The intelligent integrated system tries to surpass information calculation and information network calculation, and tightly links the information calculation and the information network calculation with the collection, the penetration and the operation of a logistics network, a knowledge network and a financial network, thereby realizing intelligent integration.

As the basis of the invention, the brand-new logic basis comprises holographic convergent logic, bipolar convergent logic and bipolar holographic convergent logic; the brand new mathematics foundation comprises holographic convergent mathematics, dipolar convergent mathematics and system transition analytical mathematics; the brand new scientific basis comprises resource allocation dynamics, holographic organization synergetics, a system efficacy value theory, game organization synergetics, hedging balance economics, holographic confluent physics and through science (cross science and transverse science) formed by the large synthesis of a series of brand new theories, namely element system science and intelligent integration science; the brand new technology base is a brand new system technology (cluster) taking a value chain system as a core and oriented to holographic cooperativity; the brand new engineering foundation is brand new system engineering (cluster) taking a value chain system as a core and oriented to holographic cooperativity.

Disclosure of Invention

The MA/GVC is a brand-new holographic cooperative system which can be regarded as longitudinal and transverse association around a global value chain and is formed by comprehensively expanding and improving the industrial value chain market allocation technology MA/IVC. A MA/GVC system must be embodied in a manner that satisfies technical needs, such as a Graphical User Interface (GUI) associated internally and externally to a global value chain market configuration, a relational database associated internally and externally to a global value chain market configuration, an integration of suppliers associated internally and externally to a global value chain market configuration, various reports made as needed, and the like.

(1) For a Global Value Chain, the inventor establishes a new logic foundation, a new mathematical foundation, a new scientific foundation, a new technical foundation and a new engineering foundation independently, in order to transform an indefinite 'cloud' computing system into a 'heaven-earth' computing system which can link everything and run through longitude and latitude, insists on taking a Global Value Chain system as a core, and establishes a configuration unit design concept, a frame and a model facing Global Value Chain market Operation (Global Value Chain) by taking the connection and coordination of a GVC cognitive system (RS and a computer-aided system thereof) and a GVC practice system (PS and a computer-aided system thereof) as a principal line of an evolution process of a high-level intelligent integration system (HIIS).

The goal of global value chain configuration is to make the global value chain operate more efficiently, more mobile, and more in harmony. Four currently available decision tools for measuring the operational efficiency of the global value chain market configuration internal and external associations are: and (3) configuring internal and external associated basic information of the global value chain market, such as internal and external associated fund information of the global value chain market: cash flow and financial rate, etc.; configuration information associated inside and outside the global value chain market configuration, such as cost information associated inside and outside the global value chain market configuration: resource utilization and overall profit, etc.; capability information associated internally and externally to the global value chain market configuration, such as expertise and vulnerability of the global value chain organization associated internally and externally to the competitor; the global value chain market configures internal and external associated resource information, including internal and external associated resources and manpower, etc., as shown in fig. 1.

Before the introduction of MA/GVC, the communication of information within the global value chain was largely via paper. Although such network systems already exist in the global value chain, people are accustomed to communicating information through tangible files. This is because the systems in the global value chain are each administrative and separate from each other. The MA/GVC is generated just for changing the situation, organically integrates various functional modules related to the inside and the outside of the global value chain organization, and works together with the MA/GVC and the NA/GVC.

(1.1) a multi-level, multi-functional and multi-domain product chain system with global value chain organization node set as the center is shown in figure 2. For global value chains, any generalized meta-system commodity can be regarded as a hierarchical system which is formed by a plurality of resource nodes and various configuration nodes by taking an organization node set as a center. In a generalized meta-system commodity formed for a global value chain, a variety of resources having different quantities and different measurement units can be summarized aslA resource node, andlone resource node can be summarized asmThe number of the configuration nodes is equal to the number of the configuration nodes,meach configuration node can be summarized asnTissue nodes.

The inventors have divided the various commodities into two broad categories: narrow commodities (basic commodity BG, narrow products and services for exchange) and broad commodities (GG, broad products and services for exchange).

The BG (product and service) is a basic product in the general sense. This is the subject of classical and modern economics. According to the resource allocation dynamics analysis established by the present inventors, basic commodities are products or services for exchange formed centering on resource nodes.

The generalized commodity GG (generalized product and service) is the commodity which the inventor first proposed and includes various complex forms, and belongs to a research object of new economics. Generalized goods (generalized products and services) include: basic commodities (BG, basic product and service thereof), composite commodities (CG, composite product and service thereof), system commodities (SG, system product and service thereof), and meta system commodities (MG, meta system product and service thereof).

GG = BG + CG + SSG + CSG + GSG + MG + GMG

Wherein, GSG is general system commodity, GMG is general meta system commodity.

Viewed collectively, a base good refers to (1) a simple item characterized entirely by a single resource element, temporal, and spatial, that is not further decomposable, centered around a resource node, or (2) a simple service characterized entirely by a single function, temporal, and spatial, that is not further decomposable. Suppose that onlylIdentifying basic commodities; index of each basic commodityhIs from 1 tolA number of (2). It is also assumed that the number of these basic commodities can be any real number.

Narrow sense commodity-basic commodity (with resource node as center)

Basic commodity (with resource node as center)

Commodity composite commodity (with resource node integration as the center)

Simple system class commodity

Generalized commodity system type commodity (with configuration node as center) complex systematized commodity

Complex and large systematized commodity

(with configuration node set as the center)

Meta-system type commodity (with organization node as center) basic meta-system type commodity

Generalized meta-system commodities

(with tissue node set as the center)

Thus, it is possible to call spaceR ^w Is a basic commodity space. For any economic agent, a basic economic activity is an indication of the amount of each basic good that the economic agent will provide or that the economic agent can obtain. Thus, a basic economic activity is composed ofR ^w A point inaAnd (4) representing.

Each basic commodityrWith a certain real number (i.e. its price)p _r And (6) contacting. This price can be interpreted as the current economic activity artificially getting (or offering) every unitrBasic commodityThe amount paid out (or drawn). The general meaning of price includes many different terms of common usage such as normal price, wage, rent, ticket price, cost, shipping cost, patent tax, and the like.

The price system iswTuplep = ( p ₁ , p ₂ , ···, p _r , ···, p _w ) (ii) a Obviously, it can be usedR ^w Is shown as a dot. And pricing systempBasic actions of interestaIs of value to

I.e. bypAndainner product of (2)p · a。

Imagine a basic commodity as currency in placesTime of daytCirculate, is provided withrIs an index of the basic commodity. To obtain the firstrBasic commodities are planted ins、tPrice ofp _{r s t ; ,} Should usep _r Is divided byp _v . For all pricespAll this is done, can be obtained ins、tPricing system ofp _{s t,} = p ( 1 / p _v )。

Is provided witht ₁、t ₂ Is a date of the day,t ₁ < t ₂ . Byp _{s t, 1} = p _{s t, 2} α _{s t t; 1, 2} Number of definitionα _{s t t; 1, 2} Can be referred to assFromt ₁Tot ₂ The cumulative coefficient of (2). When in uset ₁ = t Andt ₂ = t+ 1, can be defined at the locations Fromt TotA percentage of interest of + 1i _{s t t; , + 1} = a _{s t t; , + 1}-1. It is thats、tGiven unit value ands、t+ 1 difference in value. Froma _{s t t; , + 1} = 1 + i _{s t t; , + 1}The following can be obtained:

this is the product.

The modern economic complex large-system commodity can be regarded as a member commodityW ₁₄Tool commodityW ₁₃Means commodityW ₁₂Instrument and commodityW ₁₁And the equipment commodityW ₁₀Facility commodityW ₉Program productW ₈Rule (including system) commodityW ₇Trick commodityW ₆Planning (including design) of goodsW ₅Method, article of manufactureW ₄Strategy commodityW ₃Technical commodityW ₂Strategic commodityW ₁ A complex dynamic system of various commodities at different levels, i.e.

W _S = < W, ψ> ( W = { W ₁ , W ₂ , ···, W ₁₄ })。

Here, the complex large system commodity can be put into practiceWIs divided into 14 layers (i = 1, 2, ···, 14)：

< W, ψ>Multi-layer multi-factor complex large system commodity

WThe element set of the complex large-system commodity,namely, it is

{ w ₁₁ , w ₁₂ , ···, w _{k 1 1} , w ₂₁ , w ₂₂ , ···, w _{k 2 2} , ··· , w _{14 1} , w _{14 2} , ···, w _{k 14 14} }

ψThe structural function of the complex large-system commodity,ψ = ψ( X )

X state vectors of elements of complex large-system commodities, i.e.

( x ₁₁ , x ₁₂ , ···, x _{k 1 1} , x ₂₁ , x ₂₂ , ···, x _{k 2 2} , ··· , x _{14 1} , x _{14 2} , ···, x _{k 14 14} )

< W _{i j} , s _{i j} >Complex large system goods< W, ψ>To (1) aiA hierarchy of subsystems, including a hierarchy of subsystems,i = 1, 2, ···, 14；j = 0, 1, 2, ···, k _i

D (h _i , s _i ) Complex large system goods< W, ψ>To (1) aiHierarchical decomposition

s _i First, theiThe state vector of the hierarchical subsystem, i.e. ()s _i1 , s _i2 , ···, s _{ik i} )

h _i First, theiHierarchical subsystem< s _i , h _i >As a function of the structure of (a),s _i = { s _i1 , s _i2 , ···, s _{ik i} }， h _i = h _i ( g _i )

U _{i j} { e _i | ψ( e _i ) ≥ j _i }

min U _{i j} (φ) ψ ( X ) The set of minimum vectors of (a) is,j = 0, 1, 2, ···, k _i

Pstate probability vectors for complex large system class commodities, i.e. () (P( 0 ), P( 1 ), P( 2 ), ···, P( k _i ) )

A is obtained by taking the sum of

V-shaped extraction, meaning taking a big operation in a lattice operation

MCTS multilayer multi-state related complex large system commodity

Discrete function of monotone increasing MIF

Further, the following comments may be given:

level 14: component merchandise collectionW ₁₄ = { w _{14, 1} , w _{14, 2} , ···, w _{k 14, 14} }

Level 13: tool commodity setW ₁₃ = { w _{13, 1} , w _{13, 2} , ···, w _{k 13, 1} }

Level 12: means commodity setW ₁₂ = { w _{12, 1} , w _{12, 2} , ···, w _{k 12, 1} }

Level 11: instrument commodity collectionW ₁₁ = { w _{11, 1} , w _{11, 2} , ···, w _{k 11, 1} }

Level 10: equipment commodity setW ₁₀ = { w _{10, 1} , w _{10, 2} , ···, w _{k 10, 1} }

Level 9: set of utility goodsW ₉ = { w _{9, 1} , w _{9, 2} , ···, w _{k 9, 1} }

Level 8: program commodity collectionW ₈ = { w _{8, 1} , w _{8, 2} , ···, w _{k 8, 1} }

Level 7: regular collection of goodsW ₇ = { w _{7, 1} , w _{7, 2} , ···, w _{k 7, 1} }

Level 6: set of skills merchandiseW ₆ = { w _{6, 1} , w _{6, 2} , ···, w _{k 6, 1} }

Level 5: planned collection of itemsW ₅ = { w _{5, 1} , w _{5, 2} , ···, w _{k 5, 1} }

Level 4: method and article setW ₄ = { w _{4, 1} , w _{4, 2} , ···, w _{k 4, 1} }

Level 3: policy commodity collectionW ₃ = { w _{3, 1} , w _{3, 2} , ···, w _{k 3, 1} }

Level 2: tactical merchandise collectionW ₂ = { w _{2, 1} , w _{2, 2} , ···, w _{k 2, 1} }

Level 1: strategic merchandise collectionW ₁ = { w _{1, 1} , w _{1, 2} , ···, w _{k 1, 1} }

In a multi-level organization of a complex large system, a set of basic organization units is often composed of many configuration units.

The time region for generating the multi-level organization of the complex large system can be divided into a series of tight basic intervals with equal length, and the basic intervals can be arranged in time sequence.

Similarly, a spatial region that produces a multi-level organization of a complex large system may be divided into a series of closely spaced elementary sections of equal length, which may be arranged in spatial tandem. A base interval is said to be a location, and thus, "at a locationSIs "equivalent to" in the secondSA certain point of the basic section ".

The generalized meta-system commodity is often a commodity having a generalized body cooperative structure and function formed by an organization node set as a center through an internal and external multiple product value chain, an internal and external multiple global value chain, and an internal and external multiple industrial value chain.

With the organization node set as the center, the generalized meta-system class commodity (or tuple organization commodity) comprises:

internal and external basic cooperative organization commodity G [ EMH/IMH ]; the internal and external centralized cooperation organization commodity G [ ECC/ICC ];

internal and external scatter-and-collaboration organization commodity G [ EDC/IDC ]; internal and external centralized competition organization commodity G [ ECK/ICK ];

internal and external distributed competitive organization product G [ EDK/IDK ].

A multi-level, multi-functional and multi-domain product chain system with organization node set as the center is shown in fig. 2. Any generalized meta-system commodity can be regarded as a hierarchical system which is formed by a plurality of resource nodes and various configuration nodes by taking an organization node set as a center. In a generalized meta-system commodity, a variety of resources with different quantities and different measurement units can be summarized aslA resource node, andlone resource node can be summarized asmThe number of the configuration nodes is equal to the number of the configuration nodes,meach configuration node can be summarized asnTissue nodes.

(1.2) for a global value chain, a product value chain reproduction system of complex large-system commodities, a global value chain reproduction system, an industrial value chain reproduction system, a national economic value chain reproduction system and a global economic value chain reproduction system.

For the global value chain, the generalized commodity system and the multi-level value chain system are shown in fig. 3.

According to the analysis established by the inventor, the value of the commodity is to meet the social necessary efficacy of the general supply and demand relationship of the society. There is a base of value at different levels as follows.

The value of the simple commodity lies in that the simple production meets the social essential effect of the general supply and demand relationship of the society:

V _simpl ：

, s. t.

；

the value of the composite commodity lies in that the composite production meets the social essential effect of the common supply and demand relationship of the society:

V _compl ：

, s. t.

the value of the simple system commodity is that the simple production system meets the social essential effect of the general supply and demand relationship of the society:

V _syst ：

, s. t.

the value of the complex system commodity is that the complex production system meets the social essential effect of the general supply and demand relationship of the society:

V _com-syst ：

, s. t.

the theoretical hypothesis and the logical structure of the hedge balance economic value analysis established by the inventor are centered on a value measurement system established in a basic commodity space, a composite commodity space, a system commodity space and a meta-system commodity, and the generalized value measurement system is based on the social essential efficacy (a function closely related to the balance price and the balance quantity) of the generalized commodity.

(1.3) the global value chain resource allocation network can be seen as a set consisting of a certain number (or variable number) of nodes and a certain number (or variable number) of chains.

We can divide the various networks of the global value chain into four levels as follows:

global value chain resource network (URN): resource node (rn) -resource chain (rc) -resource set (rs)

Global value chain configuration network (UDN): configuration node (dn) -configuration chain (dc) -configuration set (ds)

Global value chain organization network (UON): tissue node (on) -tissue chain (oc) -tissue set (os)

Global value chain group network (UGN): group node (gn) -group chain (gc) -group set (gs)

Because the value chain system can be divided into five levels, namely a product value chain system, an enterprise value chain system, an industrial value chain system, a national economic value chain system and a global economic value chain system, various generalized commodities in the market configuration system can be correspondingly divided into five levels, namely:

a base commodity (narrow commodity) BG (MA/PVC) in the PVC reproduction market disposition system, a base commodity (narrow commodity) BG (MA/GVC) in the GVC reproduction market disposition system, a base commodity (narrow commodity) BG (MA/IVC) in the IVC reproduction market disposition system, a base commodity (narrow commodity) BG (MA/NVC) in the NVC reproduction market disposition system, and a base commodity (narrow commodity) BG (MA/GVC) in the GVC reproduction market disposition system;

composite commodity CG (MA/PVC) in a PVC reproduction market configuration system, composite commodity CG (MA/GVC) in a GVC reproduction market configuration system, composite commodity CG (MA/IVC) in an IVC reproduction market configuration system, composite commodity CG (MA/NVC) in an NVC reproduction market configuration system and composite commodity CG (MA/GVC) in a GVC reproduction market configuration system;

simple system commodity SSG (MA/PVC) in a PVC reproduction market configuration system, simple system commodity SSG (MA/GVC) in a GVC reproduction market configuration system, simple system commodity SSG (MA/IVC) in an IVC reproduction market configuration system, simple system commodity SSG (MA/NVC) in an NVC reproduction market configuration system, and simple system commodity SSG (MA/GVC) in a GVC reproduction market configuration system;

a complex system commodity CSG (MA/PVC) in a PVC reproduction market configuration system, a complex system commodity CSG (MA/GVC) in a GVC reproduction market configuration system, a complex system commodity CSG (MA/IVC) in an IVC reproduction market configuration system, a complex system commodity CSG (MA/NVC) in an NVC reproduction market configuration system and a complex system commodity CSG (MA/GVC) in a GVC reproduction market configuration system;

GSG (MA/PVC) of complex large system type in a PVC reproduction market configuration system, GSG (MA/GVC) of complex large system type in a GVC reproduction market configuration system, GSG (MA/IVC) of complex large system type in an IVC reproduction market configuration system, GSG (MA/NVC) of complex large system type in an NVC reproduction market configuration system and GSG (MA/GVC) of complex large system type in a GVC reproduction market configuration system.

The generalized commodity hierarchy and the multi-level value chain hierarchy are shown in fig. 3.

Is provided withXIn order to be a set of nodes, the node sets,Rin order to be a set of chain relations,nfor hierarchy, the value chain system VCS can be represented as follows:

wherein,

VCS _{i ( 3 )} for a product value chain system:

product value chainVCS _{i ( 3 )}: resource nodes (elements) -configuration nodes (personnel) -organization nodes (groups);

VCS _{i ( 4 )} for a product value chain system:

project value chainVCS _{i ( 4 )}: configuring nodes (personnel) -configuring nodes (groups) -organizing nodes (units);

VCS _{i ( 5 )} for a product value chain system:

global valueChainVCS _{i ( 5 )}: configuring nodes (small groups), configuring nodes (units), and organizing nodes (enterprises);

VCS _{i ( 6 )} for a product value chain system:

industry value chainVCS _{i ( 6 )}: configuring nodes (units), configuring nodes (enterprises), and organizing nodes (industries);

VCS _{i ( 7 )} for a product value chain system:

department value chainVCS _{i ( 7 )}: configuring nodes (enterprises), configuring nodes (industries), and organizing nodes (departments);

VCS _{i ( 8 )} for a product value chain system:

regional value chainVCS _{i ( 8 )}: configuring nodes (industry) -configuring nodes (department) -organizing nodes (region);

VCS _{i ( 9 )} for a product value chain system:

national value chainVCS _{i ( 9 )}: configuration nodes (departments) -configuration nodes (regions) -organization nodes (countries);

VCS _{i ( 10 )} for a product value chain system:

global value chainVCS _{i ( 10 )}: configuration nodes (regions) -configuration nodes (countries) -organizational nodes (global).

(1.4) the global value chain market configuration system can be regarded as a process that a global value chain market configuration main body acts on an intelligent integrated object in a certain intelligent integration mode in a certain environment according to a certain intelligent integration target.

According to the analysis of the inventor, the mass-energy configuration of the advanced intelligent life system is composed of a main configuration center (the analysis of which is oriented to an organization node), a configuration target (a multi-level target system), a configuration mode (the analysis of which is oriented to a configuration node), a configuration load (the analysis of which is oriented to a resource node), configuration environment factors and the like. Here, the mass-energy configuration center of the advanced intelligent life system has evolved into an advanced configuration subject with a complex target system, and has a complex dynamic basis (besides the bio-energy composition, also related to property relationships, interest distribution structures, etc.), an advanced intelligent organization (and a socialized complex organization form), and a complex decision structure; the mass-energy configuration mode of the advanced intelligent life system relates to the aspects of configuration approaches, tools, means, equipment, technical systems, methods, programs, strategies and the like; the resource allocation load of the advanced intelligent life system comprises a natural resource allocation load, a social resource allocation load and a life resource allocation load, or comprises a material resource allocation load, an information resource allocation load, a value resource allocation load, a human resource allocation load and the like. Advanced intelligent life is a complex configuration subject capable of engaging in practical activities and cognitive activities and combining the two activities for intelligent integration, and advanced intelligent life information has richer contents and more advanced forms than general life information. In various advanced intelligent environments, the advanced intelligent life system not only has stronger adaptability, but also has stronger development capability and certain overriding property.

According to the new design, the global value chain market allocation subject is actually related to (or appears as) the global value chain cognitive system subject on the one hand and related to (or appears as) the global value chain practice system subject on the other hand; global value chain market allocation objectives can be viewed as a result of integrating cognitive objectives and practice objectives; the global value chain market configuration can be regarded as the integration of a cognitive configuration mode and a practical configuration mode.

The inventor claims that the established global value chain market configuration integrated dynamic convergence network comprises system hardware, system software, system configuration, system organization, system operation and system management and system service, and the target mode of the network is that the network is to be integrated with the global value chain market configuration integrated dynamic convergence network

The nodes can be increased and decreased, and the scale can be expanded; the structure can be evolved, and the function can be updated;

the target is adjustable, and the mode is convertible; organization can be improved and management can be improved.

Global value chain market allocation integration is a multi-level, multi-domain process, and relates to organization integration, department integration, regional integration, national integration, and global integration. Correspondingly, the global value chain market allocation integrated self-organizing management center is a multi-level and multi-field resource allocation center and comprises an organization data center, a department data center, a regional data center, a national data center, an international data center and a global data center.

(1.5) now, we can consider the development of transaction concepts and models in the interrelationships between the various subsystems of the global value chain system (or between organizations and individuals) to form what can be referred to as "GVC generalized transactions".

A "GVC universal transaction" should consist of three basic elements:

A1. the GVC component systems (or organizations and individuals) traders: the trading behavior of each GVC subsystem body or organization and individual in the global value chain system determines the basic behavior of the GVC subsystem and can be regarded as the basic trading behavior of the GVC subsystem. The number of GVC subsystem (or organization and individual) is the number of GVC subsystem traders. The GVC subsystem trading agent can be a natural person or various social organizations such as enterprises, governments, communities and the like.

In the following discussion, the GVC subsystem transaction agent is noted as a GVC subsystem transaction agentiTrader, traderiDetermine the GVC subsystemS _i The behavior of (c).

GVC component system trader collectionζ = { 1, 2, ···, I I.e. totalIA GVC subsystem transactor, if the number of GVC subsystems (or organizations and individuals) involved in the transaction is unlimited, thenζIs the entire positive integer set. For ease of discussion, we can divide a GVC into system tradersiThe traders other than this are called "iThe other party's' is marked as-i 。

A2. Generalized commodity composition (generated foods composition): as objects of basic transaction activities, systems and processes, generalized commodities can be classified into basic commodities, composite commodities, simple system commodities, complex system commodities and complex large system commodities. Generally, the complex and large system commodities can be regarded as member commoditiesW ₁₄Tool commodityW ₁₃Means commodityW ₁₂Instrument and commodityW ₁₁And the equipment commodityW ₁₀Facility commodityW ₉Program productW ₈Rule (including system) commodityW ₇Trick commodityW ₆Planning (including design) of goodsW ₅Method, article of manufactureW ₄Strategy commodityW ₃Technical commodityW ₂Strategic commodityW ₁ A complex dynamic system of factors at different levels, i.e.W _S = < W, Ψ> ( W = { W ₁ , W ₂ , ···, W ₁₄ }). The complexity of a complex large system class commodity can be measured by structural entropy. For a particular generalized commodity transaction activity, there is always a particular generalized commodity combination. For a particular combination of goods in a broad sense,a mean-variance analysis may be performed to determine the optimal generalized commodity combination.

System (or organization and individual) traders to divide GVC into systemsiThe generalized commodity basis available isW _i ∈ Θ _i ，Θ _i For GVC-subsystem (or organization and individual) tradersiThe set of selectable generalized commodity components is also called generalized commodity space.IThe GVC subsystem traders each select a vector composed of generalized commoditiesW = ( W ₁ , W ₂ , ···, W _I ) May be called generalized goods combinations (generalized goods profiles), the set of generalized goods combinations being

。

The GVC generalized transaction based on generalized commodity composition is a comprehensive transaction.

Further, the member commodity in the broad sense commodity constitutionW ₁₄Tool commodityW ₁₃Means commodityW ₁₂Instrument and commodityW ₁₁And the equipment commodityW ₁₀Facility commodityW ₉Program productW ₈Rule (including system) commodityW ₇Trick commodityW ₆Planning (including design) of goodsW ₅Method, article of manufactureW ₄Strategy commodityW ₃Technical commodityW ₂Strategic commodityW ₁ By waiting for various factors at different levels, the universal game can be divided into component commoditiesW ₁₄Transaction, for tool goodsW ₁₃Transaction of (2) and means commodityW ₁₂Transaction, for instrument goodsW ₁₁Transaction, for equipment merchandiseW ₁₀Transaction of, for, facility goodsW ₉Transaction of, for program commodityW ₈Transaction and target ruleThen (including system) goodsW ₇Trade, target skill commodityW ₆For planned (including design) goodsW ₅Trade, method and commodityW ₄Trade, target to strategy goodsW ₃For tactical goodsW ₂Trading, targeting strategic commoditiesW ₁The transaction of (2), etc.

The concept of "generalized mixed goods composition" can be extended from the concept of generalized goods composition. GVC subsystem (or organization and individual) tradersiGeneralized mixed commodity composition ofΩ _i Is his generalized commodity spaceΘ _i The probability distribution in (1) represents that a GVC subsystem trader randomly selects and executes in the generalized commodity composition based on the probability distribution when actually trading.Ω _i ( W _i ) To representΩ _i Distribution to generalized Commodity constructsW _i Probability of, GVC subsystem traderiCan be recorded asΣ _i Generalized mixed commodity composition space can be written asΣ= ×Σ _i . The generalized commodity configuration is a special case of the generalized mixed commodity configuration.

For ease of analysis, the GVC is classified as a system (or organization and individual) traderiBy other traders than the othersiThe generalized commodity composition adopted by the other party is recorded asW _{i –}∈ Θ _{i –}And general commodity combinationsW = ( W ₁ , W ₂ , ···, W _{i– 1} , W' _i , W _{i + 1} , ···, W _I ) Is marked by (W' _i , W _{i –}) Similar notations may be given for generalized mixed commodity constituents.

A3. Generalized commercial power effect: refers to the enhanced configuration and increased configuration load, system benefits and paid system costs for each GVC subsystem (or organization and individual) trader from trading based on various generalized commodity combinations.

GVC generalized trading process as a basic behavioral process of the global value chain systemW _S Comprising five basic elements or subsystems, GVC subsystem (or organization and individual) tradersW _M The other partyW _O Generalized Commodity constitutionW _G And a transaction basisW _B And environmentW _E Namely:W _S = < W _M , W _O , W _G , W _B , W _E , ψ _W >whereinW = { W _M , W _O , W _G , W _B , W _E }; each of these five basic elements or subsystems is often itself a complex system. GVC subsystem traders as an intelligent ad hoc control systemW _M Can be recorded as

W _M = < w _M , ψ _M >，

Whereinw _M Is a basic organization unit setw _M = { w _{M 1} , w _{M 2} , ···, w _{M n} }，ψ _M As a function of the structure of the self-organising control systemψ _M = ψ _M ( X )，XIs a basic organization sheet of the systemMeta-state vectorX = ( x ₁ , x ₂ , ···, x _n )，W _{M i ,} = < w _{M i ,} , s _{M i} > ( i = 1, 2, ···, n) Is a systemW _M = < w _M , ψ _M >A subsystem ofhIs a system< s _M , h >As a function of the structure of (a),s _M = { s _{M 1} , s _{M 2} , ···, s _{M w} }，h = h ( s _M ). MaterialW _{B M} Energy sourceW _{B E} And a communication facilityW _{B I} Forming the material basis of transaction systems, i.e.W _B = { W _{B M} , W _{B E} , W _{B I} }。

For one is composed oflA resource (integration) node,mIndividual (integrated) configuration nodes andnunder the condition of not relating to organization group, based on generalized secondary integration analysis coordinate, we can introduce dynamic combination factor according to the following relational expressionb _F To determine the arrangement force enhanced from the countermeasures based on various generalized commodity combinationsF _{D T ,} ：

( 1. 7. 1 )

In the formulaM _{D i,} To organize nodesiThe amount of the configuration of (a) is,p _i to organize nodesiThe price of the transaction of (a) is,Q _i to organize nodesiThe amount of resources of (a) is,r _i to organize nodesiThe integrated radial dimension of the light source is measured,i = 1, 2, ···, n 。

suppose that the complex large system goods can be dividedmA field of activity andnand (4) each department. First, theiA department (i = 1, 2, ···, n ) To (1) ajAn activity ofj = 1, 2, ···, m ) The enhanced benefit from the strategy based on various generalized commodity combinations isB _{i j} ( W ) Then the total benefit of the system is:

( 1. 7. 2 )

whereinp _{i j k} Is as followsiThe department isjIn the middle of the activitykSpecies resource (k = 1, 2, ···, l ) The transaction price of (2).

The GVC generalized trading is formed by three basic elements, namely a GVC subsystem trader, a generalized commodity composition and a generalized commodity dynamic effect.

(2) For a global value chain, the inventor establishes a brand-new logic foundation, a brand-new mathematical foundation, a brand-new scientific foundation, a brand-new technical foundation and a brand-new engineering foundation independently, in order to modify a neglected and uncertain 'cloud' computing system into a 'heaven-earth' computing system which can link everything and run through longitude and latitude, the inventor insists on taking a global value chain system as a core, and establishes a design foundation of service flow arrangement by taking the connection and coordination of a GVC cognitive system (RS and a computer-aided system thereof) and a GVC practice system (PS and a computer-aided system thereof) as a principal line of an evolution process of a high-level intelligent integration system (HIIS).

(2.1) we can give the concept of GVC generalized transactional dynamic equilibrium and effect equilibrium.

Definition 1A generalized CommodityW ^* The condition for satisfying the power balance (feasibility balance) is that for alli In all other areasW _i ∈

Θ _i In the following, the first and second parts of the material,

( 1. 7. 3 )

definition 2A generalized Mixed CommodityΩ ^* The condition for satisfying the power balance (feasibility balance) is that for alliIn all other areasW _i ∈ Θ _i In the following, the first and second parts of the material,

( 1. 7. 4 )

definition 3A generalized CommodityW ^* The condition for satisfying effect balance (necessity balance) is that alliIn all other areasW _i ∈Θ _i In the following, the first and second parts of the material,

( 1. 7. 5 )

definition 4A generalized Mixed CommodityΩ ^* The condition for satisfying effect balance (necessity balance) is that alliIn all other areasW _i ∈ Θ _i In the following, the first and second parts of the material,

( 1. 7. 6 )

theorem 7.1 there is at least one equilibrium of dynamics satisfied by generalized mixed commodity constituents for any transaction with limited generalized commodity constituents.

This can be seen as the basic presence theorem for GVC generalized transactions. The Kakutani fixed point theorem is used in the following demonstration.

Proof of concept of first-introduced response, GVC subsystem traderiTo counterr _i Combining each generalized commodityΩMapping adopted for its adversaryΩ _{i –}Set of generalized mixed commodities whose disposition force is maximized, althoughr _i Rely on onlyΩ _{i –}However, in order to apply the law of fixed points, it is expressed as a function composed of the generalized commodities of all GVC subsystem tradersr _i ( Ω). Definition of the corresponding pairsr : Σ→ ΣIs composed ofr _i The cartesian product of (a).r Has a fixed point of satisfyingΩ∈r ( Ω) Is/are as followsΩFor each GVC subsystem transactor,Ω _{i –}∈r ( Ω _{i –}). Thereby to obtainrThe stationary point of (1) is the power balance.

According to the Kakutani theorem of stationary points, the following isr : Σ→ ΣSufficient conditions with fixed points (not necessary conditions): (1)Σa non-empty, tight subset of euclidean space; (2) for any purposeΩ，r ( Ω) Is not empty; (3) for any purposeΩ，r ( Ω) Is convex; (4)r ( Ω) The method comprises the following steps: if it is paired with

Is provided withThen, then

. This property may be referred to as semi-continuity.

Now only the certification is neededr ( Ω) The above conditions are satisfied.

For condition (1), because eachΣ _i Are probability spaces of being (a)N _{Θ i ,} -1) a pure form of (A)N _{Θ i,} Is composed ofΘ _i Number of elements) of the group. This means thatΣIs a non-empty, convex, bounded set, and thus also a tight set.

For condition (2), since the desired configuration action is a linear function of probability and thus continuous, while the continuous function over the tight set must reach a maximum, there isr _i ( Ω) Thereby to maker ( Ω) Is not empty.

For condition (3), the desired linearity of the configuration function means, for anyΩ'∈ r( Ω)，Ω''∈ r( Ω) Is provided withλΩ'+ ( 1– λ) Ω''∈ r( Ω). For any purposeλE (0, 1), i.e. ifΩ' andΩ'' is a pairΩ _{i –}Then their weighted average is also onΩ _{i –}The optimum reaction. This proves thatr( Ω) The convexity of (c).

Finally, the condition (4) is proved to be satisfied by a counter-proof method. Suppose thatr( Ω) Not the first half of a sequence, then there is a sequence that satisfies

And is and

however, but

. This means that for some GVC subsystem tradersiIs provided withThus exist ofε>0 andΩ' _i so that

。

Due to the fact thatF _{D i ,} Is continuous with

So that whennWhen large enough, it has

Thus, as a pair

The reaction of (a) with (b),is strictly superior to

This is assumed

Are in contradiction. Thus, satisfaction of the condition (4) is confirmed.

The above theorem illustrates the existence of a dynamic equilibrium in a limited transaction.

Theorem 7.2 there is at least one equilibrium of the effects satisfied by the generalized mixed commodity configuration for any countermeasure against the limited generalized commodity configuration.

This can be seen as another basic presence theorem for GVC generalized transactions.

The proof is similar to the above proof and is omitted.

For unlimited transactions where the GVC subsystem trader has an unlimited number of generalized commodities, the existence of dynamic equilibrium is guaranteed by the following theorem.

Theorem 7.3 innIn the general commodity configuration strategy of the GVC subsystem trader, if the general commodity space of each traderΘ _i Is a non-empty bounded closed convex set in Euclidean space, and is configured with an enhanced functionF _{D i ,} ( W ) In succession and in pairW _i Is pseudo-concave, there is a dynamic balance in the transaction that is satisfied by a generalized commodity.

The proof of this theorem is similar to that of theorem 7.1. This theory gives that there is a sufficient (not necessary) condition for the dynamic equilibrium of the generalized commodity, where dishing is a rather strict condition, and when this condition is not met, the introduction of the generalized mixed commodity configuration can guarantee the existence of equilibrium.

Theorem 7.4 innIn the general commodity configuration strategy of the GVC subsystem trader, if the general commodity space of each traderΘ _i Is a non-empty bounded closed convex set in Euclidean space, and is configured with an enhanced functionF _{D i ,} ( W ) Continuously, then there is a broad mixed commodity house in the transactionThe power balance is satisfied.

Theorem 7.5 innIn generalized commodity configuration type trading of GVC subsystem traders, if the generalized commodity space of each traderΘ _i Is a non-empty bounded closed convex set in Euclidean space, and is a benefit enhancement functionB _i ( W ) Continuous and pairs are pseudo-concave, then there is a balance of effects satisfied by a generalized commodity in this transaction.

The proof of this theorem is similar to that of theorem 7.1. This theory gives sufficient (not necessary) conditions for equilibrium of the generalized commodity effect, where dishing is a rather strict condition, and when this condition is not met, the introduction of the generalized mixed commodity composition can guarantee the existence of equilibrium.

Theorem 7.6 innIn the general commodity configuration strategy of the GVC subsystem trader, if the general commodity space of each traderΘ _i Is a non-empty bounded closed convex set in Euclidean space, and is a benefit enhancement functionB _i ( W ) And continuously, a generalized mixed commodity effect balance exists in the transaction.

(2.2) for the global value chain cooperative game organization mode of various types of products, the inventor introduces two closely related categories, namely a product efficacy structure P [ PES ] and a product value structure P [ PVS ]. Under the overall analysis framework provided by the inventor, the product efficacy structure and the product value structure jointly form a product technology economic structure P [ PES/PVS ] of a global value chain cooperative game organization.

Under the general analysis framework provided by the inventor, as a basic part of a product technology and economic structure of a global value chain cooperative game organization, a product efficacy structure system is composed of a product technology structure and a product knowledge structure.

As a basic component of the product efficacy architecture, the product technology architecture can be divided into

A technology intensive product P [ TT/TA ] dominated by the traditional technology, a technology trivial product P [ TT/TB ] dominated by the traditional technology, and a technology evacuation product P [ TT/TC ] dominated by the traditional technology;

a technology intensive product P GT/TA under the general technology dominance, a technology trivial product P GT/TB under the general technology dominance, and a technology evacuation product P GT/TC under the general technology dominance;

a technology intensive product P [ HT/TA ] under the high and new technology dominance, a technology trivial product P [ HT/TB ] under the high and new technology dominance, and a technology evacuation product P [ HT/TC ] under the high and new technology dominance.

General product technology architecture

TSSP = P [ TT / TA, TT / TB, TT / TC, GT / TA, GT / TB, GT / TC, HT / TA, HT / TB, HT / TC ]。

As a general component of the product efficacy architecture, the product knowledge structure can be divided into

A knowledge intensive product P [ SK/KA ] dominated by scientific knowledge, a knowledge trivial product P [ SK/KB ] dominated by scientific knowledge, and a knowledge-dispersed product P [ SK/KC ] dominated by scientific knowledge;

a knowledge intensive product P [ TK/KA ] under the leading of technical knowledge, a knowledge trivial product P [ TK/KB ] under the leading of technical knowledge, and a knowledge dispersed product P [ TK/KC ] under the leading of technical knowledge;

the knowledge intensive product P [ EK/KA ] under the control of engineering knowledge, the knowledge trivial product P [ EK/KB ] under the control of engineering knowledge, and the knowledge dispersed product P [ EK/KC ] under the control of engineering knowledge.

Total product knowledge architecture

KSSP = P [ SK / KA, SK / KB, SK / KC, TK / KA, TK / KB, TK / KC, EK / KA, EK / KB, EK / KC ]。

Total product efficacy architecture

PESS = P [ TT / TA, TT / TB, TT / TC, GT / TA, GT / TB, GT / TC, HT / TA, HT / TB, HT / TC,

[ SK / KA, SK / KB, SK / KC, TK / KA, TK / KB, TK / KC, EK / KA, EK / KB, EK / KC ]]。

When analyzing a global value chain cooperative game organization mode of various types of products, a product efficacy structure type product and a product value structure type product are considered firstly:

on one hand, the inventor analyzes a product rationalization selection mechanism of national technology constitution type meeting the coordination configuration priority principle, and on the other hand, the inventor analyzes an effective selection mechanism of a national technology leading mode plan meeting the efficiency priority principle;

on one hand, the inventor analyzes the social knowledge formation type product rationalization selection mechanism meeting the coordination configuration priority principle, and on the other hand, the inventor analyzes the knowledge leading mode academic coordination selection mechanism meeting the coordination priority principle.

Under the total analysis framework provided by the inventor, as a basic component of a social product technology and economy structure of a global value chain cooperative game organization, a product economy infrastructure system is composed of two parts, namely a property attribution structure and an operation attribution structure.

In terms of product economics infrastructure (ESP type), we can classify the property attribution product types as capital all products P [ NO ], private capital all products P [ PO ], legal capital all products P [ LO ]; the operation is attributed to the product type: public organization market configuration product P [ PM ], private organization market configuration product P [ IM ], and private organization market configuration product P [ AM ].

As a central component of the economic infrastructure system of social products, the economic infrastructure of internal products can be divided into

Configuring a product P [ INO/IPM ] in a public and private organization market under the leading of all internal initiative capital (INO, national institutes of health);

configuring a product P [ INO/IAM ] in a civil organization market under the leading of all internal initiative capital (INO, national institutes) system;

private organisation market configuration product P [ INO/IIM ] under the initiative of all internal initiative capital (INO, national institutes of health);

configuring product P [ IPO/IPM ] in public and private organization market under the dominance of internal private capital ownership (IPO, private system);

configuring product P [ IPO/IAM ] in civil and private organization market under the dominance of internal private capital ownership (IPO, private system);

private organisation market configuration product P [ IPO/IIM ] under the initiative of internal private capital ownership (IPO, private);

the public organization market configuration product P [ ILO/IPM ] under the initiative of the capital ownership System (ILO, community ownership System);

a product P [ ILO/IAM ] is configured in a civil and private organization market under the initiative of the capital ownership system (ILO, community ownership system);

private organization market configuration product P [ ILO/IIM ] dominated by the capital ownership System (ILO, Community ownership System).

Total in-house product economy infrastructure system

IESP = P [ INO / IPM, INO / IAM, INO / IIM,

IPO / IPM, IPO / IAM, IPO / IIM, ILO / IPM, ILO / IAM, ILO / IIM ]。

As a system component of the social product economic infrastructure system, the external product economic infrastructure can be divided into

The product P [ ENO/EPM ] is configured in the market of the public organization under the leading of all external initiative capital (INO, national institutes of health);

configuring a product P [ ENO/EAM ] in a civil and private organization market under the leading of all external capital authorities (ENO, national institutes of government);

private organisation market configuration product P [ ENO/EIM ] under the initiative of external initiative capital ownership (ENO, national institutes of health);

public venture market configuration product P [ EPO/EPM ] dominated by external private capital ownership (EPO, proprietary);

product P [ EPO/EAM ] is configured in the market of civil and private organizations dominated by the external private capital ownership (EPO, proprietary);

private organisational market configuration product P [ EPO/EIM ] dominated by external private capital ownership (EPO, proprietary);

a public organization market configuration product P [ ELO/EPM ] dominated by the capital ownership System (ELO, community ownership System);

a product P [ ELO/EAM ] is configured in a civil organization market dominated by the capital ownership system (ELO, community ownership system);

the private organisation market disposition product P [ ELO/EIM ] is dominated by the external legal capital ownership system (ELO, community ownership system).

Total outsource product economic infrastructure system

EESP = P [ ENO / EPM, ENO / EAM, ENO / EIM,

EPO / EPM, EPO / EAM, EPO / EEM, ELO / EPM, ELO / EAM, ELO / EIM ]。

Total product economics infrastructure system

ESPS = P [ INO / IPM, INO / IAM, INO / IIM, IPO / IPM, IPO / IAM, IPO / IIM,

ILO / IPM, ILO / IAM, ILO / IIM, [ ENO / EPM, ENO / EAM, ENO / EIM,

EPO / EPM, EPO / EAM, EPO / EEM, ELO / EPM, ELO / EAM, ELO / EIM ]]。

When analyzing various types of global value chain cooperative game organization market configuration product modes, in addition to considering a technical knowledge structure, the property attribution product types and the operation attribution product types are also considered.

According to the analysis established by the inventor, the value of the commodity is to meet the social necessary efficacy of the general supply and demand relationship of the society. There is a base of value at different levels as follows.

The value of the simple commodity lies in that the simple production meets the social essential effect of the general supply and demand relationship of the society:

V _simpl ：

, s. t.

；

the value of the composite commodity lies in that the composite production meets the social essential effect of the common supply and demand relationship of the society:

V _compl ：

, s. t.

the value of the simple system commodity is that the simple production system meets the social essential effect of the general supply and demand relationship of the society:

V _syst ：

, s. t.

the value of the complex system commodity is that the complex production system meets the social essential effect of the general supply and demand relationship of the society:

V _com-syst ：

, s. t.

the theoretical hypothesis and the logical structure of the hedge balance economic value analysis established by the inventor are centered on a value measurement system established in a basic commodity space, a composite commodity space, a system commodity space and a meta-system commodity, and the generalized value measurement system is based on the social essential efficacy (a function closely related to the balance price and the balance quantity) of the generalized commodity.

(3) For a global value chain, the inventor introduces appropriate basic cooperative variables for respectively reflecting basic power, basic load, basic efficacy, basic consumption, internal cooperation and competition of a general complex adaptive system and external cooperation and competition to establish an engineering concept and a technical scheme of configuration unit design in order to modify a neglected and uncertain 'cloud' computing system into a 'heaven-earth' computing system which is communicated with all things and passes through longitude and latitude on the basis of independently establishing a brand-new logic foundation, a brand-new mathematical foundation, a brand-new scientific foundation and a brand-new technical foundation and an engineering foundation, insisting on taking a global value chain system as a core and taking the connection and coordination of a GVC cognitive system and a GVC practice system as a key process of an intelligent integrated system.

(3.1) expanding the commodities and their combinations into the broad commodities and their compositions (i.e. the commodities consisting of members)W ₁₄Tool commodityW ₁₃Means commodityW ₁₂Instrument and commodityW ₁₁And the equipment commodityW ₁₀Facility commodityW ₉Program productW ₈Rule (including system) commodityW ₇Trick commodityW ₆Planning (including design) of goodsW ₅Method, article of manufactureW ₄Strategy commodityW ₃Technical commodityW ₂Strategic commodityW ₁ A complex dynamic system formed by various factors at different levels) necessarily brings a series of complexities to the value theory.

On the basis of the concept and model of 'GVC general transaction' given in the previous section by the interrelation among the GVC subsystems (or among organizations and among individuals) of the global value chain system, the value entity problem of the generalized commodity can be considered to be discussed from the system efficacy of the generalized commodity.

The basic logic of the inventor's thought about the problem of the generalized commodity value can be described as the following structure: the price of the generalized commodity is based on the value of the generalized commodity; the value entity of the generalized commodity lies in the system efficacy of the generalized commodity; the systematic efficacy of the generalized commodity lies in the objectives of the trader and the objectives of the trading system; the goal of the trader and trading system is to achieve "GVC generalized trading dynamics balance" and "GVC generalized trading effects balance"; the system effect that the generalized commodity meets the 'GVC generalized transaction effect balance' is the social essential effect of the generalized commodity; therefore, the value entity of the generalized commodity is that the generalized commodity meets the system efficacy of 'GVC generalized transaction effect balance'.

The entirety of the configuration cell design will essentially follow such logic.

According to the analysis established by the present inventors, we can consider a global value chain systemSMiddle GVC subsystem (or organization and individual)S _i In (A) isM _out , M _int) And (4) exchanging. At a given target S The global value chain system is defined by its structureS Behavior of sum

To determine:

. GVC subsystem (or organization and individual)S _i Is aimed at S _i Has a structure ofS _i Behavior of

Namely:

。

if two parameters are used: (M _out , M _int) To characterize the state of the transaction system, the operation of the transaction system can be viewed as a series of outputs from the GVC subsystemM _out And input amount of large systemM _int And (4) determined exchange.M _int Is dependent onM _out And GVC subsystemS _i And large systemSStructure and action ofM _out Is dependent onM _int And GVC subsystemS _i And large systemSThe structure and behavior of (a), therefore, have the following trade relations:

M _int = M _int ( M _out , S _i , S )， M _out = M _out ( V, S _i , S )。 ( 1. 7. 7 )

between the GVC systems (or organizations and individuals) of the global value chain system, we can introduce a concept of transaction input effect. The transaction input effect refers to the degree to which the transaction input meets the actual trends or requirements of the GVC subsystem. For a certain GVC subsystemS _i Is provided withu _r Divide system's second for a GVC for other tradersrA seed substance input (or entropy flow),r = 1, 2, ···, R then the effect function of the transaction input is

( 1. 7. 8 )

The GVC systems (or organizations and individuals) that participate in trading activities in the global value chain system can be divided into two categories, namely: person in need of treatmentS _D AndS _S and (4) a supplier. Is provided withp _D Andp _S expressing the prices of the generalized commodities acceptable to the demand side and the suppliers, respectively, we can give the following Kolmogorov model:

,

。 ( 1. 7. 9 )

in that

And

is consistent with the supply behavior under the condition of (1)And

reflecting that the demand behavior and the supply behavior are conflicting, and furthermore, in

And

under the condition that the interaction between the demand side and the supply side is reflected to be favorable for the supply sideS _S Is not favorable for the demand sideS _D In a manner that

And

is in favor of the demander by reflecting the interaction between the demander and the supplierS _D Is not good for the supplierS _S In (1).

For the demand sideS _D And supplierS _S Coupled competitive power systems, we can give the following Lotka-Volterra model:

，

。 ( 1. 7. 10 )

here, the

，AIs oneA matrix whose elements outside the main diagonal are non-negative,Dis provided withAOf the same nature (n－k ) × ( n－k ) Matrix, matrixBAndCalso having non-negative elements.p _D Andp _S in that

The "partial order" is maintained within the domain.

In general, consider an open set

Upper by requiring sideS _D And supplierS _S Are coupled to formC ¹ A power system:

，

， ( 1. 7. 11 )

if it is not

And

the transaction coupling hierarchy (1.7.11) is said to be cooperative; if it is not

Andthe transaction coupling hierarchy (1.7.11) is said to be competitive.

Obviously by time shiftingt = －τThe transaction collaboration hierarchy may be a transaction competition hierarchy.

To measure the impact of the trade coupling, two dynamics are given as follows:

if it is not

，The transaction may then be coupled into the powertrain (1.7.11)

Called cooperative effect, recorded asΓ _S 。

If it is not，The transaction may then be coupled into the powertrain (1.7.11)

Called degree of competitive effect, recorded asL _S 。

It is assumed that all transaction systems (or resource allocation units) canThe method is divided into three categories: one is a transaction collaboration system, written asS _Γ (ii) a One is a trade competition system, denoted asS _L (ii) a One is a transaction collaboration system, denoted asS _Ω . From these three GVC subsystems, the following trade coupled power systems can be given:

，

，

，

， ( 1. 7. 12 )

wherein,

and

，

and

，

and

，

，

to this end, we can get，

Andthe transaction cooperation effect, the transaction competition effect and the transaction cooperation effect of a global value chain system are respectively considered.

For a global value chain system, the resource allocation quantity of the cooperative trading system, the resource allocation quantity of the competitive trading system and the resource allocation quantity of the hybrid trading system are respectively set as

，

，。

For a trade coupled power system (1.7.12) of the global value chain system, a trade cooperation effect, a trade competition effect, and a trade mix effect of the global value chain system may be determined, respectively, as follows:

( 1. 7. 13 )

now, for a certain global value chain system, a trading power factor is formed by trading cooperation effect and trading competition effect, and therefore a trading power trend factor can be introduced as follows:

。 ( 1. 7. 14 )

(3.2) from the perspective of internal collaborative organizational relationships, global value chain market allocation units can be divided into the following 9 seed types:

market configuration unit for internal centralized cooperation type global value chain network URN (on, oc, os, [ ICC ])

Market configuration unit for internal centralized cooperation type global value chain network URN (on, oc, os, [ ICK ])

Market configuration unit for internal centralized cooperation type global value chain network URN (on, oc, os, [ ICH ])

Market configuration unit for internal centralized cooperation type global value chain network URN (on, oc, os, [ IDC ])

Market allocation unit for internal centralized cooperation type global value chain network URN (on, oc, os, [ IDK ])

Market allocation unit for internal centralized cooperation type global value chain network URN (on, oc, os, [ IDH ])

Market allocation unit for internal centralized cooperation type global value chain network URN (on, oc, os, [ IMC ])

Market configuration unit for internal centralized cooperation type global value chain network URN (on, oc, os, [ IMK ])

Market allocation unit for internal centralized cooperation type global value chain network URN (on, oc, os, [ IMH ])

From the perspective of external collaborative organizational relationships, global value chain market allocation units can be divided into the following 9 seed types:

market allocation unit for external centralized cooperation type global value chain network URN (on, oc, os, [ ECC ])

Market configuration unit for external centralized competition type global value chain network URN (on, oc, os, [ ECK ])

Market configuration unit for external centralized coordination type global value chain network URN (on, oc, os, [ ECH ])

Market allocation unit for external decentralized cooperation type global value chain network URN (on, oc, os, [ EDC ])

Market allocation unit for external decentralized competitive global value chain network URN (on, oc, os, [ EDK ])

Market allocation unit for external decentralized harmonization type global value chain network URN (on, oc, os, [ EDH ])

Market allocation unit for external distributed cooperation type global value chain network URN (on, oc, os, [ EMC ])

Market allocation unit for external distributed competitive global value chain network URN (on, oc, os, [ EMK ])

Market configuration unit for external distributed coordination type global value chain network URN (on, oc, os, [ EMH ])

From the perspective of internal and external collaborative organizational relationships, global value chain market allocation units can be divided into 81 seed types as follows:

market configuration unit for external/internal centralized cooperation type global value chain NVC ([ ECC/ICC ])

Market configuration unit of external centralized cooperation/internal centralized competition type global value chain NVC ([ ECC/ICK ])

Market configuration unit for external centralized cooperation/internal centralized coordination type global value chain NVC ([ ECC/ICH ])

Market configuration unit for external centralized cooperation/internal decentralized cooperation type global value chain NVC ([ ECC/IDC ])

Market allocation unit for external centralized cooperation/internal distributed competition type global value chain NVC ([ ECC/IDK ])

Market allocation unit for external centralized cooperation/internal distributed coordination type global value chain NVC ([ ECC/IDH ])

Market configuration unit for external centralized cooperation/internal distributed cooperation type global value chain NVC ([ ECC/IMC ])

Market configuration unit of external centralized cooperation/internal distributed competition type global value chain NVC ([ ECC/IMK ])

Market configuration unit of external centralized cooperation/internal distributed coordination type global value chain NVC ([ ECC/IMH ])

Market configuration unit of external centralized competition/internal centralized cooperation type global value chain NVC ([ ECK/ICC ])

Market configuration unit for external/internal centralized competition type global value chain NVC ([ ECK/ICK ])

Market configuration unit for external centralized competition/internal centralized coordination type global value chain NVC ([ ECK/ICH ])

Market configuration unit for external centralized competition/internal decentralized cooperation type global value chain NVC ([ ECK/IDC ])

Market allocation unit for external centralized competition/internal decentralized competition type global value chain NVC ([ ECK/IDK ])

Market configuration unit for external centralized competition/internal decentralized coordination type global value chain NVC ([ ECK/IDH ])

Market configuration unit for external centralized competition/internal distributed cooperation type global value chain NVC ([ ECK/IMC ])

Market configuration unit for external centralized competition/internal distributed competition type global value chain NVC ([ ECK/IMK ])

Market configuration unit of external centralized competition/internal distributed coordination type global value chain NVC ([ ECK/IMH ])

Market configuration unit for external centralized coordination/internal centralized cooperation type global value chain NVC ([ ECH/ICC ])

Market configuration unit for external centralized coordination/internal centralized competition type global value chain NVC ([ ECH/ICK ])

Market configuration unit for external/internal centralized coordination type global value chain NVC ([ ECH/ICH ])

Market configuration unit for external centralized coordination/internal decentralized cooperation type global value chain NVC ([ ECH/IDC ])

Market configuration unit for external centralized coordination/internal decentralized competition type global value chain NVC ([ ECH/IDK ])

Market configuration unit for external centralized coordination/internal decentralized coordination type global value chain NVC ([ ECH/IDH ])

Market configuration unit for external centralized coordination/internal distributed cooperation type global value chain NVC ([ ECH/IMC ])

Market configuration unit of external centralized coordination/internal distributed competition type global value chain NVC ([ ECH/IMK ])

Market configuration unit of external centralized coordination/internal distributed coordination type global value chain NVC ([ ECH/IMH ])

Market configuration unit for external decentralized cooperation/internal centralized cooperation type global value chain NVC ([ EDC/ICC ])

Market configuration unit for external decentralized cooperation/internal centralized competition type global value chain NVC ([ EDC/ICK ])

Market configuration unit for external decentralized cooperation/internal centralized coordination type global value chain NVC ([ EDC/ICH ])

Market configuration unit for external/internal decentralized cooperation type global value chain NVC ([ EDC/IDC ])

Market allocation unit for external decentralized cooperation/internal decentralized competition type global value chain NVC ([ EDC/IDK ])

Market allocation unit for external decentralized cooperation/internal decentralized coordination type global value chain NVC ([ EDC/IDH ])

Market allocation unit for external decentralized collaboration/internal distributed collaboration type global value chain NVC ([ EDC/IMC ])

Market allocation unit for external decentralized cooperation/internal distributed competition type global value chain NVC ([ EDC/IMK ])

Market allocation unit for external decentralized cooperation/internal distributed coordination type global value chain NVC ([ EDC/IMH ])

Market configuration unit for external decentralized competition/internal centralized cooperation type global value chain NVC ([ EDK/ICC ])

Market allocation unit for external decentralized competition/internal centralized competition type global value chain NVC ([ EDK/ICK ])

Market configuration unit for external decentralized competition/internal centralized coordination type global value chain NVC ([ EDK/ICH ])

Market configuration unit for external decentralized competition/internal decentralized cooperation type global value chain NVC ([ EDK/IDC ])

Market allocation unit for external decentralized competition/internal decentralized competition type global value chain NVC ([ EDK/IDK ])

Market allocation unit for external decentralized competition/internal decentralized coordination type global value chain NVC ([ EDK/DH ])

Market allocation unit for external decentralized competition/internal decentralized cooperation type global value chain NVC ([ EDK/IMC ])

Market allocation unit for external decentralized competition/internal decentralized competition type global value chain NVC ([ EDK/IMK ])

Market allocation unit for external decentralized competition/internal decentralized coordination type global value chain NVC ([ EDK/IMH ])

Market configuration unit for external decentralized harmonization/internal centralized cooperation type global value chain NVC ([ EDH/ICC ])

Market allocation unit for external decentralized harmonization/internal centralized competition type global value chain NVC ([ EDH/ICK ])

Market configuration unit for external decentralized harmonization/internal centralized harmonization type global value chain NVC ([ EDH/ICH ])

Market configuration unit for external decentralized harmonization/internal decentralized cooperative type global value chain NVC ([ EDH/IDC ])

Market allocation unit for external decentralized harmonization/internal decentralized competition type global value chain NVC ([ EDH/IDK ])

Market allocation unit for external/internal decentralized harmonization type global value chain NVC ([ EDH/IDH ])

Market configuration unit for external decentralized harmonization/internal decentralized cooperative type global value chain NVC ([ EDH/IMC ])

Market allocation unit for external decentralized harmonization/internal decentralized competition type global value chain NVC ([ EDH/IMK ])

Market configuration unit for external decentralized harmonization/internal decentralized harmonization type global value chain NVC ([ EDH/IMH ])

Market configuration unit of external distributed cooperation/internal centralized cooperation type global value chain NVC ([ EMC/ICC ])

Market configuration unit of external distributed cooperation/internal centralized competition type global value chain NVC ([ EMC/ICK ])

Market configuration unit for external distributed cooperation/internal centralized coordination type global value chain NVC ([ EMC/ICH ])

Market configuration unit for external/internal decentralized cooperation type global value chain NVC ([ EMC/IDC ])

Market allocation unit for external distributed cooperation/internal distributed competition type global value chain NVC ([ EMC/IDK ])

Market configuration unit for external distributed cooperation/internal distributed coordination type global value chain NVC ([ EMC/IDH ])

Market configuration unit for external distributed cooperation/internal centralized cooperation type global value chain NVC ([ EMC/IMC ])

Market configuration unit of external distributed cooperation/internal centralized competition type global value chain NVC ([ EMC/IMK ])

Market configuration unit of external distributed cooperation/internal centralized coordination type global value chain NVC ([ EMC/IMH ])

Market configuration unit of external distributed competition/internal centralized cooperation type global value chain NVC ([ EMK/ICC ])

Market allocation unit for external distributed competition/internal concentrated competition type global value chain NVC ([ EMK/ICK ])

Market configuration unit for external distributed competition/internal centralized coordination type global value chain NVC ([ EMK/ICH ])

Market configuration unit for external distributed competitive/internal distributed collaborative global value chain NVC ([ EMK/IDC ])

Market allocation unit for external distributed competition/internal distributed competition type global value chain NVC ([ EMK/IDK ])

Market allocation unit for external distributed competition/internal distributed coordination type global value chain NVC ([ EMK/IDH ])

Market configuration unit for external distributed competition/internal distributed cooperation type global value chain NVC ([ EMK/IMC ])

Market allocation unit for external/internal distributed competition type global value chain NVC ([ EMK/IMK ])

Market configuration unit of external distributed competition/internal distributed coordination type global value chain NVC ([ EMK/IMH ])

Market configuration unit of external distributed coordination/internal centralized cooperation type global value chain NVC ([ EMH/ICC ])

Market configuration unit for external distributed coordination/internal centralized competition type global value chain NVC ([ EMH/ICK ])

Market configuration unit for external/internal centralized coordination type global value chain NVC ([ EMH/ICH ])

Market configuration unit for external decentralized harmonization/internal decentralized cooperative type global value chain NVC ([ EMH/IDC ])

Market allocation unit for external distributed coordination/internal distributed competition type global value chain NVC ([ EMH/IDK ])

Market allocation unit for external/internal distributed coordination type global value chain NVC ([ EMH/IDH ])

Market configuration unit for external distribution coordination/internal distribution cooperation type global value chain NVC ([ EMH/IMC ])

Market configuration unit of external distribution coordination/internal distribution competition type global value chain NVC ([ EMH/IMK ])

Market configuration unit of external distribution coordination/internal distribution coordination type global value chain NVC ([ EMH/IMH ])

4. Description of the drawings

FIG. 1 illustrates: FIG. 1 is a MA/CVC: and (5) a main flow chart for purchasing the production materials.

The goal of global value chain configuration is to make the global value chain operate more efficiently, more mobile, and more in harmony. Four currently available decision tools for measuring the operational efficiency of the global value chain market configuration internal and external associations are: and (3) configuring internal and external associated basic information of the global value chain market, such as internal and external associated fund information of the global value chain market: cash flow and financial rate, etc.; configuration information associated inside and outside the global value chain market configuration, such as cost information associated inside and outside the global value chain market configuration: resource utilization and overall profit, etc.; capability information associated internally and externally to the global value chain market configuration, such as expertise and vulnerability of the global value chain organization associated internally and externally to the competitor; the global value chain market configures internal and external associated resource information, including internal and external associated resources and manpower, etc., as shown in fig. 1.

FIG. 2 illustrates:

a multi-level, multi-functional and multi-domain product chain system with organization node set as the center is shown in fig. 2. Any generalized meta-system commodity can be regarded as a hierarchical system which is formed by a plurality of resource nodes and various configuration nodes by taking an organization node set as a center. In a generalized meta-system commodity, a variety of resources with different quantities and different measurement units can be summarized aslA resource node, andlone resource node can be summarized asmThe number of the configuration nodes is equal to the number of the configuration nodes,meach configuration node can be summarized asnTissue nodes.

Now assume that a generalized meta-system class of goods isSWhich compriseslA resource node (k = 1, 2, ···, l )，mEach of the configuration nodes (or configuration agents,j = 1, 2, ···, m），ntissue node (i = 1, 2, ···, n )，wA resource category (r = 1, 2, ···, w ) Which has in phase spacesAnd (4) a plurality of degrees of freedom. In any generalized meta-system commodity, when all organization units are independent from each other,irrespective of the configuration of the nodesjAnd tissue nodeiWhether or not to form a one-to-one correspondence relationship, the number of the tissue nodesnAre all equal to the number of organization unitsN . There are two cases here: or any configuration nodejCan only organize nodes by oneiControl and coordination, which may be referred to as exclusivity; or any configuration node may not necessarily consist of only one organizational nodeiControl and coordination, which case may be referred to as compatibility. In any complex system, when all the organization units are independent of each other, the number of the organization units does not exceed the number of the configuration nodes, namelyN ≤ m(ii) a Without the number of tissue nodes exceeding the number of tissue units, i.e. the number of tissue nodesn ≤ N(ii) a Therefore, the number of tissue nodes does not exceed the number of configuration nodes, i.e. the number of configuration nodesn ≤ N ≤ m 。

FIG. 3 illustrates:

the generalized commodity hierarchy and the multi-level value chain hierarchy are shown in fig. 3.

According to the analysis established by the inventor, the value of the commodity is to meet the social necessary efficacy of the general supply and demand relationship of the society. There is a base of value at different levels as follows.

The value of the simple commodity lies in that the simple production meets the social essential effect of the general supply and demand relationship of the society:

V _simpl ：

, s. t.

；

the value of the composite commodity lies in that the composite production meets the social essential effect of the common supply and demand relationship of the society:

V _compl ：

, s. t.

the value of the simple system commodity is that the simple production system meets the social essential effect of the general supply and demand relationship of the society:

V _syst ：

, s. t.

the value of the complex system commodity is that the complex production system meets the social essential effect of the general supply and demand relationship of the society:

V _com-syst ：

,

s. t.

FIG. 4 illustrates:

the GVC market is provided with an intelligent integrated dynamic convergence network system.

5. Detailed description of the preferred embodiments

The MA/GVC system to be developed and established is undoubtedly an advanced economic scientific and technical system, an advanced management scientific and technical system and an advanced system engineering theory and practice, and relates to the problems of wide range, large investment, long implementation period, high difficulty and certain risk, and a scientific method is needed to ensure the success of project implementation.

C1 global value chain market allocation project implementation planning

According to the global value chain organizational reality, the whole project is determined to be carried out in two stages:

the first stage mainly implements the system control, sales configuration, receivable configuration, logistics arrangement, payable configuration, inventory accounting, product data configuration (including global value chain structure configuration and process configuration), cost budget configuration (including cost configuration), financial project accounting, PDM data arrangement and demand analysis, hardware network environment construction and global value chain market configuration related to the inside and the outside of the global value chain market configuration. The period is about 12 months. The method mainly completes the integration of related logistics and fund flow inside and outside the global value chain market configuration, and the basic configuration is standard and transparent.

And the second stage is to integrate the production main planning, material demand planning, capacity balance, workshop project configuration, quality configuration, equipment metering configuration, human resource configuration, solution analysis and global value chain market configuration which are related inside and outside the global value chain market configuration. The period is about 16 months. The holographic collaborative organization mode mainly realizes that the market related to the inside and the outside of the global value chain market configuration is used as the demand, the main plan driven longitudinally and transversely is used as the core, and the input and output related to the inside and the outside of the global value chain market configuration is used as the main content, effectively controls the work-in-process, compresses the stock to the maximum extent, improves the delivery date and quickly meets the market demand.

Overall target for C2 market configuration

aAnd promoting the global value chain to be converted from a traditional closed, low-efficiency and extensive configuration mode to a transparent, cooperative, normative and lean configuration mode by taking the implementation of the global value chain market configuration project as a trigger, and supporting the realization of the global value chain strategic target.

bReinforcing the global value chain infrastructure. Establishing standardized global value chain market allocation internal and external associated data standard and code bodyThe system promotes the rectification of the global value chain foundation; product design and process file standardized configuration related to the inside and the outside of global value chain market configuration are enhanced; raw material consumption, working hours, capital occupation and equipment time-per-hour quota allocation related to the inside and the outside of global value chain market allocation are refined; standardizing global value chain production period standards related to the inside and the outside of global value chain market configuration; customer resource information configuration related to the inside and the outside of global value chain market configuration is enhanced; the cost expense and price configuration related to the inside and the outside of the global value chain market configuration are refined; and the carrying flow and role specification configuration related to the inside and the outside of the global value chain market configuration is enhanced.

cImprove configuration, decision-making methods. Information resource planning related to the inside and the outside of global value chain market allocation, data integration of each subsystem and global sharing of a database are realized; establishing a global value chain basic information structure which is related to the inside and the outside of the global value chain market configuration and comprises an integrated information network and a comprehensive and uniform data interaction format; configuring internal and external related complete inventory configuration and analysis in the global value chain market; global value chain market configuration internal and external associated process consumption cost accounting; configuring internal and external associated credit risk control and customer resource configuration in the global value chain market; the integrated application of the main system operation planning, the material demand planning and the order configuration driven longitudinally and transversely; configuring real-time cost accounting of internal and external associated sub-products by the global value chain market; fast quotation; carrying out profit budget and profit-loss balance analysis on the internal and external correlation of global value chain market configuration; and (4) online multidimensional data analysis and decision application support.

　　dAnd the global value chain market allocation is standardized, the global value chain allocation is systematically promoted, the global value chain is supported to carry out systematic evolution, and transparent, open, cooperative, standardized and lean global value chain culture is formed.

Implementation content of C3 market configuration

aGlobal value chain market configurations internal and external associated logistics arrangements. The method is supported by a brand new information system, the requirements of the global value chain market configuration internal and external associated production systems are timely transmitted, and the method quickly reacts to the requirements of the global value chain market configuration internal and external associated production through information integration with the global value chain market configuration internal and external associated logistics systems, so that the complete set of the global value chain market configuration internal and external associated production materials is ensured. The global value chain market allocation system provides a demand plan of the internal and external associated production of the global value chain market allocation according to the system operation plan; the global value chain market configuration internal and external associated production system can inquire the complete set condition of raw materials and parts according to material planning and provide global value chain market configuration internal and external associated logistics arrangement planning; establishing a perfect global value chain market allocation internal and external associated supplier allocation system by means of the integration of the global value chain market allocation internal and external associated information of a global value chain market allocation system; information such as delivery date, article quality and the like of internal and external associated suppliers configured in the global value chain market is used as the basis for evaluating the suppliers; integrating global value chain market configuration internal and external associated supplier evaluation results with distribution of logistics arrangement shares and payment policies; and establishing an information base of basic configurations such as global value chain market configuration internal and external related logistics arrangement period, economic batch, safety stock and the like, and providing a basis for timely guaranteeing material supply.

bGlobal value chain market deployments internal and external associated sales, inventory and production systems. The system operational plan is a schema file that directs the global value chain market to configure internal and external associated production activities. In order to guarantee the implementation of the system operation planning, a series of matched plans such as material logistics arrangement planning, outside cooperation planning, workshop project planning, equipment use planning, tooling mold planning and the like which are related inside and outside the global value chain market configuration can be generated at the same time. The system operation plan and the plans are in the relation of outline and purpose, and outline can be referred to as a target.

cGlobal value chain market configuration internal and external associated cost configurations. Planning, accounting, controlling and configuring the production cost associated with the inside and the outside of the global value chain market configuration, establishing a section cost budgeting method associated with the inside and the outside of the global value chain market configuration, comparing the cost with the cost analysis in the affairs, leading the budgeting to be learned and accurate by sections step by step, and providing useful data for the global value chain organization decision-making.

dGlobal value chain market configurations internal and external associated due configurations. The payable subsystem which is arranged inside and outside the global value chain market is mainly used for configuring various interactive funds between the global value chain and a supplier in the operation process, effectively helping a global value chain configurator master the flow direction of funds, controlling the outflow of the funds of the global value chain by monitoring the payment condition and forming a good cycle of the mobile funds. The payable subsystem associated internally and externally to the global value chain market configuration fills out invoices, taxes and logistics arrangement fees based on the occurrence of the logistics arrangement activity, or may directly invoke orders generated by the logistics arrangement subsystem. The invoice amount and the warehousing material are shared, and the payment condition of the warehousing material can be determined. After the invoice is posted, an account receivable is generated, the payment bill and the account receivable are settled, the paid amount and the unpaid amount are determined, and meanwhile, the prepayment can be processed. In order to master future fund flow conditions of the global value chain organization in real time, the system which is associated with the inside and the outside of the global value chain market configuration also provides rich inquiry statistical functions and is used in an integrated way with a logistics arrangement subsystem and an accounting subsystem which are associated with the inside and the outside of the global value chain market configuration.

eGlobal value chain market configurations internal and external associated receivable configurations. The global value chain organization realizes the sharing of data between financial project departments and sales departments which are related inside and outside the global value chain market configuration through the application of a global value chain market configuration system, and completes the communication of data information on a network; financial project department with internal and external associations for global value chain market configurationsThe income accounting form money is registered by taking a sales invoice of a sales department as a basis; the income accounting form money of the inside and outside correlation of global value chain market configuration is collected according to the current user. The internal and external related collection and sale invoices of the global value chain market configuration are determined according to the data, and the flow source is determined. Each account receivable can be appointed when the payment is returned for settlement, so that the income accounting form age and the pre-receivable account age can be reflected timely and accurately, and the income accounting form age and the pre-receivable account age can be analyzed, and the returned account age can also be analyzed.

6. Introduction to 600 patent Co-implementation plan

Through thirty years of free exploration, an independent inventor officially submits 600 patent applications to the national patent office through an electronic application system in 2011 and 9 months, and submits 600 parts of materials such as a claim, a specification, an attached drawing and the like with about 3600 ten thousand characters in total.

After thirty years of free exploration, on the basis that more than eighty papers (without cooperative achievement) have been published through international and domestic academic publications and academic conferences, eight academic big works (total 3000 ten thousand characters) which are closely related to the 600 technical inventions reported at this time have been written and completed by independent inventors recently, and the official publication affairs are treated successively after 9 months in 2011.

The 600 technical inventions reported this time are a new technical cluster of self-forming system established by independent and free exploration for thirty years, and their overall name is "global value chain network technology support system" [ DCN/HII (GVC) ].

Based on a series of independently and freely completed major pioneering academic research results and 600 latest technical inventions, the inventor provides a strategy which can be called as 'opening the earth' plan-a global value chain system engineering technology cluster development overall strategy.

The overall strategic goals of the global value chain network technology support system can be summarized as follows:

1. in the basic aspect of technical development (the front end of an ICT industrial chain), a multi-level multi-mode global value chain system (GVC) is taken as a core, connection and coordination of natural intelligence and artificial intelligence based on a computer and a network thereof are taken as a main line of an upgrading process of a general Intelligent Integrated System (IIS), a brand-new logic foundation, a mathematical foundation, a scientific foundation and a brand-new technical foundation and engineering foundation are established, a relatively closed and relatively static 'resource pool' -cloud computing network is injected with soul, intelligence and life, a global intelligent integrated network computer system (CS/HSN (GII) is built, and the global Internet is created into a technical support system which really has a life and ecological holographic synergetic organization.

2. In the application aspect of brand-new technology (at the end of an ICT industrial chain), a global value chain system (GVC) with multi-level and multi-mode is taken as a core, the method is characterized in that connection and coordination of a cognitive system and a practice system based on a computer aided system and the Internet are used as a main line of an evolution process of a high-level intelligent integrated system (HIIS), an intelligent integrated scientific and technological system (IIS & IIT) based on a completely new scientific theory of a meta-system (MS) is established, a novel global Internet endowed with life vitality is integrated with a logistics network, an energy network, a financial network and a knowledge network which are scattered in all the fields around the world into a whole (DCN), a global value chain system project is vigorously carried out, and a global intelligent integrated dynamic convergence network system (DCN/HII (GVC)) with a real life and ecological holographic synergetic organization is established, so that an intelligent integrated network, a life Internet and an ecological operation network are built.

By implementing a global value chain system engineering technology cluster to develop a general strategy, which is called as a 'open the earth' plan by the inventor, an overlooked 'cloud' computing system is transformed into a 'heaven and earth' computing system which can be used for connecting everything and runs through longitude and latitude.

The heaven-earth computing revolution based on the cloud computing revolution takes a multi-level multi-mode global value chain system as a core, takes a modern electronic technology, a modern communication technology and a modern information network technology as a support foundation, and tightly combines a logistics network, an energy network, an information network, a financial network and a knowledge network to establish a high-efficiency, intensive and intelligent integrated dynamic converging network large system with life (or ecological) self-organization property, thereby greatly simplifying team management (and enterprise management), department management (and industry management), regional management, national management and global management, effectively reducing the cost of team (and enterprise) infrastructure, the cost of department (and industry) infrastructure, the cost of regional infrastructure, the cost of national infrastructure and the cost of global infrastructure, and comprehensively improving the informatization level of the team (enterprise), The department (and industry) informatization level, the regional informatization level, the national informatization level and the global informatization level change all social organizations and activities thereof into configuration nodes and activities thereof in a global multi-level multi-mode system efficacy chain network system, particularly change all social economic organizations and activities thereof into configuration nodes and activities thereof in the global multi-level multi-mode value chain network system, and finally lead to the knowledge, intellectualization and networking to become the basic attributes of society, organization and individuals.

Claims (7)

1. The independent claim, namely an ICT technical support design of a global value chain market configuration unit, is a new technique proposed by the applicant by establishing a basic model and a paradigm of network configuration dynamics, with internet users as the center, further with a global value chain system (GVC) as the center, and with connection and coordination of natural intelligence and artificial intelligence based on computers and their networks as a principal line of a general Intelligent Integrated System (IIS) upgrade process, in order to modify an indefinite "cloud" computing system into a universal and longitude and latitude-penetrating "heaven-earth" computing system, based on establishing a brand new logic foundation, a brand new mathematical foundation, a brand new scientific foundation, and a brand new technical foundation and a brand new engineering foundation, and the present invention is characterized in that:

A. for ICT technical support of global value chain market configuration units, a brand new logic basis comprises holographic convergence logic, bipolar convergence logic and bipolar holographic convergence logic; the brand new mathematics foundation comprises holographic convergent mathematics, dipolar convergent mathematics and system transition analytical mathematics; the brand new scientific basis comprises resource allocation dynamics, holographic organization synergetics, a system efficacy value theory, game organization synergetics, hedging balance economics, holographic confluent physics and through science (cross science and transverse science) formed by the large synthesis of a series of brand new theories, namely element system science and intelligent integration science; the brand new technology base is a brand new system technology (cluster) taking a value chain system as a core and oriented to holographic cooperativity; the brand new engineering foundation is a brand new system engineering (cluster) taking a value chain system as a core and oriented to holographic cooperativity;

B. for ICT technical support of the global value chain market allocation unit, "world" computing itself is an extremely complex system with a very complex holographic collaborative organization structure, where, on the one hand, various computers and their infrastructures, attached devices and network devices (including servers, browsers) are connected in a holographic collaborative organization mode (including ICC, ICK, ICH, IDC, IDK, IDH, IMC, IMK, IMH, ECC, ECK, ECH, EDC, EDK, EDH, EMC, EMK, EMH) to form a computer-interconnected network organization; on the other hand, various users and their efficacy chains are connected in a holographic collaborative organization mode (including ICC, ICK, ICH, IDC, IDK, IDH, IMC, IMK, IMH, ECC, ECK, ECH, EDC, EDK, EDH, EMC, EMK, EMH) to form a natural intelligent socialization organization, which together with the computer interconnection network organization forms the "world" computing system CS/hsn (gii) referred to by the inventor;

C. for ICT technical support of a Global Value Chain market configuration unit, establishing a market configuration unit design concept, framework and model facing Global Value Chain market Operation (Marketing Operation of Global Value Chain), and further establishing a design basis of business process arrangement;

D. for ICT technical support of a global value chain market configuration unit, introducing appropriate various basic cooperative variables for respectively reflecting basic power, basic load, basic efficacy, basic consumption, internal cooperation and competition and external cooperation and competition of a general complex adaptive system, and establishing an engineering concept and a technical scheme for designing the configuration unit.

2. The invention according to the independent claim 1 regards the global value chain market configuration system as a set consisting of a certain number (or variable number) of nodes and a certain number (or variable number) of chains, having multiple levels and multiple modes, and establishes a design concept and framework of configuration units oriented to global value chain market operations, the invention is characterized in that:

for global value chain, assume a generalized meta-system class of goods asSWhich compriseslA resource node (k = 1, 2, ···, l )，mEach of the configuration nodes (or configuration agents,j = 1, 2, ···, m），ntissue node (i = 1, 2, ···, n )，wA resource category (r = 1, 2, ···, w ) Which has in phase spacesA single degree of freedom; in any generalized meta-system commodity, when all organization units are independent from each other, no matter nodes are configuredjAnd tissue nodeiWhether or not to form a one-to-one correspondence relationship, the number of the tissue nodesnAre all equal to the number of organization unitsN (ii) a There are two cases here: or any configuration nodejCan only organize nodes by oneiControl and coordination, which may be referred to as exclusivity; or any configuration node may not necessarily consist of only one organizational nodeiControl and coordination, which case may be referred to as compatibility; in any complex system, when all the organization units are independent of each other, the number of the organization units does not exceed the number of the configuration nodes, namelyN ≤ m(ii) a Without the number of tissue nodes exceeding the number of tissue units, i.e. the number of tissue nodesn ≤ N(ii) a Therefore, the number of tissue nodes does not exceed the number of configuration nodes, i.e. the number of configuration nodesn ≤ N ≤ m ；

The value of the simple commodity lies in that the simple production meets the social essential effect of the general supply and demand relationship of the society:

V _simpl ：

, s. t.

；

the value of the composite commodity lies in that the composite production meets the social essential effect of the common supply and demand relationship of the society:

V _compl ：

, s. t.

the value of the simple system commodity is that the simple production system meets the social essential effect of the general supply and demand relationship of the society:

V _syst ：

, s. t.

the value of the complex system commodity is that the complex production system meets the social essential effect of the general supply and demand relationship of the society:

V _com-syst ：

, s. t.

。

3. dependent claims-for global value chain market configuration, a global value chain market operation oriented configuration unit design model is established with the connection and coordination of the GVC cognitive system (RS and its computer-aided system) and the GVC practice system (PS and its computer-aided system) as the principal line of the evolution process of the advanced intelligent integrated system (HIIS) according to the invention of independent claim 1, the present claims being characterized in that:

we can consider the development of transaction concepts and models in the interrelationships between the various subsystems of the global value chain system (or between organizations and individuals) to form concepts and models that can be referred to as "GVC generalized transactions";

system (or organization and individual) traders to divide GVC into systemsiThe generalized GVC commodity basis available isW _i ∈ Θ _i ，Θ _i For GVC-subsystem (or organization and individual) tradersiA set of alternative generalized GVC commodity compositions, also known as generalized GVC commodity space;Ithe GVC subsystem traders each select a vector composed of generalized GVC commoditiesW = ( W ₁ , W ₂ , ···, W _I ) May be called generalized GVC commodity combinations (generalized foods profiles) of which the set is

；

The GVC generalized transaction formed based on the generalized GVC commodities is a comprehensive transaction;

the concept of generalized GVC commodity composition canThe concept of generalized mixed GVC commodity composition (composition of generated mixed foods) is introduced; GVC subsystem (or organization and individual) tradersiGeneralized mixed GVC commodity composition ofΩ _i Is his generalized GVC commodity spaceΘ _i The probability distribution represents that when a GVC subsystem trader actually carries out trading, the probability distribution is randomly selected and implemented in the generalized GVC commodity composition;Ω _i ( W _i ) To representΩ _i Commodity composition assigned to generalized GVCW _i Probability of, GVC subsystem traderiGeneralized mixed GVC commodity space of (a)Σ _i Generalized hybrid GVC Commodity composition space can be written asΣ= ×Σ _i (ii) a The generalized GVC commodity constitutes a special case of a generalized mixed GVC commodity;

suppose that GVC commodity can be divided out for the complex large systemmA field of activity andneach department; first, theiA department (i = 1, 2, ···, n ) To (1) ajAn activity ofj = 1, 2, ···, m ) The enhanced benefit from the strategy based on various generalized GVC commodity combinations isB _{i j} ( W ) Then the total benefit of the system is:

( 1. 7. 2 )

whereinp _{i j k} Is as followsiThe department isjIn the middle of the activitykSpecies resource (k = 1, 2, ···, l ) The transaction price of (2).

4. Dependent claims-for global value chain market deployment, the GVC generalized trading power and effect balancing concepts and a series of corresponding theorems are given according to the invention of independent claim 1, the present claims being characterized in that:

definitions 1A generalized GVC commercial productW ^* The condition for satisfying the power balance (feasibility balance) is that for alli In all other areasW _i ∈ Θ _i In the following, the first and second parts of the material,

( 1. 7. 3 )

definition 2A generalized Mixed GVC commercial productΩ ^* The condition for satisfying the power balance (feasibility balance) is that for alliIn all other areasW _i ∈ Θ _i In the following, the first and second parts of the material,

。

5. dependent claims-for global value chain market allocation, a more specific design and description of the business process is given by case analysis according to the invention of independent claim 1, characterized in that:

the internal and external related logistics of the global value chain organization are arranged as an outsource technology department, a leading business logistics department, an auxiliary business logistics department and a derivative product logistics department, and the economic connection between a central city and surrounding small towns and villages is also considered; the outsource technology department is responsible for production preparation of parts needing outsource logistics arrangement, the main business logistics arrangement department is responsible for logistics arrangement business functions of main businesses needing the outsource logistics arrangement, the auxiliary business logistics arrangement department is responsible for logistics arrangement business functions of auxiliary businesses and outsources and subcontracts of basic construction, technical measures and maintenance infrastructure projects, and the derivative product logistics arrangement department is responsible for logistics arrangement business functions of derivative products and outsources and subcontracts of the basic construction, the technical measures and the maintenance infrastructure projects.

6. Dependent claims-for the global value chain, the invention according to independent claim 1 introduces appropriate various basic co-variables for reflecting the basic dynamics, basic load, basic efficiency, basic consumption, internal and external co-ordination and competition of the general complex adaptive system, respectively, building an engineering idea of the design of the market configuration unit, this claim being characterized in that:

the basic logic of our invention's thought on the problem of commodity value in generalized GVC according to the independent claim 1 can be described as the following structure: the price of the generalized GVC commodity is based on the value of the generalized GVC commodity; the value entity of the generalized GVC commodity lies in the system efficacy of the generalized GVC commodity; the systematic efficacy of generalized GVC commodities lies in the trader's objectives and the goals of the trading system; the goal of the trader and trading system is to achieve "GVC generalized trading dynamics balance" and "GVC generalized trading effects balance"; the system efficacy of the generalized GVC commodity meeting the 'GVC generalized trading effect balance' is the social essential efficacy of the generalized GVC commodity; therefore, the value entity of the generalized GVC commodity is that the generalized GVC commodity meets the system efficacy of 'GVC generalized transaction effect balance';

the entirety of the configuration cell design will essentially follow such logic.

7. Dependent claims-for global value chain, the invention according to independent claim 1 introduces appropriate various basic co-variables for reflecting basic dynamics, basic load, basic efficacy, basic consumption, internal cooperation and competition and external cooperation and competition of a general complex adaptation system, respectively, creating a technical solution for market allocation unit design, this claim being characterized in that:

from the perspective of internal collaborative organizational relationships, global value chain market allocation units can be divided into the following 9 seed types:

market configuration unit for internal centralized cooperation type global value chain network URN (on, oc, os, [ ICC ])

Market configuration unit for internal centralized cooperation type global value chain network URN (on, oc, os, [ ICK ])

Market configuration unit for internal centralized cooperation type global value chain network URN (on, oc, os, [ ICH ])

Market configuration unit for internal centralized cooperation type global value chain network URN (on, oc, os, [ IDC ])

Market allocation unit for internal centralized cooperation type global value chain network URN (on, oc, os, [ IDK ])

Market allocation unit for internal centralized cooperation type global value chain network URN (on, oc, os, [ IDH ])

Market allocation unit for internal centralized cooperation type global value chain network URN (on, oc, os, [ IMC ])

Market configuration unit for internal centralized cooperation type global value chain network URN (on, oc, os, [ IMK ])

Market allocation unit for internal centralized cooperation type global value chain network URN (on, oc, os, [ IMH ])

From the perspective of external collaborative organizational relationships, global value chain market allocation units can be divided into the following 9 seed types:

market allocation unit for external centralized cooperation type global value chain network URN (on, oc, os, [ ECC ])

Market configuration unit for external centralized competition type global value chain network URN (on, oc, os, [ ECK ])

Market configuration unit for external centralized coordination type global value chain network URN (on, oc, os, [ ECH ])

Market allocation unit for external decentralized cooperation type global value chain network URN (on, oc, os, [ EDC ])

Market allocation unit for external decentralized competitive global value chain network URN (on, oc, os, [ EDK ])

Market allocation unit for external decentralized harmonization type global value chain network URN (on, oc, os, [ EDH ])

Market allocation unit for external distributed cooperation type global value chain network URN (on, oc, os, [ EMC ])

Market allocation unit for external distributed competitive global value chain network URN (on, oc, os, [ EMK ])

Market allocation unit for external distributed coordination type global value chain network URN (on, oc, os, [ EMH ]).

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