CN102724255A - Global value chain planning configuration intelligence integration operation system technology base - Google Patents
Global value chain planning configuration intelligence integration operation system technology base Download PDFInfo
- Publication number
- CN102724255A CN102724255A CN2011103469084A CN201110346908A CN102724255A CN 102724255 A CN102724255 A CN 102724255A CN 2011103469084 A CN2011103469084 A CN 2011103469084A CN 201110346908 A CN201110346908 A CN 201110346908A CN 102724255 A CN102724255 A CN 102724255A
- Authority
- CN
- China
- Prior art keywords
- gvc
- external
- internal
- configuration
- value chain
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Pending
Links
- 238000013439 planning Methods 0.000 title claims abstract description 425
- 238000005516 engineering process Methods 0.000 title claims abstract description 63
- 230000010354 integration Effects 0.000 title claims abstract description 24
- 238000000034 method Methods 0.000 claims abstract description 130
- 230000008569 process Effects 0.000 claims abstract description 96
- 230000008520 organization Effects 0.000 claims abstract description 42
- 230000002195 synergetic effect Effects 0.000 claims abstract description 18
- 238000007726 management method Methods 0.000 claims description 70
- 230000000694 effects Effects 0.000 claims description 47
- 230000006870 function Effects 0.000 claims description 34
- 238000013461 design Methods 0.000 claims description 31
- 238000003860 storage Methods 0.000 claims description 27
- 238000004891 communication Methods 0.000 claims description 24
- 239000011159 matrix material Substances 0.000 claims description 23
- 230000015654 memory Effects 0.000 claims description 22
- 238000004519 manufacturing process Methods 0.000 claims description 20
- 239000000463 material Substances 0.000 claims description 14
- 238000011161 development Methods 0.000 claims description 13
- 238000012545 processing Methods 0.000 claims description 9
- 230000008859 change Effects 0.000 claims description 8
- 239000013598 vector Substances 0.000 claims description 8
- 230000007246 mechanism Effects 0.000 claims description 7
- 238000013468 resource allocation Methods 0.000 claims description 7
- 230000015572 biosynthetic process Effects 0.000 claims description 5
- 238000011156 evaluation Methods 0.000 claims description 4
- 230000007717 exclusion Effects 0.000 claims description 4
- 239000000203 mixture Substances 0.000 claims description 4
- 230000001737 promoting effect Effects 0.000 claims description 4
- 230000007704 transition Effects 0.000 claims description 4
- 238000013473 artificial intelligence Methods 0.000 claims description 3
- 230000006855 networking Effects 0.000 claims description 3
- 239000002994 raw material Substances 0.000 claims description 3
- 238000003786 synthesis reaction Methods 0.000 claims description 3
- 238000012384 transportation and delivery Methods 0.000 claims description 3
- 230000009471 action Effects 0.000 claims description 2
- 230000009286 beneficial effect Effects 0.000 claims description 2
- 230000008901 benefit Effects 0.000 claims description 2
- 230000005540 biological transmission Effects 0.000 claims description 2
- 230000000903 blocking effect Effects 0.000 claims description 2
- 238000009826 distribution Methods 0.000 claims description 2
- 230000001419 dependent effect Effects 0.000 claims 6
- 230000033772 system development Effects 0.000 claims 2
- 230000003044 adaptive effect Effects 0.000 claims 1
- 230000018109 developmental process Effects 0.000 claims 1
- 230000004044 response Effects 0.000 claims 1
- 230000001149 cognitive effect Effects 0.000 abstract description 7
- 238000004458 analytical method Methods 0.000 description 15
- 230000003993 interaction Effects 0.000 description 15
- 238000013507 mapping Methods 0.000 description 13
- 229910052799 carbon Inorganic materials 0.000 description 7
- 238000004880 explosion Methods 0.000 description 7
- 239000000243 solution Substances 0.000 description 6
- 238000004364 calculation method Methods 0.000 description 5
- 229910052698 phosphorus Inorganic materials 0.000 description 5
- 230000002452 interceptive effect Effects 0.000 description 3
- 230000033001 locomotion Effects 0.000 description 3
- 238000005259 measurement Methods 0.000 description 3
- 238000011160 research Methods 0.000 description 3
- 230000009466 transformation Effects 0.000 description 3
- 230000001364 causal effect Effects 0.000 description 2
- 230000006872 improvement Effects 0.000 description 2
- 229910052757 nitrogen Inorganic materials 0.000 description 2
- 238000007670 refining Methods 0.000 description 2
- 238000004088 simulation Methods 0.000 description 2
- 238000000638 solvent extraction Methods 0.000 description 2
- 230000003068 static effect Effects 0.000 description 2
- 206010063385 Intellectualisation Diseases 0.000 description 1
- 230000002159 abnormal effect Effects 0.000 description 1
- 239000008186 active pharmaceutical agent Substances 0.000 description 1
- 230000003542 behavioural effect Effects 0.000 description 1
- 239000003795 chemical substances by application Substances 0.000 description 1
- 238000010276 construction Methods 0.000 description 1
- 239000013078 crystal Substances 0.000 description 1
- 238000007405 data analysis Methods 0.000 description 1
- 238000001514 detection method Methods 0.000 description 1
- 230000004927 fusion Effects 0.000 description 1
- 230000008570 general process Effects 0.000 description 1
- 230000010365 information processing Effects 0.000 description 1
- 230000000977 initiatory effect Effects 0.000 description 1
- 238000002347 injection Methods 0.000 description 1
- 239000007924 injection Substances 0.000 description 1
- 238000013178 mathematical model Methods 0.000 description 1
- 238000012544 monitoring process Methods 0.000 description 1
- 238000003909 pattern recognition Methods 0.000 description 1
- 230000035515 penetration Effects 0.000 description 1
- 238000007639 printing Methods 0.000 description 1
- 238000011112 process operation Methods 0.000 description 1
- 230000008844 regulatory mechanism Effects 0.000 description 1
- 238000012954 risk control Methods 0.000 description 1
- 238000012163 sequencing technique Methods 0.000 description 1
- 238000007711 solidification Methods 0.000 description 1
- 230000008023 solidification Effects 0.000 description 1
- 230000009897 systematic effect Effects 0.000 description 1
- 230000029305 taxis Effects 0.000 description 1
Images
Landscapes
- Management, Administration, Business Operations System, And Electronic Commerce (AREA)
Abstract
A global value chain planning configuration intelligence integration operation system technology base is a new technology established through establishing a network configuration dynamics base model, a normal form and an equation system, and a game organization synergetics base model, the normal form and the equation system, wherein the technology is on a basis of establishing brand new logic, mathematics and science; a '' cloud '' calculating system is reconstructed into a '' universe '' calculating system which has connection with everything, an Internet user is taken as a center, and then a multi-level global value chain (GVC) is taken as the center, and combination and coordination performed by 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 integration system (HIIS).
Description
Technical Field
The invention is 600 patent clusters (named as 399 in 'global value chain network technology support system [ DCN/IIL (VCSE);') formally submitted to the national patent office through an electronic system in the 9 th month of 2011 in Lizhong of the applicant.
The invention and the invention patent cluster (the general name is "global value chain network technology support system [ DCN/IIL (VCSE) ]", the 381 st item, 382 nd item, 383 th item, 384 th item, 385 th item, 386 th item, 387 th item, 388 th item, 389 th item, 390 th item, 391 th item, 392 th item, 394 th item, 395 th item, 396 th item, 397 th item, 398 th item and 400 th item together form the invention patent cluster "global value chain planning configuration support system (ICT-PAM/[ GVC ])").
The applicant proposed a "global value chain network technology support system [ DCN/IIL (VCSE) ]; "with global value chain system (GVC) as the core, and with connection and coordination of natural intelligence and artificial intelligence based on computers and their networks as the main line of General Intelligent Integrated System (GIIS) upgrading process, a completely new logic foundation, mathematic foundation, scientific foundation, and completely new technical foundation and engineering foundation are established, and a global intelligent integrated collaborative network computer system (CS/HSN (GII)) is built for a relatively closed and relatively static" resource pool "-cloud computing network with smart, intelligent and life injection, and the global internet is created into a technical support system with real life and ecological holographic collaborative organization properties. 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 technology 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 distributed in all the fields around the world, the global value chain system engineering is vigorously pursued, 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, namely the Licheng is called as a 'open the world' plan, the inventor transforms a neglectable 'cloud' computing system into a 'heaven and earth' computing system which can be communicated with everything and is communicated with longitude and latitude.
The invention mainly aims to provide an operating system design basis for a global Internet holographic cooperative system through a brand-new logic basis, a mathematic basis, a scientific basis and a brand-new technical basis and engineering basis.
All mathematical models referred to in the specification are basically independently established in the inventor's Lizhong, and have original innovativeness.
The invention belongs to the field of network technical support facing global value chain planning configuration, planning organization and planning management (PA/GVC), is an intelligent integrated technical foundation facing a global value chain and further facing a global value chain planning 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.
PA/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 global value chain planning and configuration internal and external association system 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 PA/GVC is global value chain configuration software integrating material resource configuration (logistics), human resource configuration (human flow), capital resource configuration (financial flow) and information resource configuration (information flow) aiming at the internal and external association of global value chain planning configuration. And describing next-generation longitudinal association departments, transverse association departments and Value Resource Planning (VRP) software by DIM analysis of a rule designer, a system integrator and a module generator which are oriented to the internal and external associations of the global value chain planning configuration and SHF analysis of final consumers, social regulation mechanisms and relatives at home and abroad which are oriented to the internal and external associations of the global value chain planning configuration. It will contain the global value chain planning configuration internal and external associated user/service system architecture, using graphical user interface, application open system production. In addition to the existing standard functions, it also includes other characteristics, such as the quality of the global value chain planning configuration internal and external associations, the process operation configuration, and the adjustment report of the global value chain planning configuration internal and external associations. In particular, the underlying technology employed by the PA/GVC will provide global value chain planning with both internal and external associated independence of both user software and hardware for easier upgrade. The key to PA/GVC is that all users associated inside and outside the global value chain planning 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, Lizong first proposed a concept report of PA/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 a multi-level multi-mode Value Chain System (VCS) is used as a core, the product value chain PVC and the global value chain GVC are used as a core, the industrial value chain IVC and the regional value chain RVC as well as the national value chain NVC and the global value chain GVC are used 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
(1) 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, insists on taking a global value chain system as a core, and establishes a general technical requirement and a scientific foundation for planning and configuring an operating system design 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 integrated system (HIIS).
The equipment resources and information resources of the internal and external systems planned and configured by the global value chain are distributed and scheduled by the holographic cooperative operation system according to the requirements of internal and external users planned and configured by the global value chain according to a certain strategy. The storage management of the holographic cooperative operation system is responsible for allocating the global value chain planning configuration internal and external storage units to the program needing to be stored so as to enable the program to be executed, and recovering the global value chain planning configuration internal and external storage units occupied by the program for reuse after the program is executed. For the inside and the outside of global value chain planning configuration which provides virtual storage and provides entity storage, the holographic cooperative operation system is matched with the inside and the outside hardware of the global value chain planning configuration to complete resource scheduling work, resources are allocated according to the requirements of inside and outside execution programs of the global value chain planning configuration, the resources are called into and out of the inside and the outside of the global value chain planning configuration, resources are recycled, and the like.
The global value chain planning configuration internal and external processor management or global value chain planning configuration internal and external processor scheduling is another important content of the resource management function of the holographic cooperative operation system. In a system that allows multiple programs to be executed simultaneously within and outside a global value chain planning configuration, a holographic co-operating system alternately allocates processors to programs waiting to run within and outside the global value chain planning configuration according to certain policies within and outside the global value chain planning configuration. A program that is waiting to run inside and outside a global value chain planning configuration can only be run after the processor is available. When a program inside and outside the global value chain planning configuration encounters a certain event in the running process, for example, the global value chain planning configuration inside and outside equipment is started and cannot continue to run temporarily, or an event occurs inside and outside the global value chain planning configuration, and the like, the holographic cooperative operation system needs to process the corresponding event, and then the global value chain planning configuration inside and outside processors are redistributed.
The equipment management function of the global value chain planning configuration holographic cooperative operation system mainly comprises the steps of distributing and recovering GVC planning configuration internal and external equipment, controlling the GVC planning configuration internal and external equipment to operate according to the requirements of user programs and the like. For GVC planning configuration internal and external non-storage type equipment, such as a printing device, a display device and the like, the equipment can be directly used as external equipment in the GVC planning configuration to be allocated to an external user program in the GVC planning configuration, and the equipment is recycled after being used so as to be used by another user with a requirement. For the storage type internal and external equipment for GVC planning configuration, if the main storage setting, the auxiliary storage setting, etc., a storage space is provided for external users for GVC planning configuration, and is used for storing external files and data for GVC planning configuration. The management of external storage type devices within the GVC plan configuration is closely coupled with the management of external information within the GVC plan configuration.
The GVC planning configuration internal and external information management is an important function of a holographic cooperative operation system, and is mainly used for providing a file system for external users in the GVC planning configuration. Generally, a GVC internal and external file system provides the user with the functions of creating GVC internal and external files, revoking GVC internal and external files, reading and writing GVC internal and external files, and opening and closing GVC internal and external files. With the external file system configured by the GVC schema, a user can access data under the external file name configured by the GVC schema without knowing where the data is stored. This is not only convenient for external users to use but also beneficial for external users to share common data. In addition, the GVC plan configuration allows a creator to specify the use authority when establishing the external files, so that the data security can be ensured.
The execution of external user programs within a GVC plan configuration is performed throughout under the control of the holographic co-operating system. After a program is written by a program in a program design language inside and outside the GVC planning configuration, the program and the requirements for executing the program are input to the inside and outside of the GVC planning configuration, and the holographic cooperative operation system controls the program of the outside and inside user of the GVC planning configuration to be executed until the end according to the requirements. The holographic cooperative operating system controls the execution of external users and internal users in the GVC planning configuration, and mainly comprises the following contents: calling a corresponding internal and external compiler for GVC planning configuration, compiling a source program written by a certain internal and external programming language for the GVC planning configuration into an external executable target program for the GVC planning configuration, allocating resources such as internal and external storage for the GVC planning configuration, calling the program into the internal and external storage for the GVC planning configuration, starting the internal and external storage, and processing various events in execution and processing unexpected events related to operator contact request according to the requirements specified by internal and external users for the GVC planning configuration.
The global value chain planning and configuration holographic cooperative operation system internal and external man-machine interaction function is an important factor for determining the 'friendliness' of the global value chain planning and configuration internal and external. The GVC planning configuration internal and external man-machine interaction function is mainly completed by internal and external GVC planning configuration equipment capable of inputting and outputting and corresponding software. The equipment for GVC planning configuration internal and external man-machine interaction mainly comprises a GVC planning configuration internal and external display device, a GVC planning configuration internal and external shortcut operation tool, a GVC planning configuration internal and external various mode identification equipment and the like. The software corresponding to the devices is the part of the holographic cooperative operation system for providing the external human-computer interaction function in the GVC planning configuration. The main function of the external human-computer interaction part in the GVC planning configuration is to control the operation and understanding of external related equipment in the GVC planning configuration and execute various related commands and requirements transmitted by the external human-computer interaction equipment in the GVC planning configuration. The GVC plan configures an external operator to type in a command through a keyboard, and the holographic cooperative operation system executes the command immediately after receiving the command and displays the result through a display. With the development of external technologies in GVC planning configuration, more and more operation commands are required, and the functions are stronger and stronger. With the development of input devices for pattern recognition, such as speech recognition, chinese character recognition, etc., GVC programming has become possible to configure external operators and various devices and tools to interact at a level similar to natural language or restricted natural language. Furthermore, the human-computer interaction inside and outside the GVC planning configuration by graphics is also attracting research. The GVC planning configuration internal and external human-machine interaction can be called intelligent integrated GVC planning configuration internal and external human-machine interaction. The research work in this respect is to be further developed.
The global value chain planning configuration holographic cooperative operation system is positioned between the user planning configuration internal and external bottom layer hardware and the user and is a bridge for communication between the internal and external bottom layer hardware and the user. GVC planning configurations external and internal users may enter commands through the user interface of the holographic co-operating system. The holographic cooperative operation system interprets the GVC planning configuration internal and external commands, drives the GVC planning configuration internal and external hardware equipment, and realizes the user requirements. From a completely new perspective, a standard GVC program configures the OS/HSO of internal and external systems to provide the following functions:
GVC planning configuration internal and external Process management (Processing management/HSO [ GVC ])
GVC plan configuration internal and external Memory space management (Memory management/HSO GVC)
GVC plans configuration of internal and external File systems (File system/HSO [ GVC ])
GVC plans configuration of internal and external communication (Networking/HSO GVC)
GVC plans to configure internal and external Security mechanisms (Security/HSO GVC)
GVC configuration internal and external User interface (User interface/HSO GVC)
GVC configures internal and external drivers (Device drivers/HSO GVC)
Whether the GVC programs are external resident programs or external application programs, the GVC programs are used for configuring external processes and internal processes as standard execution units. GVC planning configures each central processor external to the configuration is not limited to executing one process at a time. The holographic cooperative operation system can utilize the GVC to plan and configure the internal and external multi-process (multitask/HSO [ GVC ]) function to execute complex processes at the same time even if the holographic cooperative operation system only has one CPU/HSO [ GVC ]. The GVC plans and configures internal and external process management refers to a function of adjusting the GVC plans and configures the internal and external complex processes by a holographic cooperative operating system.
Between the general philosophy Ontology category (Ontology) and the information science and technology Ontology term (Ontology), the inventor proposes to re-interpret the Ontology category or concept (O/Ontology, abbreviated as O-ont) between the whole and part of things, and uses the Ontology category or concept as a logical node reflecting the coordination and unification of the whole and part of things as a basic link between the general philosophy category and the information science and technology term.
Based on this, we can attribute the various unifications being explored by modern science to three different levels of unification:
the first level of uniformity UI is an Ontology Uniformity (OU) that approximates the primitive of an object. This specification defines such uniformity as the coordination and uniformity embodied between the whole (W) and the part (P) of a thing, as shown in fig. 1.
The second level of uniformity UII is a Holographic Uniformity (HU) facing system internal and external collaborative relationships. This specification defines this unity as the coordination and unification embodied between the Internal Holographic Synergistic Relationship (IHSR) and the External Holographic Synergistic Relationship (EHSR) of the system. Here, the internal holographic cooperativity relationship between the system and its subsystems and base elements is considered on the one hand, and the external holographic cooperativity relationship between the system and its surroundings and external indirection factors is considered on the other hand, as shown in fig. 2.
The third level of uniformity UIII is the Holographic Evolutionary Uniformity (HEU) throughout the evolution process of the complex system. This unity is defined herein as the coordination and unification embodied from time to time throughout the evolution of a complex system from low-level (E I) to high-level (EN). Here, the inter-holographic cooperation relationship (IHSR), the inter-holographic cooperation relationship (EHSR), and the coordination (H/IE) between the inter-and outer holographic cooperation relationships of the complex system are very organization factors of the evolution of the complex system, as shown in fig. 3.
The relationships between intelligent integration elements are the basic intelligent integration semantics. In the analysis oriented to intelligent integration, there are two types of relationships between elements: one is the relationship of elements in the structure of the intelligent integrated system; the other is the relationship of elements in completing the functions of the intelligent integrated system.
The relationship of elements on the intelligent integrated structure has one-to-one, one-to-many and many-to-many situations. For the first two cases, as shown in fig. 4, only one relationship element needs to be identified, the relationship element has direct connection with multiple parties in the relationship element, and is in one-to-one correspondence with the other party in terms of element generation, and all the connected elements are attributes of the relationship element; the relationship element is required to perform at least some of the following operations: (A) An operation of obtaining all the factor 2 which can possibly be connected with the factor l; (B) An operation of relating the related elements; (C) And an operation of releasing the relation of the related elements.
For many-to-many cases, such as the relationship between a configurator and a resource element, the association is achieved by defining the configuration and being configured with two relationship elements, as shown in FIG. 5.
In a system analysis oriented to global value chain planning configuration, elements are data and packages that act on the data to operate on. In the development of the global value chain planning and configuration system, the analysis model is a key model of the global value chain planning and configuration system. This should reflect both the structural and behavioral aspects of the global value chain planning and configuration system, whose functions are implemented through the manipulation of elements. As can be seen from the identification of the elements needing to be analyzed by the global value chain planning and configuration main body, the identification of element operation and the identification of the elements are carried out simultaneously, and each function of the global value chain planning and configuration system is realized by the operation of the corresponding element. The global value chain planning configuration elements generally comprise information which is stable for a long time in a global value chain planning configuration system and operation for processing the information.
The global value chain planning and configuration process, although having specific rules and characteristics, can be formally equivalent to an "actual problem solving" process under certain conditions. The "problem" at this point is a exploited abstraction that represents some discrepancy between the current state of a given process and the target state required by the global value chain planning configuration body. The practical solution is to virtually eliminate this difference. Any global value chain planning configuration process can be expressed as a practical problem solving process as long as appropriate state description and process description are given, namely correct formal description is established.
The process by which system L learns to solve problem A can be expressed as system S' solving problem B:
initial state: system S does not solve problem a.
Target state: system S will solve problem a.
If a system S' is found that solves the problem B, the system L learns to solve the problem A. The key here is to establish some correct formalized description of the global value chain planning configuration activity process that solves the problem.
In general, there are many equivalent representations of any given problem. A powerful representation gives a strong clarity to the problem and makes it easier to solve it. For an original problem which is not abstracted, the original problem often contains a lot of redundant information which is irrelevant to the problem solving, and the problem can be simply represented only by removing the redundant information and reserving the useful information which is necessary for solving the problem. The method of extracting useful information is different, and the obtained problem representation is also different.
Discrete mathematics has two concepts, homomorphism and isomorphism, the former can simplify the representation of a problem, and the latter can change the representation of a problem, but they are all mappings that maintain the operational characteristics. Is provided with two problems
P = < Q,F >AndP′= < Q′,F ′ >,
whereinQAndQ' is respectively a problemPAndPthe set of facts that may occur in (1),FandF ' respectively areQAndQ' if there is a full map
So as to be coupled to any sequence
If and only if sequence pair
I.e. byFAndF there is also a full mapping between
Then callP' isPIs calledPIs thatP' original problem, callhIs fromPToPHomomorphic mapping of' is denoted。
If it is nothIf the mapping is a one-to-full mapping, an isomorphic mapping is obtained. Isomorphic mapping is a special case of homomorphic mapping, denoted as
Figure 6 presents an internal relationship problem for a global value chain planning configuration organization. In this relationship, the decision-maker consists of two base members (F and M) and the executive consists of three base members (B, S and J). This is a homomorphic transformation of the actual organizational internal relationships because much of the detail is omitted. However: (a) The graph correctly describes the internal relationship of the global value chain planning configuration organization at a certain depth. (b) The graph is a further abstraction of the global value chain planning configuration subject internal relationships, which ignores relationships between members of the global value chain planning configuration subject internal, due to the existence of a full map
The following full mapping holds true for the binary relationships in the two systems
Therefore (b) Is shown in (A)a ) The homomorphism of the graph reflects the original relation in the global value chain planning configuration organization to a certain extent.
Homomorphic mapping is a partial ordering relationship that satisfies transitivity, so (1)c) The figure is also (a) Homomorphism of the graph.
In global value chain planning configuration logic, the effect of causing certain components in a state to change, thereby causing a problem to change from one particular state to another, may be referred to as an operation, which may be a mechanical step, process, rule, or operator. Operations describe relationships between states.
The State Space (State Space) of a problem is a graph that represents all possible states of the problem and their interrelations. Generally, a directed graph of assignments is provided, which contains a detailed description of the following three aspects:
S : a set of initial states that may be in the problem;
F : a set of operations;G : a set of target states;
the state space is often denoted as a triplet (S , F , G )。
In state space representation, the problem solving process is converted into finding the initial state in the graph s QDeparture to destination state g QI.e. finding a sequence of operationsαTo a problem of (a). Therefore, the solution in the state space is also often denoted as a triplet: ( s Q, α, g Q) Which comprisesThe following three aspects are explained in detail:
s Q: a certain initial state; g Q: a certain target state;α: handle s QIs converted into g QA limited sequence of operations.
If it is notα= f l , f 2 , …, n f Then there is
g Q= n f ( ∙∙∙ ( f 2 ( f l ( s Q))) … )。
The PA/GVC to be vigorously developed and established is information integration oriented to global Value Chain Planning Operation (Planning Operation of Enterprise Value Chain), and the PA/IVC is information integration oriented to Supply and demand Chain Planning Operation (Planning Operation of Supply Chain). In addition to the manufacturing, marketing, financial project functions and various support systems and technologies of the PA/IVC system, the PA/GVC combines longitudinally and transversely related products, projects and fields in the global value chain, and has a series of brand new technologies as follows:
information and Communication Technology (ICT) support design for 381 th global value chain planning and configuration mechanism
Information and Communication Technology (ICT) support design of 382 th global value chain planning configuration unit
ICT technical support design for 383 th global value chain planning configuration dynamic foundation
ICT technical support design for comparing advantages of 384 global value chain planning configuration
ICT technical support design for 385 th global value chain planning configuration holographic collaboration
Information Communication Technology (ICT) support design for 386 global value chain planning configuration production function
ICT technical support design for value measurement of global value chain planning configuration of item 387
Information and Communication Technology (ICT) technical support design for 388 global value chain planning configuration collaborative organization
389 global value chain planning configuration holographic hedging equalization technology foundation
390 th global value chain planning configuration holographic hedging balance tabulation technology
ICT technical support design of 391 global value chain planning configuration main body
Information Communication Technology (ICT) support design for planning and configuring load of 392 global value chain
ICT technical support design for 393 global value chain planning configuration mode
Information and Communication Technology (ICT) support design for 394 th global value chain planning and configuration system
Information and Communication Technology (ICT) support design for 395 th global value chain planning configuration environment
ICT technical support design for 396 global value chain planning configuration engineering
ICT technical support foundation of 397 th global value chain planning configuration justice system
Calculation technology foundation of 398 (th) intelligent integrated system for global value chain planning and configuration
399 th intelligent integrated operating system technology base for global value chain planning configuration
400 th global value chain planning configuration intelligent integrated dynamic convergence technical foundation
(2) For a global value chain, the inventor establishes a whole design framework of a planning configuration operating system and a basic composition assumption on the basis of 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 independently, in order to modify a neglected and uncertain 'cloud' computing system into a 'heaven and earth' computing system which is communicated with all things and passes through longitude and latitude, insists on taking a global value chain system as a core, and 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 main line of an evolution process of a high-level intelligent integration system (HIIS).
The global value chain planning configuration technology to be vigorously developed and established is a global value chain-oriented planning operation mode, a global value chain-oriented planning information system and a global value chain-oriented commercial software product. The method is formed by comprehensively improving and expanding an enterprise efficacy chain planning and configuration technology PA/GVC and a business value chain planning and configuration technology PA/IVC through an intelligent integrated dynamic communication network on the basis of a resource configuration dynamics, a holographic organization synergetics, a system efficacy value theory, a hedging balance economy, a game organization synergetics and an economic system engineering intelligent integrated configuration principle. This section mainly sets forth the theory of global value chain planning configuration, project implementation methods and roles in modern global value chain configuration. The application process and the final achieved effect of global value chain planning configuration in modern global value chain configuration are indicated from various aspects of global value chain software model selection, project implementation, configuration mode improvement, configuration system improvement, flow and operation specification solidification and the like.
In a broad sense, materials, funds and values in the efficacy chain are reflected to people in an information mode. The global value chain planning and configuration system is just by means of a modern information technology and a global intelligent integrated communication network information technology and an operation system, information flows related to the inside and the outside of global value chain planning and configuration on an efficacy chain are obtained, analyzed and processed, global value chain resources are effectively controlled and utilized, the resource configuration is more reasonable, satisfactory products and services are provided for clients at the fastest speed and the lowest cost, and accordingly, the global value chain organization creates profits and values for the clients while providing products and services for the clients.
(2.1) core and features of Global value chain planning configuration
The global value chain planning configuration is a configuration method which takes an efficacy chain thought as a core, takes resource configuration dynamics, a system efficacy value theory, hedge balance economics and game organization synergetics as bases, and applies modern latest information technology and global intelligent integration converged network information technology and an operation system. The method is developed on the basis of an application information technology configuration system, namely NA/IVC planning by GVC.
Holographic convergence and holographic integration of information are the most important features of global value chain planning configurations. The global value chain planning configuration carries out holographic collaborative system engineering on all departments, projects and links related to the inside and the outside of the global value chain planning configuration on an efficacy chain, including suppliers, manufacturers and other partners, according to the requirements of customers and markets, and guarantees that products and services related to the inside and the outside of the global value chain planning configuration can be guaranteed to be delivered to customers on time; meanwhile, the global value chain planning configuration integrates the resources divided by blocks under the traditional configuration condition again according to the idea of flow configuration, supports the integration or organization of a project flow (carrying flow) dynamic model and an information processing program which are related inside and outside the global value chain planning configuration, provides an assembly type software product to solve the solution of specialization and individuation by applying an object-oriented and component (or member) development technology, supports the configuration requirements of various departments, projects and links related inside and outside the global value chain planning configuration, and achieves the optimal configuration of the resources of the whole global value chain (efficacy chain). Therefore, the core of global value chain planning configuration is holographic convergence and holographic integration of global value chain configuration information.
The global value chain planning configuration is an effective way for informatization transformation of the traditional global value chain, and the configuration concept and idea of the global value chain planning configuration are crystals of a plurality of interest-related organizations and personal intelligence. For example, the global value chain planning configuration internal and external associated configuration information is complete, accurate, timely and unique, the global value chain planning configuration internal and external associated logistics, fund flow and information flow synchronization, the global value chain planning configuration internal and external associated balance and coordination of production, supply and marketing, the grasp of market demand change and the like are all very concerned problems by global value chain leaders, and the global value chain planning configuration internal and external associated logistics, fund flow and information flow synchronization cannot be realized by the traditional configuration method and means.
(2.2) GVC planning configuration holographic cooperative operation system Overall design
The GVC planning configuration holographic cooperative operating system (OS/HSO [ GVC ]) developed and established by the present inventor is a huge GVC planning configuration internal and external management control program, and roughly includes 5 management functions: GVC planning configuration internal and external process and processor management, GVC planning configuration internal and external operation management, GVC planning configuration internal and external storage management, GVC planning configuration internal and external equipment management and GVC planning configuration internal and external file management. The common operating systems DOS, OS/2, UNIX, XENIX, LINUX, Windows, Netware and the like on the current microcomputer are transformed into a GVC planning configuration holographic cooperative operating system DOS/HSO [ GVC ], OS/2/HSO [ GVC ], UNIX/HSO [ GVC ], XENIX/HSO [ GVC ], LINUX/HSO [ GVC ], Windows/HSO [ GVC ], Netware/HSO [ GVC ] and the like.
The GVC plan configuration holographic cooperative operation system is a set of system software that controls the GVC plan configuration internal and external programs to run, manages GVC plan configuration internal and external system resources, and provides an operation interface for the GVC plan configuration internal and external users, as shown in fig. 7.
The GVC planning configuration holographic cooperative operation system is responsible for basic tasks such as internal and external management and configuration memories of GVC planning configuration, determination of the priority of the resource supply and demand of the external and internal systems of the GVC planning configuration, control of internal and external input and output equipment of the GVC planning configuration, operation of internal and external networks of the GVC planning configuration, management of a file system and the like.
The GVC planning configuration holographic cooperative operation system manages all hardware resources, software resources and data resources of external systems in the GVC planning configuration; controlling the GVC to plan and configure the operation of an internal program and an external program; improving the internal and external human-computer interfaces of the GVC planning configuration; support is provided for GVC planning and configuration of internal and external application software, all resources of the internal and external systems are enabled to play a role to the maximum extent, and a convenient, effective and friendly service interface is provided for GVC planning and configuration of internal and external users.
All the global virtual machine (GVC) planning configuration holographic cooperative operation systems have four basic characteristics of internal and external concurrency of GVC planning configuration, internal and external sharing of GVC planning configuration, internal and external cooperativity of GVC planning configuration and internal and external uncertainty of GVC planning configuration.
The types of the GVC planning configuration holographic cooperative operation system are very various, the OS/HSO [ GVC ] installed by different machines can be from simple to complex, and the GVC planning configuration holographic cooperative operation system can be from an embedded system inside and outside the GVC planning configuration to a large GVC planning configuration holographic cooperative operation system inside and outside the GVC planning configuration.
In addition to the GVC configuration internal and external process management, OS/HSO [ GVC ] has the serious problems of initiating GVC configuration internal and external inter-process communication (IPC/HSO [ GVC ]), GVC configuration internal and external process abnormal termination processing, Dead knot (Dead lock) detection and processing, and the like.
There are thread problems under the external processes in the GVC plan configuration, but most of the OS/HSO [ GVC ] does not deal with the problems encountered by the external threads in the GVC plan configuration, and usually the OS/HSO [ GVC ] only provides a set of API/HSO [ GVC ] to let the external users in the GVC plan configuration operate by themselves or to control the interaction between the external threads in the GVC plan configuration through the management mechanism of the virtual-physical devices and tools.
Another important activity of external storage management within GVC planning configurations is to manage virtual-physical locations with the help of CPU/HSO [ GVC ]. If there are many processes stored on the memory device simultaneously inside and outside the GVC plan configuration, the GVC plan configuration holographic co-operating system must prevent them from interfering with each other's memory contents (unless operating under a controlled range via some protocol and restricting the accessible GVC plan configuration internal and external memory range). Partitioning the external storage space within the GVC plan configuration can achieve the goal: each process inside and outside the GVC program configuration will only see that the entire memory space (from 0 to the maximum upper limit of the external memory space inside and outside the GVC program configuration) is configured to itself (of course, some locations are reserved by OS/HSO [ GVC ] and are prohibited from being accessed).
The theory of the GVC plan configuration holographic cooperative operation system to be explored and established is a brand new branch beyond information science and computer science, and the design and implementation of the GVC plan configuration holographic cooperative operation system is the basis and kernel of the external software industry in GVC plan configuration, as shown in fig. 8.
The basic structure of the theory of the GVC planning configuration holographic cooperative operation system is as follows:
I. GVC planning configuration holographic cooperative operation system introduction theory
I.1 GVC plans to configure internal and external hardware structures
I.1.1 GVC Provisioning internal and external processors
I.1.2 GVC Provisioning internal and external memory
I.1.3 GVC Provisioning internal and external I/O devices
I.1.4 bus
I.2 what is the GVC plan configuration holographic co-operating System
I.2.1 GVC planning configuration holographic co-operating system concept
I.2.2 GVC Provisioning Primary Functions of a holographic Co-operating System
I.2.3 GVC plans the position of configuring the holographic cooperative operation system
Development prospect of I.3 GVC planning configuration holographic cooperative operation system
I.3.1 GVC Provisioning the formation of a holographic Co-operating System
Development of I.3.2 GVC planning configuration holographic cooperative operation system
I.3.3 Power for promoting development of GVC planning configuration holographic cooperative operation system
I.4 GVC plan configuring type of holographic co-operating system
I.4.1 GVC planning configuration internal and external batch processing system
I.4.2 GVC planning and configuring internal and external parts of system
I.4.3 GVC planning and configuring internal and external real-time system
I.4.4 holographic cooperative network operation system
I.4.5 holographic cooperative distributed operation system
I.4.6 other GVC planning configuration holographic cooperative operation system
I.5 GVC Provisioning features of a holographic Co-operating System
I.6 GVC planning configuration holographic cooperative operation system structure design
I.6.1 monolithic Structure
I.6.2 hierarchy
I.6.3 virtual machine architecture
I.6.4 client, Server architecture
GVC plans configuring internal and external processes and threads
II.1 GVC planning and configuration of internal and external Process concepts
II.1.1 GVC planning configuration internal and external multi-channel programming
II.1.2 GVC planning and configuring internal and external process concepts
II.2 GVC plans configuring the State and composition of internal and external Processes
II.2.1 GVC plans configuring the states of internal and external processes and their transitions
II.2.2 GVC planning configuration internal and external Process descriptions
II.2.3 GVC plan configuration of internal and external process queues
II.3 GVC planning configuration internal and external Process management
II.3.1 GVC planning and configuring internal and external process maps
II.3.2 GVC planning configuration internal and external Process creation
II, 3.3 GVC Provisioning internal and external Process terminations
II, 3.4 GVC Provisioning internal and external Process blocking
II, 3.5 GVC plan configuration internal and external process wakeup
II, 4 GVC plans configuring internal and external threads
II, 4.1 GVC Provisioning internal and external thread concepts
II, 4.2 GVC plan configuration implementation of internal and external threads
II, 5 GVC plans the synchronization and communication of configuration internal and external processes
II, 5.1 GVC plans to configure synchronization and mutual exclusion of internal and external processes
II, 5.2 GVC plans to allocate internal and external critical resources and critical sections
II, 5.3 GVC plan configuration internal and external mutual exclusion implementation mode
II, 5.4 GVC plan configuration of internal and external semaphores
General application of II, 5.5 GVC planning to configure internal and external semaphores
II, 6 GVC planning and configuring internal and external classical process synchronization problem
II, 7 GVC plan configuration of internal and external tube side
II, 8 GVC plan configuration internal and external process communication
II, 8.1 GVC planning configuration internal and external transmission system
Communication in a II, 8.2 client-server system
GVC planning configuration internal and external deadlocks
III, 1 GVC plan configuration of internal and external resources
III, 1.1 GVC plan configuration internal and external resource use mode
III, 1.2 GVC Provisioning internal and external revocable resources and non-revocable resources
III, 2 GVC planning configuration internal and external deadlocks
III, 2.2 GVC plan configuration of conditions for internal and external deadlocks
III, 2.3 GVC plan configuration internal and external resource allocation map
…………
GVC planning configuration internal and external scheduling
External storage management within V, GVC planning configuration
GVC planning and configuring internal and external file system
GVC planning configuration internal and external input/output management
GVC planning configuration of internal and external user interface services
IX. holographic cooperative operation system for embedded GVC planning and configuration
X-distributed GVC planning configuration holographic cooperative operation system
XI GVC planning configuration of internal and external security and protection mechanisms
Case study 1: UNIX/HSO [ GVC ]
Example study 2: Linux/HSO [ GVC ]
Xiv, example study 3: windows 2000/HSO [ GVC ]
Practical operation
(A2) Several typical GVC planning configuration holographic cooperative operation system architectures
The existing operating systems are improved and expanded easily to form a global virtual component coordination (GVC) planning configuration holographic operating system facing to the whole resource communication network.
(a)Linux / HSO [ GVC ]Framework
It is known that, besides the proud portability (compared with Linux, MS-DOS can only run on Intel CPU), Linux is also a time-sharing multiprocess kernel and has good memory space management (ordinary processes cannot access the memory in the kernel area). A process that wants to access any non-own memory space can only be achieved through system calls. The general process is under User mode, and the execution system is called by the system and is switched to Kernel mode, all special instructions can be executed only in Kernel mode, this measure makes the Kernel able to perfectly manage the internal and external devices of the system, and refuses the request of the process without permission. Therefore, theoretically, any application execution error cannot cause system Crash (Crash).
The almost complete Linux/HSO [ GVC ] architecture is as follows:
GVC configures internal and external user modes
GVC configures internal and external application programs (sh/HSO [ GVC ], vi/HSO [ GVC ], Open office. org/HSO [ GVC ], etc.)
GVC plans and configures internal and external complex function libraries (KDE/HSO [ GVC ], glib/HSO [ GVC ], etc.)
GVC plan configuration internal and external simple function libraries (openndbm/HSO [ GVC ], sin/HSO [ GVC ], etc.)
GVC planning configuration of internal and external C function libraries
(open/HSO [ GVC ], fopen/HSO [ GVC ], socket/HSO [ GVC ], exec/HSO [ GVC ], calloc/HSO [ GVC ], etc.)
Holographic cooperative organization core mode
GVC plans and configures software and hardware messages of internal and external system interruption, call, error and the like
GVC plans configuration of internal and external cores (GVC plans configuration of internal and external drivers, processes, networks, memory management, etc.)
GVC plans configuration of internal and external hardware (GVC plans configuration of internal and external processors, memories, various devices)
(b)Windows NT / HSO [ GVC ]The architecture of the system:
above the external hardware level in the GVC plan configuration, there is a hardware abstraction layer (HAL/HSO GVC) that is directly contacted by the microkernel, while the external drivers in the different GVC plan configuration are installed in modules and executed on the kernel. The microkernel can use functions such as external input and output, file systems, networks, information security mechanisms, and virtual memory within the GVC schema configuration. And the GVC planning configuration internal and external system service layer provides all function call libraries with uniform specification, and can unify all operation methods of the GVC planning configuration internal and external auxiliary systems. For example, although POSIX and OS/2/HSO [ GVC ] differ greatly with respect to the name and calling method of the same service, they can operate as well on the external system service layer within the GVC planning configuration. The sub-systems above the GVC within and outside system service layer are all the GVC within and outside user mode, so that the illegal action of the GVC within and outside user program can be avoided.
Simplified version of Windows NT/HSO [ GVC ] abstract architecture
GVC plans to configure internal and external users
Holographic synergetic organization mode OS/2/HSO [ GVC ]
GVC plans to configure internal and external application programs Win 32/HSO [ GVC ]
GVC plans configure internal and external applications DOS/HSO [ GVC ]
GVC plans configure internal and external programs Win 16/HSO [ GVC ]
GVC plans to configure internal and external applications POSIX/HSO [ GVC ]
GVC planning configuration of internal and external applications
GVC planning configuration internal and external other DLL function library DOS/HSO [ GVC ] system Windows simulation system
OS/2/HSO [ GVC ] subsystem Win32 subsystem POSIX.1/HSO [ GVC ] subsystem
GVC planning configuration of internal and external cores
Holographic collaborative organization mode and system service layer
GVC planning configuration internal and external input-output management
GVC plans to configure internal and external file systems, GVC plans to configure internal and external system object management system/GVC plans to configure internal and external security management system/GVC plans to configure internal and external process management/GVC plans to configure internal and external inter-object communication management/GVC plans to configure internal and external inter-process communication management/GVC plans to configure internal and external storage management
GVC plans to configure internal and external micro-kernels and window management procedures
GVC plans configure internal and external drivers, hardware abstraction layer (HAL/HSO [ GVC ]) and graphics drivers
GVC plans configuration of internal and external hardware (GVC plans configuration of internal and external processors, memories, external devices, etc.)
GVC planning configuration internal and external auxiliary system architecture
The first GVC plan configures the internal and external operating auxiliary system group as DOS/HSO [ GVC ] auxiliary system, which executes each DOS/HSO [ GVC ] program as an internal and external process of GVC plan configuration, and uses individual independent MS-DOS/HSO [ GVC ] virtual machine to bear its running environment.
The other is a Windows 3.1/HSO GVC simulation system, which actually executes the Win16 program under the Win32 subsystem. Thus, the capability of safely mastering the procedures written for MS-DOS and Windows/HSO GVC systems is achieved. However, this architecture only operates on the Intel 80386/HSO [ GVC ] processor and successor models. Moreover, some programs that directly read the external hardware in the GVC program configuration, such as most Win 16/HSO [ GVC ] games, cannot apply the system, so many early games cannot be executed on Windows NT/HSO [ GVC ].
(3) For a global value chain, the inventor establishes an engineering technical scheme for planning and configuring an operating system design 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 integrated system (HIIS) and taking a global value chain system as a core in order to modify a neglected and indefinite '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 mathematic foundation, a brand-new scientific foundation and a brand-new technical foundation and a brand-new engineering foundation.
A brute force search based on a full state space faces the serious threat of combinatorial explosion and can only cooperate effectively in very small problems. Various basic heuristic search strategies can reduce the speed of combined explosion and improve the search efficiency. However, in larger problems, due to the large gill length, the problem of combinatorial explosion is still serious, and the speed of combinatorial explosion can be further reduced by planning and multi-layer planning.
Planning is the development of problem resolution techniques (key state methods and key operations) that can significantly slow the rate of combinatorial explosion.
During the problem solving process, planning can enable us to have a rough step of solving the problem before the details are deepened, so that the combinatorial explosion in blind search is reduced. However, in the process of solving complex problems, detailed plans are often not completely proposed at a time, only a general rough assumption can be initially proposed, and then the general rough assumption is gradually refined, and more detailed considerations are added to each refinement until the detailed plans are obtained.
The multi-level planning method is a multi-level planning, which generates a planning hierarchy:
the coarsest plan is at the top level and the most exhaustive plan is at the bottom level. Resulting in a tree, each level of which corresponds to one refinement of the plan, as shown in fig. 9.
Each refinement of the plan can be represented by a process network (procedural Nets).
The global value chain planning configuration result is the result of the mutual connection and interaction of various factors. These factors, however, can be divided into five areas: a global value chain planning configuration agent; a global value chain planning configuration broker; a global value chain plan configuration object; a global value chain planning configuration basis; a global value chain planning configuration environment. Therefore, a hierarchical structure model of the global value chain planning configuration relation can be established.
Suppose a global value chain planning and configuration system hasnAnd (can be summarized into five aspects). By comparing pairwise impact factors of global value chain planning configuration results and according to relative importance between the two impact factors, we can listn×nAn order matrix, which is a decision matrix of the form:
each sub-object has a decision matrix.
The hierarchical single ordering of the importance degree of each hierarchical influence factor can be summarized as the problem of solving the eigenvalue and eigenvector of a judgment matrix:
wherein,
λ max for the largest root of the features of the matrix,
Wto correspond toλ max Normalized feature vectors of (a);
Wcomponent (b) of i WWeights for the single ordering of the respective factors.
In order to maintain consistency, the matrix is also checked for consistency:
( 2. 260 )
if the check is not satisfied, the matrix needs to be adjusted:
。
table 2.17 shows the values of RI.
TABLE 2.17
RI 0.00 0.00 0.58 0.90 1.12 1.24 1.32 1.41 1.45
Assuming that the first layer factor weight obtained in the previous step is from big to small i a ( i = l, 2, …, n) The second layer is j b ( j = l, 2, …, m) … …. And sequentially drawing the influencing factors on the graph according to a program from left to right, from top to bottom and from large to small, and marking the relative single ordering weight of each factor to obtain the global value chain planning configuration causal analysis graph.
Let us take as an example an operational procedure of an internet basic organization. The hierarchy of operational factors is shown in FIG. 10.
In the global value chain planning and configuration logic, a basic analysis is tonItem activityA l , A 2 , …, n A And (6) sorting. Typically, this needs to be taken into account during the sorting processnThe interaction between item activities. The specific consideration method is as follows:
to this according to a value criterion predetermined by the decision makernItem activities are initially ordered;
according to thisnDetermining a relative importance coefficient of each activity according to the mutual influence relation among the activities;
and correcting the preliminary sequencing result by using the relative importance coefficient of each activity.
Since this is the casenCorrelation matrix is available for the interaction between item activitiesRTo describe:
wherein,γ ij is shown asiItem activity is rightjThe dominating relationship of an item activity, accordingly,γ ji then it indicates thatjItem activity is rightiThe dominance of the item activity, and the following relationships:
γ ij ≠γ ji ,0≤γ ij ≤1
when it comes toiItem activity is firstjWhen the item activity is not affected by the item activity,γ ij = 0。
to determine a correlation matrixRCan we herenSelecting one of the activities k A As a reference point, and using a scale of 1-9 (see table 2.19), the activities were compared pairwise to determine which activity was relative to the reference point k A The degree of dominance is greater, most of them less. For thenItem activity, a pairwise comparison and judgment matrix can be obtainedA k( ) :
Wherein, ija > 0, ija = l / ji a, jia = l 。
TABLE 2.19 Scale meanings
1 indicates that the two elements have the same importance compared
3 indicates that one element is slightly more important than another element
5 indicates that one element is significantly more important than another element
7 indicates that one element is slightly more important than the other element
9 indicates that one element is slightly more important than another element
2, 4, 6, 8 is the median of the above adjacent judgments
Judgment matrixA k( ) The maximum feature root and the corresponding feature vector have the following relations:
wherein
Is composed ofA k( ) The root of the largest feature of (c),
is composed of
The corresponding feature vector, and
> 0。
feature vector
Can be expanded to:
where vector 0 is used to represent those pairs of activities k A Activity pairs without influencing relationships k A Degree of dominance of. Formula (2.264)
The following can be written:
wherein≥ 0。
By repeating the above steps, we can obtainnAn vector to
, , …, , …, . This is achieved bynThe vectors form a correlation matrixR ,
R = [
, 
, …, , …, ] ( 2. 266 )
In the incidence matrixROnce determined, we can discuss the determination of the relative contribution rate and relative location of each activity.
Definable activities k A Relative contribution rate of k RD Is the activity of k A The ratio of the amount of output information to the amount of input information.
Movement of k A The amount of output information of (a) can reflect that the activity dominates all other activities. If it is active k A To pairqItem activity jA 1, jA 2 ,…, jq A Has an influence on this, and it has an influence on thisqThe dominance degree of the item activity is sequentiallyγ k j, 1 ,γ k j, 2 ,…,γ k jq , Then it is determined that,is just about to move k A The amount of output information of (1).
Movement of k A The amount of input information can reflect the situation that the activity is subject to all other activities. If it is active k A ReceivingpItem activity i A 1, iA 2 ,…, ip A And the degree of dominance of each activity on it is in turnγ i k1, ,γ i k2, ,…,γ iq k , Then, then
Is just an activity k A The amount of input information.
Thus, move about k A Relative contribution rate of k RK Can be given by:
movement of k A And a reference point ( b A ) Relative position of (A), (B) k RP) Can be defined as from a reference point b A By the most intense way-to-way activity k A Degree of dominance (this is, of course, not the only definition). When determining the relative position of an activity, the correlation matrix can be usedRReverting to directed graphD (ii) a Each activity i A As a drawingDNode of (1), matrixRArc in (1) as a graphDMiddle arc ( i A , j A ) The weight of (c).
From relative contribution rate k RD And relative position k RP Easy determination of activities k A Relative importance coefficient of k w Namely:
k w = f ( k RD , k RP ) ( 2. 268 )
and satisfies the following conditions:
condition 1: ( 2. 269 )
condition 2: k
w = f ( β∙ k RD ,β∙ k
RP ) = k w =β∙ f ( k
RD , k RP ) ( 2. 270 )
4. description of the drawings
Fig. 1, 2 and 3 illustrate:
we can attribute the various unifications we are exploring in modern science to three different levels of unification:
the first level of uniformity UI is an Ontology Uniformity (OU) that approximates the primitive of an object. This specification defines such uniformity as the coordination and uniformity embodied between the whole (W) and the part (P) of a thing, as shown in fig. 1.
The second level of uniformity UII is a Holographic Uniformity (HU) facing system internal and external collaborative relationships. This specification defines this unity as the coordination and unification embodied between the Internal Holographic Synergistic Relationship (IHSR) and the External Holographic Synergistic Relationship (EHSR) of the system. Here, the internal holographic cooperativity relationship between the system and its subsystems and base elements is considered on the one hand, and the external holographic cooperativity relationship between the system and its surroundings and external indirection factors is considered on the other hand, as shown in fig. 2.
The third level of uniformity UIII is the Holographic Evolutionary Uniformity (HEU) throughout the evolution process of the complex system. This unity is defined herein as the coordination and unification embodied from time to time throughout the evolution of a complex system from low-level (E I) to high-level (EN). Here, the inter-holographic cooperation relationship (IHSR), the inter-holographic cooperation relationship (EHSR), and the coordination (H/IE) between the inter-and outer holographic cooperation relationships of the complex system are very organization factors of the evolution of the complex system, as shown in fig. 3.
Fig. 4 and 5 illustrate:
the relationship between the global value chain planning configuration elements is the basic global value chain planning configuration semantic. In the analysis of global value chain planning configuration, there are two types of relationships between elements: one is the relationship of elements in the structure of a global value chain planning configuration system; the other is the relationship of the elements in completing the global value chain planning configuration system function.
The relationship of elements in the global value chain planning configuration structure has one-to-one, one-to-many and many-to-many situations. For the first two cases, as shown in fig. 4, only one relationship element needs to be identified, the relationship element has direct connection with multiple parties in the relationship element, and is in one-to-one correspondence with the other party in terms of element generation, and all the connected elements are attributes of the relationship element; the relationship element is required to perform at least some of the following operations: (A) An operation of obtaining all the factor 2 which can possibly be connected with the factor l; (B) An operation of relating the related elements; (C) And an operation of releasing the relation of the related elements.
For many-to-many cases, such as the relationship between a configurator and a resource element, the association is achieved by defining the configuration and being configured with two relationship elements, as shown in FIG. 5.
FIG. 6 illustrates:
figure 6 presents an internal relationship problem for a global value chain planning configuration organization. In this relationship, the decision-maker consists of two base members (F and M) and the executive consists of three base members (B, S and J). This is a homomorphic transformation of the actual organizational internal relationships because much of the detail is omitted. However: (a) The graph correctly describes the internal relationship of the global value chain planning configuration organization at a certain depth. (b) The graph is a further abstraction of the global value chain planning configuration subject internal relationships, which ignores relationships between members of the global value chain planning configuration subject internal, due to the existence of a full map
The following full mapping holds true for the binary relationships in the two systems
h′ 1 : ( a, b, b, d ) ( α, α, β, β)
Therefore (b) Is shown in (A)a ) The homomorphism of the graph reflects the original relation in the global value chain planning configuration organization to a certain extent.
FIG. 7 illustrates:
the GVC planning configuration holographic cooperative operating system (OS/HSO [ GVC ]) developed and established by the present inventor is a huge GVC planning configuration internal and external management control program, and roughly includes 5 management functions: GVC planning configuration internal and external process and processor management, GVC planning configuration internal and external operation management, GVC planning configuration internal and external storage management, GVC planning configuration internal and external equipment management and GVC planning configuration internal and external file management. The common operating systems DOS, OS/2, UNIX, XENIX, LINUX, Windows, Netware and the like on the current microcomputer are transformed into a GVC planning configuration holographic cooperative operating system DOS/HSO [ GVC ], OS/2/HSO [ GVC ], UNIX/HSO [ GVC ], XENIX/HSO [ GVC ], LINUX/HSO [ GVC ], Windows/HSO [ GVC ], Netware/HSO [ GVC ] and the like.
The GVC plan configuration holographic cooperative operation system is a set of system software that controls the GVC plan configuration internal and external programs to run, manages GVC plan configuration internal and external system resources, and provides an operation interface for the GVC plan configuration internal and external users, as shown in fig. 7.
FIG. 8 illustrates:
another important activity of external storage management within GVC planning configurations is to manage virtual-physical locations with the help of CPU/HSO [ GVC ]. If there are many processes stored on the memory device simultaneously inside and outside the GVC plan configuration, the GVC plan configuration holographic co-operating system must prevent them from interfering with each other's memory contents (unless operating under a controlled range via some protocol and restricting the accessible GVC plan configuration internal and external memory range). Partitioning the external storage space within the GVC plan configuration can achieve the goal: each process inside and outside the GVC program configuration will only see that the entire memory space (from 0 to the maximum upper limit of the external memory space inside and outside the GVC program configuration) is configured to itself (of course, some locations are reserved by OS/HSO [ GVC ] and are prohibited from being accessed).
The theory of the GVC plan configuration holographic cooperative operation system to be explored and established is a brand new branch beyond information science and computer science, and the design and implementation of the GVC plan configuration holographic cooperative operation system is the basis and kernel of the external software industry in GVC plan configuration, as shown in fig. 8.
FIG. 9 illustrates:
during the problem solving process, planning can enable us to have a rough step of solving the problem before the details are deepened, so that the combinatorial explosion in blind search is reduced. However, in the process of solving complex problems, detailed plans are often not completely proposed at a time, only a general rough assumption can be initially proposed, and then the general rough assumption is gradually refined, and more detailed considerations are added to each refinement until the detailed plans are obtained.
The multi-level planning method is a multi-level planning, which generates a planning hierarchy:
the coarsest plan is at the top level and the most exhaustive plan is at the bottom level. Resulting in a tree, each level of which corresponds to one refinement of the plan, as shown in fig. 9.
FIG. 10 illustrates:
assuming that the first layer factor weight obtained in the previous step is from big to small i a ( i = l, 2, …, n) The second layer is j b ( j = l, 2, …, m) … …. And sequentially drawing the influencing factors on the graph according to a program from left to right, from top to bottom and from large to small, and marking the relative single ordering weight of each factor to obtain the global value chain planning configuration causal analysis graph. Let us take as an example an operational procedure of an internet basic organization. The hierarchy of operational factors is shown in FIG. 10. In the global value chain planning and configuration logic, a basic analysis is tonItem activityA l , A 2 , …, n A And (6) sorting. Typically, this needs to be taken into account during the sorting processnThe interaction between item activities.
5. Detailed description of the preferred embodiments
The PA/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 technical fields of wide application, 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 planning configuration project implementation plan
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 planning 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 planning configuration, and the basic configuration is normative and transparent.
And the second stage is integrating 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 planning configuration which are related inside and outside the global value chain planning configuration. The period is about 16 months. The method mainly realizes a holographic synergetic organization mode which takes global value chain planning to configure internal and external associated markets as requirements, takes main planning driven longitudinally and transversely as a core and takes input and output related to the global value chain planning to configure the internal and external associated input and output as main contents, effectively controls work-in-process, compresses stock to the maximum extent, improves delivery date and quickly meets market requirements.
Overall target for C2 planning 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 a global value chain planning configuration project as a trigger, and supporting the realization of a global value chain strategic target.
bReinforcing the global value chain infrastructure. Establishing a standard global value chain planning configuration internal and external associated data standard and a coding system, and promoting the global value chain foundation to be consolidated; product design and process file standardized configuration related to the inside and the outside of global value chain planning configuration are enhanced; refining raw material consumption, working hours, capital occupation and equipment time-per-hour quota configuration related to the inside and the outside of global value chain planning configuration; standardizing global value chain planning and configuring internal and external associated global value chain production period standards; customer resource information configuration related to the inside and the outside of global value chain planning configuration is enhanced; refining global value chain planning configuration inside and outside(ii) associated cost charges and price configurations; and the internal and external associated carrying flow and role specification configuration of global value chain planning configuration is enhanced.
cImprove configuration, decision-making methods. Information resource planning related to the inside and the outside of global value chain planning configuration, 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 planning configuration, wherein the global value chain basic information structure comprises an integrated information network and a comprehensive and uniform data interaction format; global value chain planning and configuration of internal and external related complete inventory configuration and analysis; global value chain planning configures internal and external associated process consumption cost accounting; global value chain planning and configuration of internal and external associated credit risk control and customer resource configuration; the integrated application of the main system operation planning, the material demand planning and the order configuration driven longitudinally and transversely; global value chain planning configures real-time cost accounting of internal and external associated sub-products; fast quotation; the global value chain planning configures the internal and external associated profit budget and profit-loss balance analysis; and (4) online multidimensional data analysis and decision application support.
dAnd the global value chain planning configuration is standardized, the global value chain configuration 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 planning configuration
aGlobal value chain planning configures internal and external associated logistics arrangements. The requirements of the global value chain planning configuration internal and external associated production systems are transmitted in time by means of brand-new information system support, and the requirements of the global value chain planning configuration internal and external associated production systems are quickly responded to through information integration with the global value chain planning configuration internal and external associated logistics systems, so that the compatibility of the global value chain planning configuration internal and external associated production materials is guaranteed. Global value chain planning configuration systemOperation planning, namely providing a demand plan of related production inside and outside the global value chain planning configuration; the global value chain planning 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 planning configuration internal and external associated logistics arrangement planning; establishing a perfect global value chain planning configuration internal and external associated supplier configuration system by integrating global value chain planning configuration internal and external associated information of a global value chain planning configuration system; the method comprises the following steps of taking information of delivery date, article quality and the like of internal and external associated suppliers of global value chain planning configuration as the basis of supplier evaluation; integrating evaluation results of global value chain planning configuration internal and external associated suppliers with distribution of logistics arrangement shares and payment policies; and establishing an information base of basic configurations such as global value chain planning 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 planning configures internal and external associated sales, inventory and production systems. The system operational plan is a compendium file that directs global value chain planning to configure internal and external associated production activities. In order to guarantee the implementation of 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 global value chain planning 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 planning configures 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 planning configuration, establishing a department cost budgeting method associated with the inside and the outside of the global value chain planning configuration, comparing with the analysis of the cost in affairs, ensuring that the budgeting is learned and accurate by departments step by step, and providing useful data for global value chain organization decision-making.
dGlobal value chain planning configures internal and external associated due configurations. The global value chain planning configuration internal and external related payable subsystems are mainly used for configuring various interactive funds between the global value chain and a supplier in the operation process, effectively help global value chain configurators master the flow direction of funds, control the outflow of the funds of the global value chain by monitoring the payment condition and form good circulation of the mobile funds. The global value chain planning configures internal and external associated payable subsystems to fill out invoices, taxes and logistics arrangement expenses based on the occurrence of logistics arrangement activities, and orders generated by the logistics arrangement subsystems can also be directly called. 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 related to the global value chain planning configuration inside and outside also provides rich inquiry statistical functions and is used in an integrated manner with a logistics arrangement subsystem and an accounting subsystem related to the global value chain planning configuration inside and outside.
eGlobal value chain planning configures internal and external associated receivable configurations. The global value chain organization realizes the sharing of data between the financial project departments and the sales departments which are related inside and outside the global value chain planning configuration through the application of the global value chain planning configuration system, and completes the communication of data information on the network; the income accounting form money of the financial project department related to the inside and the outside of the global value chain planning configuration is registered by taking the sales invoice of the sales department as the basis; the income accounting form money of the internal and external association of the global value chain planning configuration is collected according to the current users. The global value chain planning configures internal and external related collection and sales invoices according to the data, and defines the flow source. 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
After thirty years of free exploration, the independent inventor li zong professor formally submits 600 patent applications of inventions to the national patent office through an electronic application system in 2011 and 9 months, and submits 600 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, the independent inventor Lizong professor has independently written eight academic large works (total 3000 ten thousands) closely related to the 600 technical inventions reported this time on the basis of more than eighty papers published (without cooperative achievement) through international and domestic academic publications and academic conferences, and intends to continuously process official publishing matters after 9 months in 2011.
The 600 technical invention patents reported this time are a brand new technical cluster of a self-formed system established by the inventor of Lizong through thirty years of independent free exploration, and the general name is 'global value chain network technology support system' [ DCN/HII (GVC); ].
Based on a series of independently and freely completed major creative academic research results and 600 latest technical inventions, the inventor has proposed a strategy which can be called as 'open 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 fundamental aspect of technical development (the front end of an ICT industrial chain), a multi-level and 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 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' -a soul, intelligence and life are injected into a cloud computing network, 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 multi-level multi-mode 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-level intelligent integrated system (HIIS), an intelligent integrated scientific technology system (IIS & IIT) based on a meta-system (MS) scientific brand-new theory 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 (DCN) which are scattered at each department of all fields of the world, the global value chain system engineering is vigorously pushed, and a global intelligent integrated dynamic converged network system (DCN/HII (GVC)) really having life and ecological holographic synergetic organization is established, so that an intelligent integrated network is established, The life internet and the ecological operation network.
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 a global value chain planning configuration intelligent integrated operating system technical basis, is a new technology which is provided by the inventor by establishing a network configuration dynamics basic model and paradigm, taking internet users as the center, further taking a global value chain system (GVC) as the center, taking the connection and coordination of natural intelligence and artificial intelligence based on computers and networks thereof as a main line of a general Intelligent Integrated System (IIS) upgrading process, and aiming at modifying an indefinite cloud computing system into a universal and longitude and latitude-penetrating computing system on the basis of independently establishing a brand new logic basis, a brand new mathematical basis, a brand new scientific basis and a brand new technical basis and engineering basis, and is characterized in that:
A. for the global value chain planning configuration intelligent integrated operation system technology, 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 global value chain planning and configuration intelligent integrated operating system technology, "heaven and earth" computing is an extremely complex system per se, and has a quite complex holographic collaborative organization structure, wherein, on one hand, various computers and the infrastructures, the accessories and the network devices (including servers and browsers) thereof 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 and EMH) to form a computer interconnection 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 Internet organization forms what the inventor refers to as the "world" computing system CS/HSN (GII);
C. for the global value chain planning configuration intelligent integrated operating system technology, establishing general technical requirements and scientific basis of planning configuration operating system design, and further establishing a general design framework and basic composition assumption of the planning configuration operating system;
D. for the global value chain planning configuration intelligent integrated operation system technology, a proper engineering technical scheme for establishing the planning configuration operation system design is introduced, wherein the proper basic cooperative variables are used 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.
2. Dependent claims-for global value chain, the invention according to independent claim 1 first establishes general technical requirements for planning a configuration operating system design, which is characterized in that:
equipment resources and information resources of an internal and external system are allocated and scheduled by the global value chain planning configuration holographic cooperative operation system according to the requirements of internal and external users of the global value chain planning configuration according to a certain strategy; the storage management of the holographic cooperative operation system is responsible for allocating the global value chain planning configuration internal and external storage units to the program needing to be stored so as to be executed, and recovering the global value chain planning configuration internal and external storage units occupied by the program after the program is executed so as to be reused; for the inside and the outside of global value chain planning configuration which provides virtual storage and provides entity storage, the holographic cooperative operation system is matched with the inside and the outside hardware of the global value chain planning configuration to complete resource scheduling work, resources are allocated according to the requirements of inside and outside executive programs of the global value chain planning configuration, and the resources are called into and out of the inside and the outside of the global value chain planning configuration, resources are recycled and the like in the execution;
the GVC planning configuration internal and external information management is an important function of a holographic cooperative operation system, and is mainly used for providing a file system for GVC planning configuration internal and external users; generally speaking, a GVC internal and external file system for planning and configuring GVC provides the user with the functions of creating external and internal GVC files, revoking external and internal GVC files, reading and writing external and internal GVC files, opening and closing external and internal GVC files, and the like; after the internal and external file systems are configured by the GVC plan, a user can access data according to the internal and external file names configured by the GVC plan without knowing where the data are stored; the method is not only convenient for external and internal users in the GVC planning configuration to use, but also beneficial for the external and internal users in the GVC planning configuration to share common data; in addition, as the GVC plan configuration allows a creator to specify the use authority when establishing the internal and external files, the safety of data can be ensured;
from a completely new perspective, a standard GVC program configures the OS/HSO of internal and external systems to provide the following functions:
GVC planning configuration internal and external Process management (Processing management/HSO [ GVC ])
GVC plan configuration internal and external Memory space management (Memory management/HSO GVC)
GVC plans configuration of internal and external File systems (File system/HSO [ GVC ])
GVC plans configuration of internal and external communication (Networking/HSO GVC)
GVC plans to configure internal and external Security mechanisms (Security/HSO GVC)
GVC configuration internal and external User interface (User interface/HSO GVC)
GVC configures internal and external drivers (Device drivers/HSO GVC).
3. Dependent claims for global value chain, the invention according to independent claim 1 first establishes a scientific basis for planning the design of a configuration operating system, the rights being characterized in that:
the effect of causing certain components in the state to change, thereby changing the problem from one particular state to another, in the global value chain planning configuration logic, may be referred to as an operation, which may be a mechanical step, process, rule, or operator; the operations describe relationships between states;
the State Space (State Space) of a problem is a graph that represents all possible states of the problem and their interrelations; generally, a directed graph of assignments is provided, which contains a detailed description of the following three aspects:
S : a set of initial states that may be in the problem;
F : a set of operations;G : a set of target states;
the state space is often denoted as a triplet (S , F , G );
In state space representation, the problem solving process is converted into finding the initial state in the graph s QDeparture to destination state g QI.e. finding a sequence of operationsαThe problem of (2); therefore, the solution in the state space is also often denoted as a triplet: ( s Q, α, g Q) It contains the following three detailed descriptions:
s Q: a certain initial state; g Q: a certain target state;α: handle s QIs converted into g QA limited sequence of operations;
if it is notα= f l , f 2 , …, n f Then there is
g Q= n f ( ∙∙∙ ( f 2 ( f l ( s Q))) … )。
4. Dependent claims-for global value chain planning configuration, the overall design framework of the planning configuration operating system is established according to the invention of independent claim 1, this claim being characterized in that:
the global value chain planning configuration is a configuration method which takes an efficacy chain thought as a core, takes resource configuration dynamics, a system efficacy value theory, hedge balance economics and game organization synergetics as bases and applies modern latest information technology and global intelligent integration converged network information technology and an operation system; the method is developed on the basis of an application information technology configuration system of GVC planning NA/IVC;
the invention according to independent claim 1 proposes a GVC-plan-configuration holographic co-operating system (OS/HSO [ GVC ]) to be developed and built, which is a huge GVC-plan-configuration internal and external management control program, comprising roughly 5 management functions: GVC planning configuration internal and external process and processor management, GVC planning configuration internal and external operation management, GVC planning configuration internal and external storage management, GVC planning configuration internal and external equipment management and GVC planning configuration internal and external file management; the common operating systems DOS, OS/2, UNIX, XENIX, LINUX, Windows, Netware and the like on the current microcomputer are transformed into a GVC planning configuration holographic cooperative operating system DOS/HSO [ GVC ], OS/2/HSO [ GVC ], UNIX/HSO [ GVC ], XENIX/HSO [ GVC ], LINUX/HSO [ GVC ], Windows/HSO [ GVC ], Netware/HSO [ GVC ] and the like.
5. Dependent claims-for planning configuration of global value chains, the basic constructive concept of building a planning configuration operating system according to the invention of the independent claim 1, this right being characterized in that:
the basic structure of the theory of the GVC planning configuration holographic cooperative operation system is as follows:
I. GVC planning configuration holographic cooperative operation system introduction theory
I.1 GVC plans to configure internal and external hardware structures
I.1.1 GVC Provisioning internal and external processors
I.1.2 GVC Provisioning internal and external memory
I.1.3 GVC Provisioning internal and external I/O devices
I.1.4 bus
I.2 what is the GVC plan configuration holographic co-operating System
I.2.1 GVC planning configuration holographic co-operating system concept
I.2.2 GVC Provisioning Primary Functions of a holographic Co-operating System
I.2.3 GVC plans the position of configuring the holographic cooperative operation system
Development prospect of I.3 GVC planning configuration holographic cooperative operation system
I.3.1 GVC Provisioning the formation of a holographic Co-operating System
Development of I.3.2 GVC planning configuration holographic cooperative operation system
I.3.3 Power for promoting development of GVC planning configuration holographic cooperative operation system
I.4 GVC plan configuring type of holographic co-operating system
I.4.1 GVC planning configuration internal and external batch processing system
I.4.2 GVC planning and configuring internal and external parts of system
I.4.3 GVC planning and configuring internal and external real-time system
I.4.4 holographic cooperative network operation system
I.4.5 holographic cooperative distributed operation system
I.4.6 other GVC planning configuration holographic cooperative operation system
I.5 GVC Provisioning features of a holographic Co-operating System
I.6 GVC planning configuration holographic cooperative operation system structure design
I.6.1 monolithic Structure
I.6.2 hierarchy
I.6.3 virtual machine architecture
I.6.4 client, Server architecture
GVC plans configuring internal and external processes and threads
II.1 GVC planning and configuration of internal and external Process concepts
II.1.1 GVC planning configuration internal and external multi-channel programming
II.1.2 GVC planning and configuring internal and external process concepts
II.2 GVC plans configuring the State and composition of internal and external Processes
II.2.1 GVC plans configuring the states of internal and external processes and their transitions
II.2.2 GVC planning configuration internal and external Process descriptions
II.2.3 GVC plan configuration of internal and external process queues
II.3 GVC planning configuration internal and external Process management
II.3.1 GVC planning and configuring internal and external process maps
II.3.2 GVC planning configuration internal and external Process creation
II, 3.3 GVC Provisioning internal and external Process terminations
II, 3.4 GVC Provisioning internal and external Process blocking
II, 3.5 GVC plan configuration internal and external process wakeup
II, 4 GVC plans configuring internal and external threads
II, 4.1 GVC Provisioning internal and external thread concepts
II, 4.2 GVC plan configuration implementation of internal and external threads
II, 5 GVC plans the synchronization and communication of configuration internal and external processes
II, 5.1 GVC plans to configure synchronization and mutual exclusion of internal and external processes
II, 5.2 GVC plans to allocate internal and external critical resources and critical sections
II, 5.3 GVC plan configuration internal and external mutual exclusion implementation mode
II, 5.4 GVC plan configuration of internal and external semaphores
General application of II, 5.5 GVC planning to configure internal and external semaphores
II, 6 GVC planning and configuring internal and external classical process synchronization problem
II, 7 GVC plan configuration of internal and external tube side
II, 8 GVC plan configuration internal and external process communication
II, 8.1 GVC planning configuration internal and external transmission system
Communication in a II, 8.2 client-server system
GVC planning configuration internal and external deadlocks
III, 1 GVC plan configuration of internal and external resources
III, 1.1 GVC plan configuration internal and external resource use mode
III, 1.2 GVC Provisioning internal and external revocable resources and non-revocable resources
III, 2 GVC planning configuration internal and external deadlocks
III, 2.2 GVC plan configuration of conditions for internal and external deadlocks
III, 2.3 GVC plan configuration internal and external resource allocation map
…………
GVC planning configuration internal and external scheduling
External storage management within V, GVC planning configuration
GVC planning and configuring internal and external file system
GVC planning configuration internal and external input/output management
GVC planning configuration of internal and external user interface services
IX. holographic cooperative operation system for embedded GVC planning and configuration
X-distributed GVC planning configuration holographic cooperative operation system
XI GVC planning configuration of internal and external security and protection mechanisms
Case study 1: UNIX/HSO [ GVC ]
Example study 2: Linux/HSO [ GVC ]
Xiv, example study 3: windows 2000/HSO [ GVC ].
6. Dependent claims-for global value chain, the invention according to independent claim 1 establishes a problem solving basis for planning a configuration operating system design, the rights being characterized in that:
suppose a global value chain planning and configuration system hasnIndividual action factors (can be summarized into five aspects); by comparing pairwise impact factors of global value chain planning configuration results and according to relative importance between the two impact factors, we can listn × nAn order matrix, which is a decision matrix of the form:
each sub-target is provided with a judgment matrix;
the hierarchical single ordering of the importance degree of each hierarchical influence factor can be summarized as the problem of solving the eigenvalue and eigenvector of a judgment matrix:
wherein,
λ max for the largest root of the features of the matrix,
Wto correspond toλ max Normalized feature vectors of (a);
Wcomponent (b) of i WWeights for single ordering of the corresponding factors;
in order to maintain consistency, the matrix is also checked for consistency:
if the check is not satisfied, the matrix needs to be adjusted:
。
7. dependent claims-for global value chain, a technical embodiment of the invention according to the independent claim 1 for establishing a planning configuration operating system, the right being characterized in that:
the method has the advantages that the requirements of the global value chain planning configuration internal and external associated production systems are transmitted in time by means of brand-new information system support, and rapid response is rapidly made to the requirements of the global value chain planning configuration internal and external associated production through information integration with the global value chain planning configuration internal and external associated logistics systems, so that the compatibility of the global value chain planning configuration internal and external associated production materials is ensured; the global value chain planning and configuration system provides a demand plan of the internal and external associated production of the global value chain planning and configuration according to the system operation plan; the global value chain planning 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 planning configuration internal and external associated logistics arrangement planning; establishing a perfect global value chain planning configuration internal and external associated supplier configuration system by integrating global value chain planning configuration internal and external associated information of a global value chain planning configuration system; the method comprises the following steps of taking information of delivery date, article quality and the like of internal and external associated suppliers of global value chain planning configuration as the basis of supplier evaluation; integrating evaluation results of global value chain planning configuration internal and external associated suppliers with distribution of logistics arrangement shares and payment policies; and establishing an information base of basic configurations such as global value chain planning configuration internal and external related logistics arrangement period, economic batch, safety stock and the like, and providing a basis for timely guaranteeing material supply.
Priority Applications (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN2011103469084A CN102724255A (en) | 2011-11-07 | 2011-11-07 | Global value chain planning configuration intelligence integration operation system technology base |
Applications Claiming Priority (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN2011103469084A CN102724255A (en) | 2011-11-07 | 2011-11-07 | Global value chain planning configuration intelligence integration operation system technology base |
Publications (1)
| Publication Number | Publication Date |
|---|---|
| CN102724255A true CN102724255A (en) | 2012-10-10 |
Family
ID=46949916
Family Applications (1)
| Application Number | Title | Priority Date | Filing Date |
|---|---|---|---|
| CN2011103469084A Pending CN102724255A (en) | 2011-11-07 | 2011-11-07 | Global value chain planning configuration intelligence integration operation system technology base |
Country Status (1)
| Country | Link |
|---|---|
| CN (1) | CN102724255A (en) |
-
2011
- 2011-11-07 CN CN2011103469084A patent/CN102724255A/en active Pending
Similar Documents
| Publication | Publication Date | Title |
|---|---|---|
| Murer et al. | Fifteen years of service-oriented architecture at Credit Suisse | |
| CN102739730A (en) | Operation system technique foundation for intelligent integration of industrial value chain market allocation | |
| CN102724255A (en) | Global value chain planning configuration intelligence integration operation system technology base | |
| Moshiri et al. | Enterprise Architecture Fundamentals | |
| CN102685190A (en) | Intelligent integrated operating system technological base for industrial value chain planning and configuration | |
| CN102833302A (en) | Technology base of global value chain network configuration intelligent integrated operating system | |
| CN102638500A (en) | Intelligent integrated operating system technology basis for regional value chain planning configuration | |
| CN102724258A (en) | National value chain market configuration intelligence integration operation system technology base | |
| CN102638488A (en) | Intelligent integrated operating system technical foundation for national value chain planning and distribution | |
| CN102761586A (en) | Technological base of intelligent integrated operation system for regional value chain market disposition | |
| CN102724256A (en) | National value chain network configuration intelligence integration operation system technology base | |
| CN102739724A (en) | Operation system technique foundation for intelligent integration of enterprise value chain network configuration | |
| CN102769657A (en) | Enterprise value chain market allocation based on intelligent integrated operating system technology | |
| CN102710681A (en) | Intelligent integrated operating system technical foundation for Internet user terminal market allocation | |
| CN102833304A (en) | Technology base of industrial value chain network configuration intelligent integrated operating system | |
| Ciarleglio | Modular abstract self-learning tabu search (MASTS): Metaheuristic search theory and practice | |
| CN102624796A (en) | Computing technology foundation for providing intelligent integrated system for internet user terminal market configuration | |
| CN102724250A (en) | Internet IDK/ICT technical design basis | |
| CN102638555A (en) | IDC/ICT operation design basis of internet | |
| CN103179137A (en) | Intelligent integrated operating system technological base for global value chain market configuration | |
| CN103023953A (en) | Intelligent integrated operation system technological base for planning allocation of internet user terminals | |
| CN102624798A (en) | Computing technology basis of intelligent integrated system for planning and configuring regional value chain | |
| CN103001996A (en) | Technological base of integrated intelligent operating system of regional value chain network configuration | |
| CN102624840A (en) | Information and communication technology (ICT) network docking technology of planning and configuration system of user terminal of internet | |
| CN102694844A (en) | Internet EMK/ICT technology design basis |
Legal Events
| Date | Code | Title | Description |
|---|---|---|---|
| C06 | Publication | ||
| PB01 | Publication | ||
| C02 | Deemed withdrawal of patent application after publication (patent law 2001) | ||
| WD01 | Invention patent application deemed withdrawn after publication |
Application publication date: 20121010 |