RU2018130478A - ASSET MASTER DATA MANAGEMENT SYSTEM - Google Patents

Claims (53)

1. A master asset data management system containing: the core of the system that supports the creation, modification and storage of the master asset data model in memory: master asset data model must include: - at least three hierarchically organized views corresponding to some representations of the available asset park, each of which is associated with at least one unique generic classifier of asset master data included in the model; - generic classifiers, each of which is a hierarchical system of classes built on the basis of the principles of inheritance and encapsulation, while the class of each object of the master data on assets in the classifier completely defines all the attributes of the corresponding object of this class and all types of its connections with objects of other angles ; - sets of links of each object of any of the angles with objects of other angles for transition between different representations of the same asset; and optionally containing, for each hierarchically organized view: - a set of non-hierarchical (network) links between assets belonging to the same view, reflecting view-specific relationships between assets, while these links can be of different types and can be characterized by sets of attributes; - a set of structural models of master data on assets, describing the internal relationships and the component composition of specific types of assets; - a set of functional models of master asset data, built both on the basis of relatively simple algorithms and on the basis of complex mathematical models and using the attribute values of individual instances of master asset data and attributes of related instances of master asset data in order to to check the completeness of the asset data entry or to identify the asset type depending on the attribute values; at least three interface modules, each of which provides interaction of the system core with one application or one functional module of the ERP system. Each interface module is configured to unload, upon requests from external applications and / or ERP modules, a requested piece of master data about assets related to a specific view of the master data with which the requesting module or application works; at least one algorithmic module configured to process the entire master asset data model and / or individual views of the master asset data model, providing some operations from the following list: - checking the correctness and completeness of the system of connections between objects in the model; - checking the correctness of classifiers; - search for objects by classifiers; - formation of new views of the master data based on the data of other views available in the system or on the basis of external data; - formation of reports on the data model and on the adjustments made in it; - as well as other similar operations required to work with the master data of a specific asset park; a module of the dialog interface, providing the creation and correction of master data by the administrator of the master data in the dialog mode. 2. The system according to claim 1, characterized in that each hierarchically organized view of the model reflects the ownership of assets (the entry of objects into higher-level objects). 3. The system according to claim 1, characterized in that if non-hierarchical (network) links between assets of one view are of different types, then for them the master data model of assets necessarily contains a classifier of links related to this view, which is a hierarchical system of classes, built on the principles of polymorphism and encapsulation, which, if necessary, can determine all the attributes of each type of network links of a given view. 4. The system according to claim 1, characterized in that, if necessary, the interface modules may have: the ability to unload hierarchies, classifiers, network links, structural and functional models related to objects of a specific view, with which this interface module works, as well as existing links with objects of other views; the ability to load model data into the master data management system, but this data cannot be used until confirmed by the master data administrator. 5. The system according to claim 1, characterized in that the dialog interface module, if necessary, can correct the master asset data obtained from the interface modules, confirm the correctness of this master data and transfer it to the main asset master data model. 6. The system according to claim 1, characterized in that: at least one algorithmic module will implement a method for checking the correctness and completeness of the inter-view links between assets in the system; and / or the system can have two different algorithmic modules, one of which checks the correctness of the inter-view links between assets in the system, and the second checks the completeness of the system of inter-view links between assets. 7. The system according to claim 6, characterized in that if it implements two algorithmic modules, one of which checks the correctness of the inter-view links between assets in the system, and the second checks the completeness of the system of inter-view links between assets, then each of these modules implements a data processing method in which only a part of the operations of the general method and the algorithmic module that implements it for checking the correctness and completeness of inter-view links between assets is performed. 8. The method for checking the correctness and completeness of inter-view links between assets according to claim 7 includes the following operations: clearing all data about the markup of links formed in external memory during the previous execution of the algorithm; loop traversal of all hierarchical views presented in the asset structure; traversal of all nodes of each hierarchy from top to bottom and sequentially along the branches of each subtree using a stack and a pointer located in RAM: when hitting the next node of the hierarchy: clearing the second stack in memory and loading the current hierarchy node as the first member of the second stack; clearing the set of inter-view links formed in RAM and adding to this set of inter-view links all the obligatory links of the class node of the first element of the second stack from the attributes contained in the classifier; checking the correctness and completeness of the inter-view links of this node; generation of a report on broken, missing and unpredicted connections or that there are no violations of inter-perspective connections. 9. The method according to claim 8, characterized in that when checking the correctness and completeness of inter-view links of a particular node, all rings of the existing lattice of inter-view links existing in the external memory starting from this node are bypassed. 10. The method according to claim 9, characterized in that when checking the correctness and completeness of inter-view links of a particular node, the internal numbers of the views of the data model are used, and when checking the links in a particular lattice, the internal numbers of the hierarchies are substituted so that the node at the top of the second stack and its the hierarchy received the number 1, and the numbers of all other hierarchies are shifted in any direction along the ring, preserving the order. 11. The method according to claim 10, characterized in that when checking the correctness and completeness of inter-view connections of a particular node, all the rings of the lattice are traversed in such a way that the rings from the node with number 1 are constructed so that each next node in the ring has a number greater than the previous or number 1. 12. The method according to claim 11, characterized in that when traversing all the rings of the lattice, the rings are traversed sequentially along the inter-view connections of each object, and the entire chain of ring nodes through which the next node became available is stored in the second stack. 13. The method according to claim 11, characterized in that, when traversing all the rings of the lattice, in order not to pass each ring repeatedly, a bond markup is used, which is fixed in external memory. If, when traversing the rings, a transition is performed along some connection, and for the next transition there are no unmarked connections or a hit to the beginning of the ring occurs, then a mark is put on the passed connection. On the marked links, the transition is not made. 14. The method according to claim 11, characterized in that when traversing all of the lattice rings, a second pointer is used to select a new element of the current ring. 15. The method according to claim 11, characterized in that for the upper element introduced into the second stack when traversing all the rings of one lattice, the following checks are performed: whether there is a link between the class of the node by the second pointer and the class of the node at the top of the second stack in the set of inter-view links. If not, an error message is logged; whether the link between the class of the node at the second pointer and the class of the node at the top of the second stack in the set of inter-view links is marked. If not, then a mark is put on it. 16. The method according to claim 11, characterized in that for the next element of the ring, when bypassing all the rings of one lattice, the following checks are performed: whether the node at the first pointer matches the node at the second pointer. If yes, then a mark is put on the connection between the nodes so that you do not go through it anymore; whether the total cardinality of the second stack equals the number of hierarchies in the master asset data model. If so, an error message is logged; whether there are inter-view links outgoing from the node at the second pointer. If not, an error message is logged. If yes, then a check is made to see if the next hop has connections without markup in external memory. If they are present, the node at the second pointer is added to the second stack, and if they are absent, a mark is put on the link between the node in the second stack and the node at the second pointer so that you do not go over it anymore. 17. The method according to claim 11, characterized in that after the traversal of all the rings of the lattice is completed, a check is made whether unmarked links remain in the set of inter-view links located in the RAM. If so, an error message is generated. 18. The system according to claim 1, using at least one processor and at least one memory containing machine-readable instructions, which, when executed by at least one processor, support the master data model according to claims. 1-3, as well as the functions of the system interface modules according to PP. 1, 4, the functions of the dialog module according to PP. 1, 5, as well as the functions of the algorithmic modules of the system according to PP. 1, 6-17.