CN112381445A - Data center task distribution system crossing data service provider boundary - Google Patents

Abstract

The invention relates to the technical field of task allocation systems, in particular to a data center task allocation system crossing data service provider boundaries, which comprises a user terminal, an information acquisition module, a task allocation module and a task processing module, wherein the output end of the user terminal is electrically connected with the information acquisition module; according to the invention, the data access requirements of the cross-region and cross-service providers can be reasonably distributed by collecting and distributing the requirements of the users in a centralized manner and analyzing and formulating the corresponding task distribution strategies, and the task processing efficiency and performance of the users are improved while the performance of each data center is improved.

Description

Data center task distribution system crossing data service provider boundary

Technical Field

The invention relates to the technical field of task allocation systems, in particular to a data center task allocation system crossing data service provider boundaries.

Background

The task allocation system refers to the processes of task collection, analysis, processing and task allocation, and can realize rationalization, program standardization, decision scientification and performance optimization of each data center of related task allocation, and help each data center to better process various things such as task allocation and performance optimization.

The existing task allocation system does not break through the barriers of data service operators and independently and autonomously operates in each data service operator in the using process, so that task allocation strategies are different among different data service operators, unified strategies do not exist, and the task working efficiency of trans-regional trans-service operators is influenced; the performance indexes of the data centers cannot be optimized through a unified strategy, the existing optimization targets of the data centers are different, the performance advantages of the data centers are different, and the selection difficulty and the risk assessment difficulty of a user are increased.

Based on the above, the invention designs a data center task distribution system crossing data service provider boundaries to solve the above problems.

Disclosure of Invention

The invention aims to provide a data center task distribution system crossing data service provider boundaries so as to solve the problems in the background technology.

In order to achieve the purpose, the invention provides the following technical scheme: a data center task distribution system crossing data service provider boundaries comprises a user terminal, an information acquisition module, a task distribution module and a task processing module, wherein the output end of the user terminal is electrically connected with the information acquisition module, the user terminal is provided with a task sending unit and a task processing feedback receiving unit, the output end of the information acquisition module is electrically connected with the task distribution module, the information acquisition module is provided with an information acquisition unit, an information identification unit and an information classification unit, the output end of the task distribution module is electrically connected with the task processing module, the task distribution module is provided with an information receiving unit, the system comprises a demand analysis unit, a task analysis unit and a task allocation unit, wherein the output end of a task processing module is electrically connected with a user terminal, and the task processing module is provided with a task receiving unit, a time line analysis unit, a time neutral allocation unit and a task result sending unit.

Furthermore, the task distribution module is electrically connected with a disaster alarm module, a disaster identification unit and a disaster alarm unit are arranged on the disaster alarm module, and the disaster identification unit and the disaster alarm unit are electrically connected in series. The output end of the disaster alarm unit is electrically connected with the information receiving unit on the task distribution module. The disaster alarm unit provides disaster alarm information for the information receiving unit on the task allocation module so as to adjust the task allocation strategy and start an emergency disaster recovery scheme in time.

Furthermore, a task sending unit and a task processing feedback receiving unit are arranged on the user terminal, the output end of the task sending unit is electrically connected with the information acquisition unit on the information acquisition module, and the input end of the task processing feedback receiving unit is electrically connected with the task result sending unit on the task processing module. And the task sending unit and the task processing feedback receiving unit on the user terminal are not electrically connected.

Furthermore, the information acquisition module is provided with an information acquisition unit, an information identification unit and an information classification unit which are electrically connected in series. The input end of the information acquisition unit is electrically connected with the task sending unit on the user terminal. The output end of the information classification unit is electrically connected with the information receiving unit on the task allocation module.

Furthermore, the task allocation module is provided with an information receiving unit, a demand analysis unit, a task analysis unit and a task allocation unit. The information receiving unit, the demand analysis unit, the task analysis unit and the task distribution unit are electrically connected in series. The input end of the information receiving unit is electrically connected with the information classification unit of the information acquisition module and the disaster alarm unit on the disaster alarm module. The output end of the task allocation unit is electrically connected with the task receiving unit of the task processing module.

Furthermore, the task processing module is provided with a task receiving unit, a time line analyzing unit, a time gap distributing unit and a task result sending unit. The task receiving unit, the time line analyzing unit, the time gap distributing unit and the task result sending unit are electrically connected in series. The input end of the task receiving unit is electrically connected with the task distribution unit on the task distribution module. The output end of the task result sending unit is electrically connected with the task processing feedback receiving unit on the user terminal.

Compared with the prior art, the invention has the beneficial effects that: according to the invention, the data access requirements of the cross-region and cross-service providers can be reasonably distributed by collecting and distributing the requirements of the users in a centralized manner and analyzing and formulating the corresponding task distribution strategies, and the task processing efficiency and performance of the users are improved while the performance of each data center is improved. When the disaster phenomenon occurs in the data center, the disaster alarm module in the system performs alarm operation to remind the system to perform secondary adjustment on the existing task of the data center with the corresponding disaster and adjust the work required by the future task in time; through the disaster alarm module, the demand analysis unit and the task analysis unit, the safety of task completion of each data center is improved, and the condition that the tasks cannot be completed in time is avoided, so that adverse effects and losses are caused to users; the task processing module is arranged at the data center end, so that each data center can discretely process the distributed tasks, and the time line analysis unit and the time neutral distribution unit on the task processing module are convenient for the data center to more effectively arrange the processing tasks on the time axis according to the self condition, so that the task completion degree and the data center performance are effectively improved.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings used in the description of the embodiments will be briefly introduced below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art that other drawings can be obtained according to the drawings without creative efforts.

FIG. 1 is a schematic view of the overall structure of the present invention;

FIG. 2 is a schematic diagram of the internal structure of the user terminal of the present invention;

FIG. 3 is a schematic diagram of the internal structure of the information collection module of the present invention;

FIG. 4 is a schematic diagram of the internal structure of the task assignment module of the present invention;

FIG. 5 is a schematic diagram of the internal structure of the task processing module of the present invention.

In the drawings, the components represented by the respective reference numerals are listed below:

1. a user terminal; 2. an information acquisition module; 3. a task allocation module; 4. a task processing module; 5. a disaster alert module; 6. a task sending unit; 7. an information acquisition unit; 8. an information identification unit; 9. an information classification unit; 10. an information receiving unit; 11. a demand analysis unit; 12. a task analysis unit; 13. a task allocation unit; 14. a disaster identification unit; 15. a disaster warning unit; 16. a task receiving unit; 17. a timeline analysis unit; 18. a time slot allocation unit; 19. a task result transmitting unit; 20. and the task processing feedback receiving unit.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Example one

The embodiment is described with reference to fig. 1 to 3, a data center task allocation system across data service provider boundaries, which includes a user terminal 1, an information acquisition module 2, and a task processing module 4, wherein the user terminal 1 is provided with a task sending unit 6 and a task processing feedback receiving unit 20, an output end of the task sending unit 6 is electrically connected to the information acquisition module 2, an input end of the task processing feedback receiving unit 20 is electrically connected to the task processing module 4, the information acquisition module 2 is provided with an information acquisition unit 7, an information identification unit 8, and an information classification unit 9, an output end of the information acquisition unit 7 is electrically connected to the information identification unit 8, and an output end of the information identification unit 8 is electrically connected to the information classification unit 9; the information acquisition unit 7 is used for collecting the task demand information and the resource demand information sent by the user terminal 1, the information identification unit 8 and the information classification unit 9 are arranged, the collected demand data can be accurately transmitted to the task distribution module 3 for further analysis and distribution, when the encrypted data are lost, the system performs alarm operation, and reminds the staff to perform secondary collection on the data through the system.

Example two

The embodiment is described with reference to fig. 1 to 4, and the first embodiment is further described, the data center task allocation system across the data service provider boundary further includes a task allocation module 3, the task allocation module 3 is provided with an information receiving unit 10, a demand analysis unit 11, a task analysis unit 12 and a task allocation unit 13, an input end of the information receiving unit 10 is electrically connected with the information acquisition module 2 and the disaster alarm module 5, and the information receiving unit 10, the demand analysis unit 11, the task analysis unit 12 and the task allocation unit 13 are electrically connected in a unidirectional series connection; when the received demand data needs to be analyzed, under the action of the demand analysis unit 11, the demand analysis unit analyzes and plans the demands of the user received from the information receiving unit 10, so that the task analysis unit 12 can complete the task analysis quickly, and the task allocation unit 13 can complete the task allocation scheme in the multi-data center environment more accurately.

EXAMPLE III

In the embodiment described with reference to fig. 1-4, the data center task distribution system across data service provider boundaries further includes a disaster alert module 5, and a disaster identification unit 14 and a disaster alert unit 15 are disposed on the disaster alert module 5. The output of the disaster identification unit 14 is electrically connected to the disaster alarm unit 15. The output of the disaster warning unit 15 is electrically connected to the information receiving unit 10. When a disaster occurs in the data center, the disaster alarm unit 15 generates a disaster alarm and sends the disaster alarm to the information receiving unit 10 in the task distribution module 3 through the identification information sent by the disaster identification unit 14, so that the current task requirement and the task requirement to be generated from the disaster data center information are adjusted and emergency disaster recovery response is performed under the sequential action of the requirement analysis unit 11, the task analysis unit 12 and the task distribution unit 13, thereby saving the current task requirement to the maximum extent and distributing the task requirement to be generated more reasonably.

Example four

The third embodiment is described with reference to fig. 1 to 5, and further described in the third embodiment, the data center task allocation system across data service provider boundaries further includes a task processing module 4, and the task processing module 4 is provided with a task receiving unit 16, a timeline analyzing unit 17, a time slot allocating unit 18, and a task result sending unit 19. The input end of the task receiving unit 16 is electrically connected to the task assigning module 3. The output end of the task result sending unit 19 is electrically connected with the user terminal 1. The task receiving unit 16, the time line analyzing unit 17, the time slot allocating unit 18 and the task result transmitting unit 19 are electrically connected in series in a unidirectional manner. When the task receiving unit 16 obtains the distribution plan of the specific task from the task distribution module 3, the time axis of the current data center is subjected to system analysis under the action of the time line analysis unit 17, and an optimal processing scheme for the received task is obtained under the action of the time slot distribution unit 18, and meanwhile, a task processing result is generated in the task result sending unit 19 so as to be finally sent to the user terminal 1 to inform the user of the processing result of the task.

EXAMPLE five

The fourth embodiment is further described below with reference to fig. 1 to 5, and the data center task allocation system across data service provider boundaries is multi-region closed-loop management. Aiming at multiple data centers and multi-user terminal environments, centralized task distribution facing a single data center is realized through the task distribution module 3, discrete information is acquired through the information acquisition module 2 and the task processing module 4, and complete disaster response is realized through the disaster alarm module 5. The information collection module 2 is independent of each data center and the user terminal 1 and can be distributed to any relevant place so as to perform information collection service for the corresponding user terminal 1. The task distribution module 3 performs unified analysis, planning and distribution on the acquired tasks for each data center, so that task distribution is reasonably performed according to a specified strategy, and the task processing module 4 and the disaster warning module exist in each data center, so that further reasonable processing and emergency response are performed on the tasks respectively according to the real-time situation of each data center.

The invention relates to a multiport encryption type acquisition system for data, which has the working principle that:

firstly, a user sends a task and a requirement of resource occupation to an information acquisition unit 7 in an information acquisition module 2 through a task sending unit 6 in a user terminal 1. The information collection unit 7 will collect in real time the tasks sent by the user from the task sending unit 6 in the user terminal 1 and continue to send to the information recognition unit 8. The information identification unit 8 identifies the information acquired from the information acquisition unit 7 and sends the information to the information classification unit 9 for specific classification of the information, so that the requirements of the current task of the user in various aspects can be clearly presented. When the obtained information is classified, the information classification unit 9 will send all type information about the task to the information receiving unit 10 in the task assigning module 3. The information demand analysis unit 11 in the task allocation module 3 further analyzes the demand information according to the information received by the information receiving unit 10 from the information classification unit 9 in the information collection module 2, and performs specific analysis and analysis on the received task structure through the further task analysis unit 12.

Meanwhile, the disaster identification unit 14 in the disaster alarm module 5 monitors the operation of each data center in real time. When the data center sends an abnormal situation, the disaster recognition unit 14 sends an abnormal situation report to the disaster alarm unit 15, and a disaster alarm generated by the disaster alarm unit 15 is sent to the information receiving unit 10 in the task assigning module 3. The task allocation unit 13 in the task allocation module 3 formulates a specific allocation scheme according to the received disaster alarm, the task structure and the requirement according to the corresponding set strategy, and sends the corresponding tasks to the corresponding data center task processing modules 4 according to the formulated scheme. The task receiving unit 16 in the task processing module 4 receives the tasks distributed by the task distribution module and sends the tasks to the timeline analysis unit 17 to analyze the time slot situation on the current data center timeline. After the timeline analysis unit completes analysis of the timeline of the current data center, the time slot allocation unit 18 searches for an optimal time slot according to the result of the timeline analysis unit 17 and a preset time slot allocation strategy, executes the task, and sends the execution result to the task result sending unit 19. Finally, the task result sending unit 19 feeds back the execution result of the task to the task processing feedback receiving unit 20 on the user terminal 1 to complete the closed-loop task execution flow.

The product model provided by the invention is only used according to the structural characteristics of the product, the product can be adjusted and modified after being purchased so as to be more matched and accord with the technical scheme of the invention, the product model is the best application technical scheme of the technical scheme, the product model can be replaced and modified according to the required technical parameters, and the product model is well known by the technical personnel in the field, so that the technical scheme provided by the invention can clearly obtain the corresponding use effect.

In the description herein, references to the description of "one embodiment," "an example," "a specific example" or the like are intended to mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the invention. In this specification, the schematic representations of the terms used above do not necessarily refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

The preferred embodiments of the invention disclosed above are intended to be illustrative only. The preferred embodiments are not intended to be exhaustive or to limit the invention to the precise forms disclosed. Obviously, many modifications and variations are possible in light of the above teaching. The embodiments were chosen and described in order to best explain the principles of the invention and the practical application, to thereby enable others skilled in the art to best utilize the invention. The invention is limited only by the claims and their full scope and equivalents.

Claims (6)

1. A data center task distribution system crossing data service provider boundaries comprises a user terminal, an information acquisition module, a task distribution module and a task processing module, and is characterized in that: the output end of the user terminal is electrically connected with the information acquisition module, the user terminal is provided with a task sending unit and a task processing feedback receiving unit, the output end of the information acquisition module is electrically connected with the task distribution module, the information acquisition module is provided with an information acquisition unit, an information identification unit and an information classification unit, the output end of the task distribution module is electrically connected with the task processing module, the task distribution module is provided with an information receiving unit, a demand analysis unit, a task analysis unit and a task distribution unit, the output end of the task processing module is electrically connected with the user terminal, the task processing module is provided with a task receiving unit, a timeline analysis unit, a time neutral distribution unit and a task result sending unit.

2. The data center task distribution system across data provider boundaries of claim 1, wherein: the task distribution module is electrically connected with a disaster alarm module, a disaster identification unit and a disaster alarm unit are arranged on the disaster alarm module, and the disaster identification unit and the disaster alarm unit are electrically connected in series. The output end of the disaster alarm unit is electrically connected with the information receiving unit on the task distribution module. The disaster alarm unit provides disaster alarm information for the information receiving unit on the task allocation module so as to adjust the task allocation strategy and start an emergency disaster recovery scheme in time.

3. The data center task distribution system across data provider boundaries of claim 1, wherein: the user terminal is provided with a task sending unit and a task processing feedback receiving unit, the output end of the task sending unit is electrically connected with the information acquisition unit on the information acquisition module, and the input end of the task processing feedback receiving unit is electrically connected with the task result sending unit on the task processing module. And the task sending unit and the task processing feedback receiving unit on the user terminal are not electrically connected.

4. The data center task distribution system across data provider boundaries of claim 1, wherein: the information acquisition module is provided with an information acquisition unit, an information identification unit and an information classification unit, and the information acquisition unit, the information identification unit and the information classification unit are electrically connected in series. And the input end of the information acquisition unit is electrically connected with the task sending unit on the user terminal. The output end of the information classification unit is electrically connected with the information receiving unit on the task allocation module.

5. The data center task distribution system across data provider boundaries of claim 1, wherein: the task allocation module is provided with an information receiving unit, a demand analysis unit, a task analysis unit and a task allocation unit. The information receiving unit, the demand analysis unit, the task analysis unit and the task distribution unit are electrically connected in series. The input end of the information receiving unit is electrically connected with the information classification unit of the information acquisition module and the disaster alarm unit on the disaster alarm module. The output end of the task allocation unit is electrically connected with the task receiving unit of the task processing module.

6. The data center task distribution system across data provider boundaries of claim 1, wherein: the task processing module is provided with a task receiving unit, a time line analyzing unit, a time gap distributing unit and a task result sending unit. The task receiving unit, the time line analyzing unit, the time gap distributing unit and the task result sending unit are electrically connected in series. The input end of the task receiving unit is electrically connected with the task distribution unit on the task distribution module. And the output end of the task result sending unit is electrically connected with a task processing feedback receiving unit on the user terminal.

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