CN113626170B - Control method and device for full life cycle of communication engineering task - Google Patents

Abstract

The application provides a control method and device for a full life cycle of a communication engineering task. The method comprises the following steps: collecting engineering progress data of each task node in a communication engineering task, wherein each task node is used for executing operation of at least one flow link in a life cycle of the communication engineering task, judging whether the engineering progress data meets the condition of a preset intelligent contract protocol or not, and the intelligent contract protocol comprises: and if the engineering progress data meets the conditions of the intelligent contract protocol, generating a block based on the engineering progress data and adding the block into a block chain. The method realizes the control of the whole life cycle of the communication engineering task, and improves the completion efficiency and quality of the communication engineering task.

Description

Control method and device for full life cycle of communication engineering task

Technical Field

The present disclosure relates to the field of communications engineering facility control, and in particular, to a method and an apparatus for controlling a full life cycle of a communications engineering task.

Background

In the field of communications engineering infrastructure control, as one of the fastest growing industries, communications networks will continue to maintain a rapid growth potential for the next few years. In the 5G large-scale network construction process, telecom operator facility control faces significant challenges and challenges.

At present, in the control workflow of communication engineering facilities, a node planning design scheme is needed to be designed from the steps of planning, standing, ordering, construction, single inspection and operation and maintenance, and a large amount of communication is carried out among a plurality of links such as grid planning, grid optimizing, standing, node shipment of base station equipment manufacturers, node construction of the network construction engineering, operation and maintenance node cross maintenance and the like. However, in the prior art, the construction department of the telecom operator uses a construction management platform to manage planning design and equipment construction conditions, and the maintenance department uses a full-flow platform for cross-maintenance acceptance control.

The prior art has the following problems: the whole life cycle of the communication engineering task relates to a plurality of execution nodes, each execution node comprises own business flow and business data, and the butt joint of the business data of each execution node is lack of effective control, so that the conditions of data transmission delay, inconsistency and the like are caused, and the control efficiency of the whole communication engineering task is lower.

Disclosure of Invention

The application provides a control method and a device for a full life cycle of a communication engineering task, which are used for solving the problem that the control efficiency of the whole communication engineering task is low.

In a first aspect, the present application provides a method for controlling a full life cycle of a communication engineering task, including:

collecting engineering progress data of each task node in the communication engineering task, wherein each task node is used for executing operation of at least one flow link in the life cycle of the communication engineering task;

judging whether the engineering progress data meets the conditions of a preset intelligent contract protocol or not, wherein the intelligent contract protocol comprises the following steps: service processing logic, data verification, execution authority, execution time and execution flow among task nodes in the communication engineering task;

if the engineering progress data meets the conditions of the intelligent contract agreement, a block is generated based on the engineering progress data and added into the blockchain.

In a second aspect, the present application provides a method for controlling a full life cycle of a communication engineering task, including: acquiring engineering progress data of task nodes in a communication engineering task from each block in a block chain, wherein each task node is used for executing operation of at least one flow link in a life cycle of the communication engineering task, and the engineering progress data of each task node is stored in at least one block;

And controlling each flow link of the communication engineering task life cycle according to the acquired engineering progress data.

In a second aspect, the present application provides a method for controlling a full life cycle of a communication engineering task, including:

acquiring engineering progress data of task nodes in a communication engineering task from each block in a block chain, wherein each task node is used for executing operation of at least one flow link in a life cycle of the communication engineering task, and the engineering progress data of each task node is stored in at least one block;

and controlling each flow link of the communication engineering task life cycle according to the acquired engineering progress data.

In a third aspect, the present application provides a control device for a full life cycle of a communication engineering task, including: and a memory, a processor storing code therein, the processor executing the code stored in the memory to perform the method of controlling the full life cycle of the communication engineering task as in the first aspect.

In a fourth aspect, the present application provides a control device for a full life cycle of a communication engineering task, including: and a memory, a processor storing code therein, the processor executing the code stored in the memory to perform the communication engineering task full life cycle control method as in the second aspect.

In a fifth aspect, the present application provides a computer-readable storage medium having stored therein computer-executable instructions which, when executed by a processor, are configured to implement a method of controlling a full lifecycle of a communications engineering task as in any one of the first aspects.

In a sixth aspect, the present application provides a computer-readable storage medium having stored therein computer-executable instructions which, when executed by a processor, are configured to implement a control method for a full lifecycle of a communications engineering task as in any one of the second aspects. The method collects engineering progress data of task nodes in a communication engineering task, each task node is used for executing operation of at least one flow link in the communication engineering task life cycle, whether the engineering progress data meets the condition of a preset intelligent contract protocol or not is judged, and the intelligent contract protocol comprises: and if the engineering progress data meets the conditions of the intelligent contract protocol, generating a block based on the engineering progress data and adding the block into a block chain, thereby realizing the control of the whole life cycle of the communication engineering task and improving the completion efficiency and quality of the communication engineering task.

Drawings

The accompanying drawings, which are incorporated in and constitute a part of this specification, illustrate embodiments consistent with the application and together with the description, serve to explain the principles of the application.

FIG. 1A is a diagram of a communication engineering task full life cycle control system architecture provided in an embodiment of the present application;

FIG. 1B is a structural design diagram of a full lifecycle control system for communication engineering tasks according to an embodiment of the present application;

fig. 2 is a flow chart of a control method of a full life cycle of a communication engineering task according to an embodiment of the present application;

fig. 3 is a flow chart of a control method of a full life cycle of a communication engineering task according to an embodiment of the present application;

FIG. 4 is a business flow chart of a full life cycle of a communication engineering task provided in an embodiment of the present application;

FIG. 5 is a data flow chart of a full life cycle control algorithm of a communication engineering task according to an embodiment of the present application;

FIG. 6 is a flowchart of an intelligent contract execution algorithm provided by an embodiment of the present application;

fig. 7 is a schematic diagram of a control device for a full life cycle of a communication engineering task according to an embodiment of the present application;

fig. 8 is a schematic diagram of a control device for a full life cycle of a communication engineering task according to an embodiment of the present application.

Specific embodiments thereof have been shown by way of example in the drawings and will herein be described in more detail. These drawings and the written description are not intended to limit the scope of the inventive concepts in any way, but to illustrate the concepts of the present application to those skilled in the art by reference to specific embodiments.

Detailed Description

Reference will now be made in detail to exemplary embodiments, examples of which are illustrated in the accompanying drawings. When the following description refers to the accompanying drawings, the same numbers in different drawings refer to the same or similar elements, unless otherwise indicated. The implementations described in the following exemplary examples are not representative of all implementations consistent with the present application. Rather, they are merely examples of apparatus and methods consistent with some aspects of the present application as detailed in the accompanying claims.

The terms referred to in this application are explained first:

the consensus mechanism is an algorithm for realizing distributed consensus of the block chain transaction. Due to the high network delay in the point-to-point network, the observed transaction sequence of each node cannot be completely consistent. Therefore, a mechanism needs to be designed for blockchain systems to agree on the order of transactions that occur in about the time. Such an algorithm that agrees on the precedence of transactions within a time window is called a "consensus mechanism".

Narrowband internet of things (Narrow Band Internet of Things, NB-IoT): the method is an important branch of the Internet of everything, is constructed in a cellular network, only consumes about 180KHz bandwidth, can be directly deployed in a GSM network, a UMTS network or an LTE network, is used for reducing deployment cost and realizing smooth upgrading, and has the characteristics of wide coverage, multiple connections, low speed, low cost, low power consumption, excellent architecture and the like.

P2P network (Peer-to-Peer network): refers to a Peer-to-Peer network, i.e., a Peer-to-Peer computer network, which is a distributed application architecture that distributes tasks and workloads among peers (peers), and which is a form of networking or networking of Peer-to-Peer computing models at the application layer.

Node control: in the whole implementation process of the communication process, the intelligent contract is used for controlling and detecting the progress and quality of the intersection points and time control points of various working procedures by a certain effective mode and against the progress plan and quality target which are originally formulated.

Smart contract: is a computer protocol that aims to propagate, verify or execute contracts in an informative manner. Smart contracts allow trusted transactions to be made without third parties, which transactions are traceable and irreversible. Essentially, the operating principles of these autocontracts are similar to if-then statements of other computer programs. The smart contracts merely interact with real world assets in this manner. When a pre-programmed condition is triggered, the smart contract performs the corresponding contract term.

Net preference: the method is short for network optimization, and means that the reasons affecting the network quality are found out by means of telephone traffic data analysis, field test data acquisition, parameter analysis, hardware inspection and the like on the basis of the existing network, and various optimizations (including parameter modification, network structure adjustment, equipment configuration adjustment and adoption of certain technical means) are carried out on the basis of the network. Gauge: the network planning is abbreviated as network planning, and refers to planning network construction according to network construction targets, user demands, local actual conditions and the like before a communication network is established.

The following describes the technical solutions of the present application and how the technical solutions of the present application solve the above technical problems in detail with specific embodiments. The following embodiments may be combined with each other, and the same or similar concepts or processes may not be described in detail in some embodiments. Embodiments of the present application will be described below with reference to the accompanying drawings.

The lifecycle of a communication engineering task typically involves a plurality of task nodes that assume different tasks as different task roles, performing different operations, throughout the lifecycle of the task. For example: generally, a communication engineering task is generally to pass through: demand collection, task establishment, task execution, execution result detection and the like, wherein each task link is usually executed by a different task node, and engineering progress data of each task node is determined by a task executed by the node, for example: the project progress data of the demand collection node is the demand data of the communication project, the project progress data of the task establishment node is the execution flow planning data of the communication project, the project progress data of the task execution node can correspond to the operations specifically executed by the node, and the operations can be as follows: equipment purchase data, construction data and the like, and the engineering progress data of the execution result detection node can be communication engineering project acceptance detection data.

According to the control method for the full life cycle of the communication engineering task, engineering progress data of each task node are collected, business processing logic of each task node is guaranteed by judging whether the engineering progress data meets an intelligent contract protocol, the execution sequence and the execution flow among the task nodes meet preset execution logic, data and authority of each task node can be verified through the intelligent contract protocol, for any task node, if the engineering progress data meets the intelligent contract protocol, a block of a block chain can be generated based on the engineering progress data of the task node, and the engineering progress data of each task node of the full life cycle of the whole communication engineering task can form a block chain. The method and the system incorporate the blockchain technology in the control of the whole life cycle of the communication engineering task, so that the data of each link of the whole life cycle of the communication engineering task can be collected, the execution sequence and the execution logic of each task node are effectively linked, collected and controlled, and the completion efficiency and quality of the communication engineering task are improved.

The system architecture related to the present application is described by taking a base station to erect a communication engineering task as an example, where a plurality of task execution nodes in the system may be included, and each task execution node may execute: the method comprises the steps of demand acquisition (such as a network specification network optimization node and a design node), task establishment (such as a network specification network optimization node), task execution (such as a network construction engineering node) and execution result detection (such as an operation and maintenance node). As shown in fig. 1A, includes: the system comprises a data acquisition part, a data access part, a blockchain platform and a user layer webpage platform part; the data acquisition part is mainly responsible for acquiring engineering progress data of each task node in the communication engineering task, and the data acquisition operation can be completed by equipment with a data acquisition function. For example: in the detection operation of the laid base station, the data acquisition equipment can be executed by functional equipment with a GPS (global positioning system ) positioning chip, a signal detector, an altitude measuring instrument, a camera sweep generator and the like, can also be executed by a mobile phone, a computer, a tablet terminal and the like which are provided with signal measurement software, and can also be used for collecting engineering progress data such as videos, pictures, text records and the like of a construction site; the data access part is mainly responsible for receiving various engineering progress data transmitted by the data acquisition equipment, and can be a local server, a cloud server and other equipment. And after the blockchain platform part receives the engineering progress data of each task node, judging the engineering progress data based on an intelligent contract protocol, wherein the intelligent contract protocol can be stored on a terminal corresponding to the user layer webpage platform, and the blockchain platform can call the intelligent contract protocol through an interface to judge. The method comprises the steps of presenting the project progress data in a program code mode), judging whether the project progress data meets an intelligent contract protocol or not so as to ensure business processing logic of each task node, wherein the execution sequence and the execution flow among the task nodes meet preset execution logic, verifying the data and the authority of each task node through the intelligent contract protocol, generating a block of a block chain based on the project progress data of the task node if the project progress data meets the intelligent contract protocol for any task node, and forming the block chain by the project progress data of each task node in the whole communication project full life cycle.

Fig. 2 is a flow chart of a control method of a full life cycle of a communication engineering task, as shown in fig. 2, where the method of the embodiment is implemented mainly by a blockchain platform in a system, and may include:

s201: and collecting engineering progress data of each task node in the communication engineering task, wherein each task node is used for executing operation of at least one flow link in the life cycle of the communication engineering task.

The task nodes can be communication engineering task demand acquisition nodes, communication engineering task flow establishment nodes, communication engineering task equipment parameter establishment nodes, communication engineering task operation execution nodes and the like.

The engineering progress data corresponding to the communication engineering task demand acquisition node is task demand data, the engineering progress data corresponding to the communication engineering task flow establishment node is task flow execution logic data, the engineering progress data corresponding to the communication engineering task equipment parameter establishment node is equipment parameter list, and the engineering progress data corresponding to the communication engineering task operation execution node comprises at least one or more of the following: positioning data of the operation execution node, altitude data of the operation execution node, multimedia data of an operation site of the operation execution node, and working signal data of the operation execution node.

S202: judging whether the engineering progress data meets the conditions of a preset intelligent contract protocol or not, wherein the intelligent contract protocol comprises the following steps: service processing logic, data verification, execution authority, execution time and execution flow among task nodes in the communication engineering task.

The task nodes comprise a communication engineering task demand acquisition node, a communication engineering task flow establishment node, a communication engineering task equipment parameter establishment node, a communication engineering task operation execution node and the like.

The communication engineering task demand acquisition node comprises a network specification network optimization node and a design node, the communication engineering task flow establishment node comprises a network specification network optimization node and a design node, the communication engineering task equipment parameter establishment node comprises a network specification network optimization node and a base station equipment manufacturer node, and the communication engineering task operation execution node comprises a network construction engineering node and an operation and maintenance node.

The network planning network optimization node, the design node, the base station equipment manufacturer node, the network construction engineering node and the operation and maintenance node jointly sign corresponding intelligent contracts, and all initial parameters including communication engineering project targets, plans, basic data, contract triggering conditions and the like are used as verification conditions for data verification and task verification in subsequent data uplink.

S203: if the engineering progress data meets the conditions of the intelligent contract agreement, a block is generated based on the engineering progress data and added into the blockchain.

Randomly generating a read-write block based on engineering progress data, wherein the read-write block comprises: the system comprises a block head, a corresponding engineering task identifier, a random number, a time stamp and a block body, wherein the block body comprises engineering progress data.

Read-write blocks are added to the end of the blockchain.

The intelligent contract is realized in a code form, is stored on a blockchain, and the running environment is a P2P network. Each task node initiates an operation or a transaction, a read-write block of the blockchain is randomly generated, and the read-write block is found by the node with the strongest calculation power and is added to the tail end of the blockchain to form the longest chain, namely the effective chain for storage. The smart contract agreement includes: service processing logic, data verification, execution authority, execution time and execution flow among task nodes in the communication engineering task.

According to the control method for the full life cycle of the communication engineering task, engineering progress data of each task node in the communication engineering task are collected, each task node is used for executing operation of at least one flow link in the life cycle of the communication engineering task, whether the engineering progress data meets the conditions of a preset intelligent contract protocol is judged, so that business processing logic of each task node is guaranteed, execution sequence and execution flow among all task nodes meet the preset execution logic, data and authority of each task node can be verified through the intelligent contract protocol, for any task node, if the engineering progress data meets the conditions of the intelligent contract protocol, a block can be generated based on the engineering progress data of the task node and added into a block chain, and the engineering progress data of all task nodes in the full life cycle of the whole communication engineering task can form the block chain. The method and the system incorporate the blockchain technology in the control of the whole life cycle of the communication engineering task, so that the data of each link of the whole life cycle of the communication engineering task can be collected, the execution sequence and the execution logic of each task node are effectively linked, collected and controlled, and the completion efficiency and quality of the communication engineering task are improved.

On the basis of the embodiment, the user layer platform is combined to cooperate to control the whole life cycle of the communication engineering task. The process of implementing the control method of the full life cycle of the communication engineering task through the user layer platform is described in detail below in connection with a specific embodiment.

Fig. 3 is a flow chart of a control method of a full life cycle of a communication engineering task, and as shown in fig. 3, the method of the embodiment is implemented mainly through a user layer web page platform, and may include:

s301, acquiring engineering progress data of task nodes in a communication engineering task from each block in a block chain, wherein each task node is used for executing operation of at least one flow link in the life cycle of the communication engineering task, and the engineering progress data of each task node is stored in at least one block.

The task nodes can be communication engineering task demand acquisition nodes, communication engineering task flow establishment nodes, communication engineering task equipment parameter establishment nodes, communication engineering task operation execution nodes and the like.

The engineering progress data corresponding to the communication engineering task demand acquisition node is task demand data, the engineering progress data corresponding to the communication engineering task flow establishment node is task flow execution logic data, the engineering progress data corresponding to the communication engineering task equipment parameter establishment node is equipment parameter list, and the engineering progress data corresponding to the communication engineering task operation execution node comprises at least one or more of the following: positioning data of the operation execution node, altitude data of the operation execution node, multimedia data of an operation site of the operation execution node, and working signal data of the operation execution node.

S302: and controlling each flow link of the communication engineering task life cycle according to the acquired engineering progress data.

The user layer webpage platform part can acquire engineering progress data of each task node in the communication engineering task from the blockchain by calling an API (application program interface) of the intelligent contract, so that the visual presentation of the whole life cycle of the communication engineering task is realized.

The embodiment of the application provides a control method for a full life cycle of a communication engineering task, which is characterized in that engineering progress data of task nodes in the communication engineering task are obtained from all blocks in a block chain, each task node is used for executing operation of at least one flow link in the life cycle of the communication engineering task, the engineering progress data of each task node is stored in at least one block, and all flow links in the life cycle of the communication engineering task are controlled according to the obtained engineering progress data. By the control method of the full life cycle of the communication engineering task, each flow link of the communication engineering can be controlled, and the completion efficiency and quality of the communication engineering task are improved.

Based on the embodiment of fig. 3, the following describes the business process of the communication engineering task full life cycle in detail with reference to a specific embodiment.

Fig. 4 is a business flow chart of a communication engineering task full life cycle, and as shown in fig. 4, each specific business flow link of the communication engineering full life cycle may include engineering construction requirement proposal, technical scheme writing and interrogation, purchase plan issue, manufacturer equipment information issue, equipment settlement, engineering implementation, and maintenance acceptance. Accordingly, each business link can be executed by a task node, in general, tasks set forth by engineering construction requirements can be executed by task nodes for requirement collection, for example, can be a network gauge network optimization node and a design node; the tasks of writing and negotiating the technical solution can be executed by a process establishment node, for example, a design node and a network planning network optimization node, the purchase plan issue can be executed by a process establishment node, for example, a network planning network optimization node, the manufacturer equipment information issue can be executed by an equipment parameter establishment node, for example, a base station equipment manufacturer node, the equipment settlement can be executed by an equipment parameter establishment node, for example, a network planning network optimization node and a base station equipment manufacturer node, the engineering implementation can be executed by an operation execution node, for example, a network construction engineering node, the cross-maintenance acceptance can be executed by an operation execution node, for example, an operation and maintenance node and a network construction engineering node. Fig. 5 is a data flow chart of the communication engineering task full life cycle control algorithm.

For the whole life cycle of a communication engineering task, each link of the task is executed through a plurality of task nodes, taking a base station to erect the specific communication engineering as an example for illustration, wherein the base station comprises a plurality of links shown in S401-S408, each link can be executed by one task node, and engineering progress data of each link can be written into a blockchain when an intelligent contract is met, so that each link of the whole life cycle of the communication engineering task can be effectively connected and controlled through a blockchain technology. The detailed operation of each link is described below.

S401: and the engineering construction requirement is put forward.

Can be implemented by a task node, a mesh grid optimization node. In particular, demand data related to communication engineering tasks may be collected, which may be obtained from demand data according to customer demand as well as market demand. In this link, the engineering progress data are demand data, and it is determined whether the demand data satisfy an intelligent contract protocol, where the intelligent contract protocol includes service processing logic, data verification, execution authority, execution time of each task node and execution flow among each task node in the communication engineering task, so that, for example, whether the demand data satisfy a preset corresponding index threshold of the intelligent contract can be determined from m (N1, S, P, U, D, R, T) and other aspects. Wherein N1 refers to the name of a network gauge network optimal node, S refers to the sequence number of an event, P refers to the PRB utilization rate of surrounding base stations, U refers to the weak coverage user number duty ratio of the surrounding base stations, D refers to the distance from the site selection to the surrounding base stations, R refers to the benefit investment evaluation duty ratio, and T refers to the time stamp of the release record. N1 and S may be used to determine the execution authority and execution flow of the task node, and P, U, D, R may be used to determine the service processing logic of the task node. If the digital signature (i.e., private key) of the demand data can be matched with the prefabricated public key, the data verification is passed, the engineering progress data of the node can be subjected to the uplink operation, and a block is generated and added into the blockchain.

And then, the network planning network optimization node entrusts the communication design node to formulate an overall construction scheme, an engineering proposal, a research report and writing of a preliminary design according to planning requirements.

S402: and determining communication engineering tasks.

May be implemented by a task node, a design node. Specifically, after the design node receives the delegation of the network gauge network optimization node, the design node starts to write a corresponding scheme report, and after the completion, the design node updates corresponding information in the intelligent contract. For example, whether the preset smart contract corresponding index threshold is satisfied may be determined from m (N2, S, report1, report2, report3, report4, T) or the like. Wherein N2 refers to a design node, S refers to a sequence number initiated by a current event, report1, report2, report3, and report4 are respectively a construction technical scheme, an engineering proposal, a scalable report, and a preliminary design, and T refers to a timestamp of a release record. N1, S may be used to determine the execution authority and execution flow of the task node, and report1, report2, report3, report4 may be used to determine the traffic processing logic of the task node. If the digital signature (i.e., private key) of the demand data can be matched with the prefabricated public key, the data verification is passed, the engineering progress data of the node can be subjected to the uplink operation, and a block is generated and added into the blockchain.

S403: the technical proposal is examined.

Can be implemented by a task node, a mesh grid optimization node. Specifically, the network planning network optimization node is responsible for the interrogation work of overall construction schemes, engineering projects, research reports and preliminary designs. If the examination passes, the project setting work is performed, otherwise, the project setting work is returned to the design node to be modified accordingly, and the process returns to the step S402. In this link, the engineering progress data is task flow execution logic data.

S404: and publishing a purchase plan.

Can be implemented by a task node, a mesh grid optimization node. Specifically, after being checked, planning and selecting addresses, standing, surveying and designing, and outputting equipment purchase orders by the network gauge network optimal nodes. In this link, the engineering progress data is a device parameter list, and it is determined whether the data satisfies an intelligent contract agreement. For example, it may be determined from m (N1, S, K, T, a, D) or the like whether the data satisfies a preset smart contract corresponding index threshold. Wherein N1 refers to the name of the network gauge network optimal node, S refers to the serial number initiated by the current event, K refers to the type and number of the main equipment and the corresponding matching, T refers to the timestamp of the release record, A refers to the delivery address, and D refers to the expected delivery date. If the preset corresponding index threshold of the intelligent contract is met, the engineering progress data of the node can be subjected to uplink operation, and a block is generated and added into the blockchain.

S405: and (5) issuing manufacturer equipment information.

May be implemented by a task node, a base station equipment manufacturer node. Specifically, in this link, the engineering progress data is a device parameter list, and whether the data meets the intelligent contract agreement is judged. For example, it may be determined from m (N3, P, K, T) or the like whether the device parameter list satisfies a preset smart contract corresponding index threshold. Wherein N3 represents the node name of the base station equipment manufacturer, P represents the equipment number, K represents the equipment type, and T represents the timestamp of the release record. Prior to step S404, the base station equipment manufacturer updates the information in the smart contract on the platform. If the preset corresponding index threshold of the intelligent contract is met, the engineering progress data of the node can be subjected to uplink operation, and a block is generated and added into the blockchain.

S406: and (5) settling the device.

The method can be implemented by a task node, a network planning network optimization node and a base station equipment manufacturer node. Specifically, device settlement can be performed. For example, when the purchase is completed, it may be determined from M (N1, N3, S, P, K, M, T) or the like whether the device settlement list information satisfies the preset smart contract corresponding index threshold. Wherein N1 refers to the name of the network gauge network optimal node, N3 refers to the name of the node of the base station equipment manufacturer, S refers to the serial number initiated by the current event, P refers to the equipment number, K refers to the equipment type, M refers to the purchase amount, and T refers to the timestamp of the release record. If the equipment settlement list information meets the preset corresponding index threshold value of the intelligent contract, the engineering progress data of the node can be subjected to uplink operation, and a block is generated and added into the blockchain. And in the whole purchasing period, the NFC (Near Field Communication ) label on the scanning equipment can be used for collecting equipment information and uploading the blockchain, and the N1 node, namely the net-standard net-excellent node, can be used for conveniently carrying out dynamic logistics tracking and monitoring.

Along with the arrival of equipment, the longitude and latitude geographic position and time information during data generation are acquired according to the equipment label and the positioning module of the base station auxiliary device, and whether the preset corresponding index threshold of the intelligent contract is met or not can be determined from the aspects of m (S, A, D1) and the like. And when the data meets the contract condition, performing the uplink operation, and generating a block to be added into the blockchain. Where S refers to the serial number from which the current event originated, a represents the shipping address, and D1 is the expected shipping address. When overdue goods are not sent, the N3 equipment manufacturer triggers a punishment mechanism to automatically reimburse the punishment, and the longer the overdue time is, the heavier the punishment is. The equipment arrival control is more standard, disputes are avoided, the construction arrangement is more reasonable, and the material control is realized.

S407: engineering implementation.

May be implemented by a task node, a network engineering node. Specifically, it may be responsible for the specific implementation of engineering construction. In this link, the engineering progress data are positioning data, altitude data, on-site multimedia data and working signal data, and whether the data meet the intelligent contract agreement is judged. The network construction project node agrees to preset task quantity, staff, planning design project parameters, equipment identification and project opening standards in the intelligent contract, and a project construction task plan and a task completion mark are taken as discrimination conditions. For example, it may be determined from m (S, a, st) or the like whether the data satisfies a preset smart contract corresponding index threshold. S refers to a serial number initiated by a current event, A is a longitude and latitude address, st represents state information, and the state information comprises an antenna azimuth angle, a downtilt angle, the number of sectors, power and the like. And when the data meets the threshold value, performing the uplink operation, generating a block and adding the block into a block chain, so as to realize intelligent supervision of the field construction quality.

The construction site can acquire the longitude and latitude and the signal level of the base station according to the positioning module and the signal monitoring module of the base station auxiliary device. When the base station is electrified and turned on, the base station is compared and identified with a preset base station opening standard according to the level acquired by the signal monitoring module, and when the data meet the contract conditions, the base station is automatically uplink, so that the intelligent management and control of the construction progress is realized.

The construction site can acquire longitude, latitude and antenna hanging height according to a positioning module and an altitude measuring module of the base station auxiliary device, an image AI detection mechanism is introduced, the azimuth angle and the downward inclination angle information of the antenna are acquired through a mobile terminal camera, meanwhile, the picture, video and text description record of the construction site is recorded by utilizing an application platform client, the accuracy and the planning preset of the base station industrial parameters are automatically identified through a background,

the mobile terminal or the application platform client carried by the constructor can be matched with the construction site through longitude and latitude information to judge whether the constructor is doing related work, and meanwhile, the image text description is uploaded by a specific private key signature, so that the work completion condition of the private key owner can be monitored in real time and pushed to the employee serving as the private key owner in real time, and the employee is transferred to engineering facility control personnel to realize the assessment management of a construction unit.

S408: and (5) checking and accepting the cross-dimension.

The method can be implemented by task node-operation and maintenance node and network engineering node interaction. Specifically, after the base station is healthily accessed to the network, the operation and maintenance node and the network building unit are subjected to maintenance and acceptance, and are responsible for the maintenance service of the equipment in the later period. In this link, the engineering progress data are positioning data, altitude data, on-site multimedia data and working signal data, and whether the data meet the intelligent contract agreement is judged. For example, after the base station completes construction operation, the application platform applies a big data mining technology, a clustering algorithm is introduced, an alarm problem monitoring table is automatically output, multiple regression modeling is performed, characteristic variables with high correlation with weak coverage are screened, the trend of a problem cell is mastered, prediction data are provided, the prediction data are subjected to condition judgment with a preset engineering acceptance data standard, when the prediction data meet the contract condition, the automatic uplink is performed, meanwhile, the progress and the quality result acquired by the signal monitoring module are combined, and meanwhile, the condition is met, the base station is judged to meet the base station acceptance specification, and the intelligent application of the interaction maintenance acceptance result is realized.

Before a specific business flow is carried out, firstly, operating authorities and identity authentications (account numbers and passwords of a login platform) of related personnel of network planning network optimization nodes, design nodes, base station equipment manufacturer nodes, network construction engineering nodes and operation and maintenance nodes are configured on an application platform and are used for reporting, inputting, inquiring and matching data in engineering facility control.

The application platform is specifically used for realizing the visual presentation in the whole process of communication engineering construction, and comprises the functions of basic data inquiry, intelligent output identification of operation quality data, equipment delivery tracking, engineering progress inquiry, equipment operation inquiry, engineering quality control, personnel assessment, acceptance inspection maintenance and the like. The application platform peripheral interface is connected with the network management database, the engineering acceptance data standard of the base station is configured, the existing operation quality data of the base station is read, and the K-means clustering algorithm and the multiple regression algorithm are utilized to model and intelligently output predicted data to serve as important basis of cross dimension acceptance. The predicted data mainly comprises the RRC connection number of the base station cell, traffic volume, call completing rate, switching success rate, disconnection rate, MR (measurement report ) grade distribution, interference grade distribution, alarm type problem cell and the like.

The intelligent contracts are specifically used for positioning related operations (such as construction requirement proposal and purchasing plan release) among user nodes, are realized in a code form, are stored on a blockchain, and are used for a P2P network. The smart contracts are personalized applications built on the blockchain platform. FIG. 6 is a flowchart of an intelligent contract execution algorithm.

And triggering the intelligent contract through data acquisition of the hardware device and data input operation of the engineering instrument on the construction site, and judging conditions of the data and parameters in the intelligent contract, and automatically uploading the data when the data meets the contract conditions.

Each working position responsible person signs an intelligent contract, each operation needs to be added with a digital signature, and when illegal or wrong operation occurs, the block chain is utilized to trace and collect the relevant operation of each link of the service opening so as to ensure the correctness and standardization of the whole base station network opening operation.

The address type variable in the intelligent contract programming language can be used for positioning network rule network optimization nodes, design nodes, base station equipment manufacturer nodes, network construction engineering nodes and operation and maintenance nodes, and can also be used for positioning related operations or transactions (such as construction requirement proposal and purchase plan release) among all nodes, and each time an operation or a transaction is initiated, a read-write block of a block chain is randomly generated, and the read-write block is found by the node with the strongest calculation power and is sent to the tail end of an added block chain to form a longest chain, namely an effective chain for storage.

The node control is specifically used for configuring the circulation sequence of the whole node in the engineering implementation process, and mainly comprises flow control, authority control, time control and the like, wherein the flow control is implemented by the node control; control authority-configuring operation authority and identity authentication of related personnel of a network specification network optimization node, a design node, a base station equipment manufacturer node, a network construction engineering node and an operation and maintenance node on an application platform, and is used for reporting, inputting, inquiring and matching data in engineering facility control; control time—control the flow-through time of each node.

The embodiment of the application provides a business process of a full life cycle of a communication engineering task, which comprises a plurality of links such as engineering construction requirement proposal, technical scheme writing, technical scheme interrogation, purchasing plan release, manufacturer equipment information release, equipment settlement, engineering implementation, interaction maintenance acceptance and the like, each link can be executed by a task node, engineering progress data of each link can be written into a blockchain when an intelligent contract is met, and effective connection and control of each link of the full life cycle of the communication engineering task are realized through a blockchain technology.

Fig. 7 is a schematic diagram of a control device for a full life cycle of a communication engineering task according to an embodiment of the present application. As shown in fig. 7, an embodiment of the present application provides a control device 700 for a full life cycle of a communication engineering task, including: a processor 701 and a memory 702, wherein the processor 701 and the memory 702 are connected by a bus 703.

In a specific implementation process, codes are stored in a memory, and a processor runs the codes stored in the memory to execute the control method of the full life cycle of the communication engineering task in the embodiment of the method.

The specific implementation process of the processor 701 can be referred to the above method embodiment, and its implementation principle and technical effects are similar, and this embodiment will not be described herein again.

In the embodiment shown in fig. 7, it should be understood that the processor may be a central processing unit (english: central Processing Unit, abbreviated as CPU), or may be other general purpose processors, digital signal processors (english: digital Signal Processor, abbreviated as DSP), application specific integrated circuits (english: application Specific Integrated Circuit, abbreviated as ASIC), or the like. A general purpose processor may be a microprocessor or the processor may be any conventional processor or the like. The steps of a method disclosed in connection with the present invention may be embodied directly in a hardware processor for execution, or in a combination of hardware and software modules in a processor for execution.

The memory may comprise high speed RAM memory or may further comprise non-volatile storage NVM, such as at least one disk memory.

The bus may be an industry standard architecture (Industry Standard Architecture, ISA) bus, an external device interconnect (Peripheral Component, PCI) bus, or an extended industry standard architecture (Extended Industry Standard Architecture, EISA) bus, among others. The buses may be divided into address buses, data buses, control buses, etc. For ease of illustration, the buses in the drawings of the present application are not limited to only one bus or one type of bus.

The apparatus of this embodiment may be used to perform the method embodiment shown in fig. 2, and its implementation principle and technical effects are similar, and will not be described herein again.

Fig. 8 is a schematic diagram of a control device for a full life cycle of a communication engineering task according to an embodiment of the present application. As shown in fig. 8, an embodiment of the present application provides a control device 800 for a full life cycle of a communication engineering task, including: a processor 801, and a memory 802, wherein the processor 801 and the memory 802 are connected by a bus 803.

The apparatus of this embodiment may be used to execute the method embodiment shown in fig. 3, and its implementation principle and technical effects are similar, and will not be described herein again.

The embodiment of the application provides a computer readable storage medium, wherein computer executing instructions are stored in the computer readable storage medium, and the computer executing instructions are used for realizing the control method of the full life cycle of the communication engineering task in the method embodiment when being executed by a processor.

The computer readable storage medium described above may be implemented by any type or combination of volatile or nonvolatile memory devices such as Static Random Access Memory (SRAM), electrically erasable programmable read-only memory (EEPROM), erasable programmable read-only memory (EPROM), programmable read-only memory (PROM), read-only memory (ROM), magnetic memory, flash memory, magnetic or optical disk. A readable storage medium can be any available medium that can be accessed by a general purpose or special purpose computer.

An exemplary readable storage medium is coupled to the processor such the processor can read information from, and write information to, the readable storage medium. In the alternative, the readable storage medium may be integral to the processor. The processor and the readable storage medium may reside in an application specific integrated circuit (Application Specific Integrated Circuits, ASIC for short). The processor and the readable storage medium may reside as discrete components in a device.

Those of ordinary skill in the art will appreciate that: all or part of the steps for implementing the method embodiments described above may be performed by hardware associated with program instructions. The foregoing program may be stored in a computer readable storage medium. The program, when executed, performs steps including the method embodiments described above; and the aforementioned storage medium includes: various media that can store program code, such as ROM, RAM, magnetic or optical disks.

Other embodiments of the present application will be apparent to those skilled in the art from consideration of the specification and practice of the invention disclosed herein. This application is intended to cover any variations, uses, or adaptations of the application following, in general, the principles of the application and including such departures from the present disclosure as come within known or customary practice within the art to which the application pertains. It is intended that the specification and examples be considered as exemplary only, with a true scope and spirit of the application being indicated by the following claims.

It is to be understood that the present application is not limited to the precise arrangements and instrumentalities shown in the drawings, which have been described above, and that various modifications and changes may be effected without departing from the scope thereof. The scope of the application is limited only by the appended claims.

Claims (7)

1. The control method of the full life cycle of the communication engineering task is characterized by comprising the following steps:

collecting engineering progress data of each task node in a communication engineering task, wherein each task node is used for executing operation of at least one flow link in a communication engineering task life cycle;

judging whether the engineering progress data meets the condition of a preset intelligent contract protocol or not, wherein the intelligent contract protocol comprises the following steps: service processing logic, data verification, execution authority, execution time and execution flow among all task nodes in the communication engineering task;

if the engineering progress data meets the conditions of the intelligent contract protocol, generating a block based on the engineering progress data and adding the block into a block chain;

acquiring engineering progress data of task nodes in a communication engineering task from each block in a block chain, wherein each task node is used for executing operation of at least one flow link in a communication engineering task life cycle, and the engineering progress data of each task node is stored in at least one block;

And controlling each flow link of the communication engineering task life cycle according to the acquired engineering progress data.

2. The method of claim 1, wherein generating a block based on the engineering progress data for addition to a blockchain comprises:

randomly generating a read-write block based on the engineering progress data, wherein the read-write block comprises: the system comprises a block head, a corresponding engineering task identifier, a random number, a time stamp and a block body, wherein the block body comprises the engineering progress data;

the read-write block is added to the end of the blockchain.

3. The method according to claim 1 or 2, wherein the task node comprises: the communication engineering task demand acquisition node, wherein the engineering progress data are task demand data; or alternatively, the process may be performed,

the task nodes are as follows: the communication engineering task flow establishment node, wherein the engineering progress data are task flow execution logic data; or alternatively, the process may be performed,

the task nodes are as follows: and establishing a node by using the equipment parameters of the communication engineering task, wherein the engineering progress data is an equipment parameter list.

4. A method according to claim 3, wherein the task node comprises: a communication engineering task operation execution node; the engineering progress data includes at least one or more of:

Positioning data of the operation executing node, altitude data of the operation executing node, multimedia data of an operation site of the operation executing node and working signal data of the operation executing node.

5. The method according to claim 1, wherein controlling each flow link of the communication engineering task life cycle according to the obtained engineering progress data comprises:

and monitoring the execution progress of each task node according to the acquired engineering progress data of each task node, controlling the execution connection of each task node, and detecting the quality of the execution result of the communication engineering task.

6. A control device for a full lifecycle of a communications engineering task, comprising: a memory, a processor;

the memory stores code, and the processor executes the code stored in the memory to perform the communication engineering task full life cycle control method according to any one of claims 1 to 5.

7. A computer readable storage medium, wherein computer executable instructions are stored in the computer readable storage medium, the computer executable instructions when executed by a processor are for implementing the control method of the full life cycle of the communication engineering task according to any one of claims 1 to 5.