CN117098174A - Mining wireless communication monitoring method, system and readable storage medium - Google Patents
Mining wireless communication monitoring method, system and readable storage medium Download PDFInfo
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Abstract
The application provides a mining wireless communication monitoring method, a mining wireless communication monitoring system and a mining wireless communication monitoring readable storage medium, and relates to the technical field of data processing, wherein the mining wireless communication monitoring method comprises the following steps: the method comprises the steps of executing data interaction on a target monitoring area to generate a basic data set, executing communication equipment information reading on communication equipment, configuring interaction cluster nodes of the communication equipment, constructing communication fixed interference data, interactively obtaining equipment information in the target monitoring area, constructing communication variable interference data, generating communication influence data according to the communication node calling the variable interference data and the fixed interference data, generating acquisition influence data, and generating communication early warning information of a communication result according to the acquisition influence data and the communication influence data.
Description
Technical Field
The application relates to the technical field of data processing, in particular to a mining wireless communication monitoring method, a mining wireless communication monitoring system and a readable storage medium.
Background
The coal mine production operation is mainly performed on an underground working surface, and has the characteristics of severe working environment, such as narrow working area, poor illumination, wetness, corrosiveness, multiple unsafe factors, such as threat of accidents of water, fire, gas, roof and the like, high mobility of personnel and equipment and the like; from the production operation flow, the underground multi-working-class combined operation is characterized; under the working condition, the information transmission of the mining wireless communication system is required to be timely and accurate. Along with the continuous improvement of the modernization degree of coal production, the requirements on communication means and system functions are also continuously increased. Ensuring that communication information can be timely, accurately, quickly and in real time commanded is extremely important for safe production of coal.
The lack of control over monitoring area communication equipment in the prior art today results in the technical problem of low mining wireless communication stability.
Disclosure of Invention
The application provides a mining wireless communication monitoring method, a mining wireless communication monitoring system and a mining wireless communication monitoring readable storage medium, which are used for solving the technical problem of low mining wireless communication stability caused by lack of control over communication equipment in a monitoring area in the prior art.
In view of the above, the application provides a mining wireless communication monitoring method, a mining wireless communication monitoring system and a readable storage medium.
In a first aspect, the present application provides a mining wireless communication monitoring method, the method comprising: setting a target monitoring area, performing data interaction on the target monitoring area, and generating a basic data set, wherein the basic data set is a fixed article data set in the target monitoring area; executing communication equipment information reading on the communication equipment to obtain a communication equipment information reading result, wherein the communication equipment information reading result comprises attribute data, positioning data and signal interaction data of the communication equipment; constructing an initial acquisition data quality fluctuation map according to the attribute data and the environment data set; configuring an interaction cluster node of the communication equipment, and constructing communication fixed interference data according to the fixed article data set, the communication equipment information reading result and the interaction cluster node; device information in the target monitoring area is obtained interactively, and variable interference data of communication is constructed based on the device information, the interactive cluster nodes and the communication device information reading result; reading the interactive cluster node and a communication node of the communication equipment, and calling the variable interference data and the fixed interference data according to the communication node to generate communication influence data; acquiring a data acquisition time node of the communication equipment, and generating acquisition influence data according to the data acquisition time node matched with the initial acquisition data quality fluctuation mapping; and generating communication early warning information of a communication result according to the communication influence data and the acquisition influence data.
In a second aspect, the present application provides a mining wireless communication monitoring system, the system comprising: the data interaction module is used for setting a target monitoring area, executing data interaction on the target monitoring area and generating a basic data set, wherein the basic data set is a fixed article data set in the target monitoring area; the information reading module is used for reading the information of the communication equipment to obtain the information reading result of the communication equipment, wherein the information reading result of the communication equipment comprises attribute data, positioning data and signal interaction data of the communication equipment; the first fluctuation mapping module is used for constructing initial acquisition data quality fluctuation mapping according to the attribute data and the environment data set; the data construction module is used for configuring the interactive cluster nodes of the communication equipment and constructing communication fixed interference data according to the fixed article data set, the communication equipment information reading result and the interactive cluster nodes; the data reading module is used for interactively obtaining equipment information in the target monitoring area and constructing variable interference data of communication based on the equipment information, the interactive cluster nodes and the communication equipment information reading result; the data generation module is used for reading the interaction cluster node and the communication node of the communication equipment, and calling the variable interference data and the fixed interference data according to the communication node to generate communication influence data; the second fluctuation mapping module is used for acquiring a data acquisition time node of the communication equipment and generating acquisition influence data according to the fact that the data acquisition time node is matched with the initial acquisition data quality fluctuation mapping; and the communication early warning module is used for generating communication early warning information of a communication result according to the communication influence data and the acquisition influence data.
In a third aspect, a computer readable storage medium having stored thereon a computer program which when executed by a processor performs the steps of: setting a target monitoring area, performing data interaction on the target monitoring area, and generating a basic data set, wherein the basic data set is a fixed article data set in the target monitoring area; executing communication equipment information reading on the communication equipment to obtain a communication equipment information reading result, wherein the communication equipment information reading result comprises attribute data, positioning data and signal interaction data of the communication equipment; constructing an initial acquisition data quality fluctuation map according to the attribute data and the environment data set; configuring an interaction cluster node of the communication equipment, and constructing communication fixed interference data according to the fixed article data set, the communication equipment information reading result and the interaction cluster node; device information in the target monitoring area is obtained interactively, and variable interference data of communication is constructed based on the device information, the interactive cluster nodes and the communication device information reading result; reading the interactive cluster node and a communication node of the communication equipment, and calling the variable interference data and the fixed interference data according to the communication node to generate communication influence data; acquiring a data acquisition time node of the communication equipment, and generating acquisition influence data according to the data acquisition time node matched with the initial acquisition data quality fluctuation mapping; and generating communication early warning information of a communication result according to the communication influence data and the acquisition influence data.
One or more technical schemes provided by the application have at least the following technical effects or advantages:
the application provides a mining wireless communication monitoring method, a mining wireless communication monitoring system and a mining wireless communication monitoring readable storage medium, relates to the technical field of data processing, solves the technical problem of low mining wireless communication stability caused by lack of control over monitoring area communication equipment in the prior art, realizes reasonable and accurate control over monitoring area communication equipment, and improves mining wireless communication stability.
Drawings
FIG. 1 is a schematic flow chart of a mining wireless communication monitoring method;
FIG. 2 is a schematic diagram of a process for constructing quality fluctuation mapping of initial acquired data in a mining wireless communication monitoring method;
FIG. 3 is a schematic diagram of a process for generating acquisition influence data in a mining wireless communication monitoring method;
FIG. 4 is a schematic diagram of a pre-warning compensation flow in a mining wireless communication monitoring method;
FIG. 5 is a schematic diagram of a process of equipment maintenance and management in a mining wireless communication monitoring method;
FIG. 6 is a schematic diagram of a mining wireless communication monitoring system;
fig. 7 is an internal structural diagram of a computer device in one embodiment.
Reference numerals illustrate: the system comprises a data interaction module 1, an information reading module 2, a first fluctuation mapping module 3, a data construction module 4, a data reading module 5, a data generation module 6, a second fluctuation mapping module 7 and a communication early warning module 8.
Detailed Description
The application provides a mining wireless communication monitoring method, a mining wireless communication monitoring system and a readable storage medium, which are used for solving the technical problem of low mining wireless communication stability caused by lack of control over communication equipment in a monitoring area in the prior art.
Embodiment one:
as shown in fig. 1, an embodiment of the present application provides a mining wireless communication monitoring method, which includes:
step S100: setting a target monitoring area, performing data interaction on the target monitoring area, and generating a basic data set, wherein the basic data set is a fixed article data set in the target monitoring area;
specifically, the mining wireless communication monitoring method provided by the embodiment of the application is applied to a mining wireless communication monitoring system, in order to ensure the accuracy of detection of mining wireless communication, firstly, a mining wireless communication area to be monitored is defined, the mining wireless communication area within a certain range is defined as a target detection area, when the wireless working frequency band defined in the certain range is more than 2.4 GHz, the mining wireless communication distance is less than 800m, further, the system and the target monitoring area are subjected to data interaction, namely, data transmission is carried out between a system end and a monitoring service end, all data transmitted between the system end and the monitoring service end are integrated and summarized to form a basic data set, the basic data set is a fixed article data set in the target monitoring area, the fixed article is an immovable or indispensable mining article, and the like, and the mining wireless communication is monitored as an important reference basis for later stage.
Step S200: executing communication equipment information reading on the communication equipment to obtain a communication equipment information reading result, wherein the communication equipment information reading result comprises attribute data, positioning data and signal interaction data of the communication equipment;
specifically, the mining wireless communication monitoring system is in communication connection with communication equipment, the communication equipment is used for monitoring mining wireless communication data in a target monitoring area, further, reading operation is performed on communication equipment information in the communication equipment, namely, reading data in end-to-end transmission of data realized by a computer network system and a data communication system, the read data information is recorded as a communication equipment information reading result, wherein the communication equipment reading result comprises attribute data, positioning data and signal interaction data of the communication equipment, the attribute data of the communication equipment comprises two angles, one of the communication equipment comprises an acquisition end, namely, a sensor end, the sensor end is interfered by an acquisition environment, so that the output result may not have the conditions of complete data, fluctuation, abnormality and the like, the communication angle of the communication equipment, namely, the transmission angle of the communication data after the acquisition of the data is finished, the acquired data corresponds to the attribute, the positioning data refers to position source data sent by the communication signal in the target monitoring area, the signal interaction data refers to the strength of the communication signal in the target monitoring area, the signal interaction data is the strength of the communication signal in the target monitoring area, and the mining wireless monitoring area is further realized.
Step S300: constructing an initial acquisition data quality fluctuation map according to the attribute data and the environment data set;
further, as shown in fig. 2, step S300 of the present application further includes:
step S310: collecting environmental data of the target monitoring area, and constructing an environmental data set, wherein the environmental data set comprises environmental data extremum;
step S320: performing quality fitting on sensor acquisition data under the environment data set based on the attribute data to generate a quality fitting result;
step S330: and constructing the initial acquisition data quality fluctuation map according to the quality fitting result, the environment data set and the attribute data.
Specifically, in order to ensure the accuracy of the quality fluctuation mapping of the initial acquisition data constructed later, attribute data contained in the communication equipment information reading result is required to be combined with environmental data in the current target monitoring area, the environmental data set is to acquire environmental data by the target monitoring area, namely, acquiring data such as wireless signal coverage in the target monitoring area and signal frequency bands and data transmission bandwidths in the target monitoring area, so as to construct an environmental data set, wherein the environmental data set comprises environmental data extremum, the environmental data extremum refers to a maximum value and a minimum value of the data such as the wireless signal coverage in the target monitoring area and the signal frequency bands and the data transmission bandwidths in the target monitoring area, the attribute data is to acquire data quality fitting of the sensor under the environmental data set based on the attribute data, namely, a statistical algorithm is applied to the attribute data so as to estimate a set of sensor acquisition data parameter values, the sensor acquisition data under the environmental data set can be described as accurately as possible, the sensor acquisition data are matched with the sensor acquisition data, the sensor acquisition data are mapped to the quality value, namely, the attribute data is further mapped to the environmental data quality in the initial quality data set according to the attribute data, the attribute data is fit to the attribute data, the quality fitting relation is established, the quality fitting is further is completed, the fitting is completed between the attribute data and the attribute data acquisition data is the quality fitting value is calculated, and the quality fitting is completed, the attribute data can have a plurality of values corresponding to the values, and the quality fluctuation map of the initial acquired data comprises a normal fluctuation map and an abnormal fluctuation map, wherein the normal fluctuation map refers to fluctuation caused by accidental and unavoidable factors, the normal fluctuation data obeys normal distribution, the abnormal fluctuation map refers to quality data fluctuation caused by systematic reasons, the numerical value and the positive and negative signs of the dispersion are always kept as constant values or are changed according to a certain rule, the directivity is provided, and a difference with large difference appears, so that the mining wireless communication is monitored and tamped for the subsequent realization.
Step S400: configuring an interaction cluster node of the communication equipment, and constructing communication fixed interference data according to the fixed article data set, the communication equipment information reading result and the interaction cluster node;
specifically, in order to determine communication interference caused by fixed articles included in the target monitoring area, it is necessary to configure an interaction cluster node of the communication device in the target area, where the interaction cluster node is a signal data node for performing signal data interaction with the communication device in the target area, further, by using a fixed article data set determined in the target area, a communication device information reading result and the interaction cluster node as determination data, the communication interference formed by the fixed articles having signal data interaction included in the target monitoring area is determined, that is, attribute data, positioning data and signal interaction data of the fixed articles having signal data interaction are extracted, and meanwhile, whether an abnormal fluctuation map exists in an initial acquired data quality fluctuation map is determined, and the obtained data is extracted and integrated and then is recorded as fixed interference data in the target monitoring area, so that a limited effect is achieved in monitoring mining wireless communication.
Step S500: device information in the target monitoring area is obtained interactively, and variable interference data of communication is constructed based on the device information, the interactive cluster nodes and the communication device information reading result;
specifically, data interaction is performed on communication equipment arranged in a target area, so that equipment information of the communication equipment in the target monitoring area is obtained in an interaction mode, the equipment information of the communication equipment can comprise basic information of various computer terminal equipment used by a system and including mobile and fixed terminals, such as position information, wifi list information, mac address, CPU information, memory information, SD card information, operating system version and the like of the communication equipment, further, variable interference data in communication in the target monitoring area is constructed based on variable influence information of the equipment in the obtained equipment information, non-fixed data interference nodes in interaction cluster nodes, attribute data, positioning data and signal interaction data in a reading result of the communication equipment information, and the variable interference data is interference data which can be changed randomly relative to the fixed interference data in the target monitoring area and interfere with communication signals, so that accuracy of monitoring mining wireless communication is achieved in a later period is improved.
Step S600: reading the interactive cluster node and a communication node of the communication equipment, and calling the variable interference data and the fixed interference data according to the communication node to generate communication influence data;
specifically, in order to accurately determine the data affecting communication in the target monitoring area, it is first necessary to read the communication nodes where the interaction cluster node and the communication device are located, which means to extract the communication signal interaction data contained in the interaction cluster node and the communication signal interaction data contained in the communication node where the communication device is located, and at the same time, according to the position information where the communication device records the communication signal data interaction in the communication node, call the variable interference data and the fixed interference data contained in the current position information, which means to determine whether the position information of the current interference data is variable, if the position information of the current interference data is variable, the interference data called by the communication node at this time is fixed interference data, and if the position information of the current interference data is not variable, finally, respectively perform data fusion on the variable interference data and the fixed interference data, that is, combine, correlate and combine the variable interference data with the fixed interference data, and obtain more accurate data estimation, thereby realizing that the position information of the variable interference data and the fixed interference data is monitored in the target monitoring area, and the complete wireless evaluation data is generated when the position information of the current interference data is variable, and the communication data is completely processed, and the wireless interference data is generated as the real-time reference data.
Step S700: acquiring a data acquisition time node of the communication equipment, and generating acquisition influence data according to the data acquisition time node matched with the initial acquisition data quality fluctuation mapping;
further, as shown in fig. 3, step S700 of the present application further includes:
step S710: reading interaction cluster node interaction data of the previous time node according to the data acquisition time node;
step S720: the interaction data are used as the associated environment data of the data acquisition time node, wherein the interaction data are interaction cluster node interaction data of the last time node read according to the data acquisition time node;
step S730: and matching the initial acquisition data quality fluctuation mapping according to the associated environment data to generate acquisition influence data.
Further, step S700 of the present application further includes:
step S740: judging whether the acquisition influence data is higher than a preset influence threshold value or not;
step S750: when the acquisition influence data is higher than the preset influence threshold value, generating a mode switching instruction;
step S760: controlling the variable interference data and the fixed interference data under the current time node to perform channel interaction optimizing through the mode switching instruction, and generating a channel interaction optimizing result;
step S770: and carrying out communication management according to the channel interaction optimizing result.
Specifically, the node position of the communication node cannot be accurately determined according to the acquired data in the communication equipment, so that the data acquisition time node when the communication equipment is subjected to data acquisition is firstly required to be recorded, further, the data acquisition time node is matched with the initial acquisition data quality fluctuation map, one time node is selected from the data acquisition time nodes according to the data acquisition time node, the interaction data of the interaction cluster node of the last time node is read, the interaction data of the interaction cluster node of the last time node comprise communication signal data of a system end and the communication signal number in a target monitoring area, further, the read interaction data are used as associated environment data in the data acquisition time node, the associated environment data are used as the time node with data acquisition, the interference environment data in the target monitoring area when the communication data are interacted are also included, the associated environment data are used as comparison data, the comparison ratio is performed on the data with the initial acquisition data quality fluctuation map, the data are successfully compared with the normal fluctuation map in the initial acquisition data quality fluctuation map, and the influence is taken as the acquisition data.
Because the acquired data quality is poor, in order to ensure the accuracy of the acquired influence data, firstly, the interactive channel where the interactive data is located needs to be optimized, firstly, the current acquired influence data and a preset influence threshold value need to be judged, the preset influence threshold value is preset by training an acquisition influence data set with qualified influence degree, if the acquired influence data is higher than the preset influence threshold value, a mode switching instruction is generated, the mode switching instruction is used for adaptively adjusting and switching a channel mode according to the data influence degree of the current acquired influence data, and further, the channel interaction optimization is conducted on the variable interference data and the fixed interference data under the current time node through the mode switching instruction, namely, the influence degree is respectively compared with the influence degree of the acquired influence data in the variable interference data channel and the influence data acquired in the fixed interference data channel, namely, the influence degree is inversely related to the channel priority, namely, the lower the influence degree is the better the corresponding channel interaction optimization result is generated, and finally, the communication influence in the target monitoring area is better managed according to the channel interaction optimization result.
Step S800: and generating communication early warning information of a communication result according to the communication influence data and the acquisition influence data.
Further, as shown in fig. 4, step S800 of the present application further includes:
step S810: recording node receiving data of the interactive cluster nodes;
step S820: performing data quality verification on the node received data to generate a data quality verification result;
step S830: performing deviation analysis of mapping communication early warning information based on the data quality verification result, and generating early warning compensation data according to the deviation analysis result;
step S840: and executing early warning compensation of the subsequent communication early warning through the early warning compensation data.
Further, step S800 of the present application further includes:
step S850: collecting continuous operation time of the communication equipment to generate first associated data;
step S860: acquiring equipment use duration data of the communication equipment to generate second association data;
step S870: distributing association coefficients according to the attribute data, and performing association calculation on the first association data and the second association data according to the association coefficients to generate equipment stability values;
step S880: and carrying out influence adjustment on the acquisition influence data based on the equipment stability value, and regenerating communication early warning information.
Specifically, in order to promote the efficiency of monitoring and early warning for mine wireless communication, communication influence data generated by calling variable interference data and fixed interference data according to the communication nodes and acquisition influence data generated by matching initial acquisition data quality fluctuation mapping according to the data acquisition time nodes are required to be used as basic judgment data, firstly, continuous operation time acquisition of equipment is carried out on the communication equipment, namely continuous data acquisition of the continuous time nodes is carried out in the operation time of the communication equipment, so that the continuous data acquisition of the continuous time nodes is recorded as first association data, further, equipment use time long data of the communication equipment is acquired, namely time length data between the communication equipment starting operation time nodes and the ending operation time nodes is extracted, so that the time length data is recorded as second association data, meanwhile, according to attribute data distribution association coefficients, namely distribution proportion coefficients in a target monitoring area occupied by the attribute data in each communication equipment are calculated according to the distribution association coefficients of the attribute data, namely the first association data and the second association data are closely associated on the communication data, the first association data and the second association data are recorded in the communication equipment, meanwhile, the equipment is further recorded as a stable and the stability of the equipment is regulated according to the stability of the data, the stability of the data is improved, the stability of the equipment is improved, and the stability of the equipment is improved, and carrying out communication early warning in the target monitoring area, and continuously regenerating communication early warning information in the target area according to the adjustment of the influence degree of the equipment stability value on the acquired influence data.
Because of the deviation of the communication early warning information in the generation process, in order to avoid the deviation, the node receiving data in the interaction cluster node of the communication equipment in the target monitoring area needs to be recorded, the data received by the node can comprise communication signal data, communication position data, communication interaction data and the like, further, the data quality of the data received by the node is verified, the data received by the node is compared and verified in a mode that one evaluation rule dimension provides one measurement and management information and data, the verification result is recorded as a data quality verification result, meanwhile, the deviation analysis of the mapping communication early warning information is carried out based on the data quality verification result, namely, when the data quality verification result does not meet the data quality verification requirement, the communication early warning information is generated through mapping, when a value is taken in the communication early warning information, the data quality verification result has only one value, and the data quality verification result has one value, one or more early warning values can also correspond to the communication early warning information, early warning deviation analysis is carried out on the communication early warning new information, namely, the communication early warning information corresponding to the communication early warning information is not generated when the data quality verification result does not meet the data quality verification requirement, or one or more communication early warning information is generated when the data quality verification result meets the data quality verification requirement, the communication early warning information is regarded as the deviation analysis result, and finally, the communication early warning information is updated and compensated according to the deviation analysis result, thereby obtaining compensation data of communication early warning, and carrying out early warning compensation or early warning update execution operation on the subsequent communication early warning through the early warning compensation data, therefore, the mining wireless communication is monitored more accurately in the later period.
Further, as shown in fig. 5, step S900 of the present application further includes:
step S910: judging whether the node received data has continuous quality verification abnormality or not;
step S920: generating equipment exception reporting errors when continuous quality verification exceptions exist in the node receiving data;
step S930: and carrying out equipment maintenance management on the communication equipment through the equipment abnormality error reporting.
Specifically, to ensure the accuracy of maintenance management of the communication device when there is an abnormality in the communication device in the target monitoring area, continuous data quality verification is performed on the node received data of the node of the communication device, that is, whether the node received data has a continuous quality verification abnormality or not is determined, that is, the quality of the communication data received in each time node in the communication node is verified in sequence, if there are two or more communication data with abnormal verification quality, the node received data is determined to have a continuous quality verification abnormality, when the node received data has a continuous quality verification abnormality, a device abnormality error report is generated, which may be information for reminding that the communication device in the target monitoring area has an abnormality when running, for example, the communication device maintenance management of the communication device in the target monitoring area is performed by the communication device abnormality information in the device abnormality report, for example, the network connection of the communication device is checked, the hardware driving of the device is checked, and the software failure is checked, so that the communication device maintenance management is performed more accurately based on the device abnormality report.
In summary, the mining wireless communication monitoring method provided by the embodiment of the application at least has the following technical effects that the reasonable and accurate management and control of monitoring area communication equipment is realized, and the mining wireless communication stability is improved.
Embodiment two:
based on the same inventive concept as the mining wireless communication monitoring method in the foregoing embodiments, as shown in fig. 6, the present application provides a mining wireless communication monitoring system, which includes:
the data interaction module 1 is used for setting a target monitoring area, executing data interaction on the target monitoring area and generating a basic data set, wherein the basic data set is a fixed article data set in the target monitoring area;
the information reading module 2 is used for executing communication equipment information reading on the communication equipment to obtain a communication equipment information reading result, wherein the communication equipment information reading result comprises attribute data, positioning data and signal interaction data of the communication equipment;
the first fluctuation mapping module 3 is used for constructing an initial acquisition data quality fluctuation mapping according to the attribute data and the environment data set;
the data construction module 4 is used for configuring the interactive cluster nodes of the communication equipment, and constructing the communicated fixed interference data according to the fixed article data set, the communication equipment information reading result and the interactive cluster nodes;
the data reading module 5 is used for interactively obtaining equipment information in the target monitoring area, and constructing variable interference data of communication based on the equipment information, the interactive cluster nodes and the communication equipment information reading result;
the data generation module 6 is configured to read the interaction cluster node and a communication node of the communication device, and call the variable interference data and the fixed interference data according to the communication node to generate communication influence data;
the second fluctuation mapping module 7 is used for acquiring a data acquisition time node of the communication equipment, and generating acquisition influence data according to the fact that the data acquisition time node is matched with the initial acquisition data quality fluctuation mapping;
the communication early warning module 8 is used for generating communication early warning information of a communication result according to the communication influence data and the acquisition influence data.
Further, the system further comprises:
the data set construction module is used for collecting environmental data of the target monitoring area and constructing the environmental data set, wherein the environmental data set comprises an environmental data extremum;
the fitting module is used for carrying out quality fitting on the sensor acquisition data under the environment data set based on the attribute data to generate a quality fitting result;
and the first fluctuation mapping module is used for constructing the quality fluctuation mapping of the initial acquired data according to the quality fitting result, the environment data set and the attribute data.
Further, the system further comprises:
the reading module is used for reading interaction data of the interaction cluster nodes of the previous time node according to the data acquisition time node;
the environment data module is used for taking the interaction data as the associated environment data of the data acquisition time node, wherein the interaction data is interaction data of the interaction cluster node of the last time node read according to the data acquisition time node;
and the second fluctuation mapping module is used for matching the initial acquisition data quality fluctuation mapping according to the associated environment data to generate acquisition influence data.
Further, the system further comprises:
the first judging module is used for judging whether the acquired influence data is higher than a preset influence threshold value or not;
the second judging module is used for generating a mode switching instruction when the acquisition influence data is higher than the preset influence threshold value;
the interactive optimizing module is used for controlling the variable interference data and the fixed interference data under the current time node through the mode switching instruction to perform channel interactive optimizing to generate a channel interactive optimizing result;
and the communication management module is used for carrying out communication management according to the channel interaction optimizing result.
Further, the system further comprises:
the recording module is used for recording the node receiving data of the interactive cluster nodes;
the verification module is used for carrying out data quality verification on the data received by the node and generating a data quality verification result;
the deviation analysis module is used for carrying out deviation analysis of the mapping communication early warning information based on the data quality verification result and generating early warning compensation data according to the deviation analysis result;
and the early warning compensation module is used for executing early warning compensation of subsequent communication early warning through the early warning compensation data.
Further, the system further comprises:
the verification abnormality module is used for judging whether continuous quality verification abnormality exists in the node received data or not;
the abnormal error reporting module is used for generating equipment abnormal error reporting when the continuous quality verification abnormality exists in the node received data;
and the maintenance management module is used for carrying out equipment maintenance management on the communication equipment through the equipment abnormality error reporting.
Further, the system further comprises:
the time acquisition module is used for acquiring the continuous operation time of the communication equipment to generate first associated data;
the using time length data module is used for acquiring equipment using time length data of the communication equipment and generating second associated data;
the calculating module is used for distributing association coefficients according to the attribute data, carrying out association calculation on the first association data and the second association data according to the association coefficients, and generating a device stability value;
and the influence adjustment module is used for carrying out influence adjustment on the acquired influence data based on the equipment stability value and regenerating communication early warning information.
The foregoing detailed description of a mining wireless communication monitoring method will be clear to those skilled in the art, and the device disclosed in this embodiment is relatively simple in description, and the relevant points refer to the description of the method section.
In one embodiment, a computer readable storage medium is provided, the computer device may be a server, and the internal structure of the computer device may be as shown in fig. 7. The computer device includes a processor, a memory, and a network interface connected by a system bus. Wherein the processor of the computer device is configured to provide computing and control capabilities. The memory of the computer device includes a non-volatile storage medium and an internal memory. The non-volatile storage medium stores an operating system, computer programs, and a database. The internal memory provides an environment for the operation of the operating system and computer programs in the non-volatile storage media. The database of the computer device is used for storing news data, time attenuation factors and other data. The network interface of the computer device is used for communicating with an external terminal through a network connection. The computer program when executed by a processor implements a mining wireless communication monitoring method.
It will be appreciated by those skilled in the art that the structure shown in FIG. 7 is merely a block diagram of some of the structures associated with the present inventive arrangements and is not limiting of the computer device to which the present inventive arrangements may be applied, and that a particular computer device may include more or fewer components than shown, or may combine some of the components, or have a different arrangement of components.
The previous description of the disclosed embodiments is provided to enable any person skilled in the art to make or use the present application. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the spirit or scope of the application. Thus, the present application is not intended to be limited to the embodiments shown herein but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.
Claims (9)
1. A mining wireless communication monitoring method, the method comprising:
setting a target monitoring area, performing data interaction on the target monitoring area, and generating a basic data set, wherein the basic data set is a fixed article data set in the target monitoring area;
executing communication equipment information reading on the communication equipment to obtain a communication equipment information reading result, wherein the communication equipment information reading result comprises attribute data, positioning data and signal interaction data of the communication equipment;
constructing an initial acquisition data quality fluctuation map according to the attribute data and the environment data set;
configuring an interaction cluster node of the communication equipment, and constructing communication fixed interference data according to the fixed article data set, the communication equipment information reading result and the interaction cluster node;
device information in the target monitoring area is obtained interactively, and variable interference data of communication is constructed based on the device information, the interactive cluster nodes and the communication device information reading result;
reading the interactive cluster node and a communication node of the communication equipment, and calling the variable interference data and the fixed interference data according to the communication node to generate communication influence data;
acquiring a data acquisition time node of the communication equipment, and generating acquisition influence data according to the data acquisition time node matched with the initial acquisition data quality fluctuation mapping;
and generating communication early warning information of a communication result according to the communication influence data and the acquisition influence data.
2. The method of claim 1, wherein the method further comprises:
collecting environmental data of the target monitoring area, and constructing an environmental data set, wherein the environmental data set comprises environmental data extremum;
performing quality fitting on sensor acquisition data under the environment data set based on the attribute data to generate a quality fitting result;
and constructing the initial acquisition data quality fluctuation map according to the quality fitting result, the environment data set and the attribute data.
3. The method of claim 2, wherein the method further comprises:
reading interaction cluster node interaction data of the previous time node according to the data acquisition time node;
the interaction data are used as the associated environment data of the data acquisition time node, wherein the interaction data are interaction cluster node interaction data of the last time node read according to the data acquisition time node;
and matching the initial acquisition data quality fluctuation mapping according to the associated environment data to generate acquisition influence data.
4. The method of claim 1, wherein the method further comprises:
judging whether the acquisition influence data is higher than a preset influence threshold value or not;
when the acquisition influence data is higher than the preset influence threshold value, generating a mode switching instruction;
controlling the variable interference data and the fixed interference data under the current time node to perform channel interaction optimizing through the mode switching instruction, and generating a channel interaction optimizing result;
and carrying out communication management according to the channel interaction optimizing result.
5. The method of claim 1, wherein the method further comprises:
recording node receiving data of the interactive cluster nodes;
performing data quality verification on the node received data to generate a data quality verification result;
performing deviation analysis of mapping communication early warning information based on the data quality verification result, and generating early warning compensation data according to the deviation analysis result;
and executing early warning compensation of the subsequent communication early warning through the early warning compensation data.
6. The method of claim 5, wherein the method further comprises:
judging whether the node received data has continuous quality verification abnormality or not;
generating equipment exception reporting errors when continuous quality verification exceptions exist in the node receiving data;
and carrying out equipment maintenance management on the communication equipment through the equipment abnormality error reporting.
7. The method of claim 1, wherein the method further comprises:
collecting continuous operation time of the communication equipment to generate first associated data;
acquiring equipment use duration data of the communication equipment to generate second association data;
distributing association coefficients according to the attribute data, and performing association calculation on the first association data and the second association data according to the association coefficients to generate equipment stability values;
and carrying out influence adjustment on the acquisition influence data based on the equipment stability value, and regenerating communication early warning information.
8. A mining wireless communication monitoring system, the system comprising:
the data interaction module is used for setting a target monitoring area, executing data interaction on the target monitoring area and generating a basic data set, wherein the basic data set is a fixed article data set in the target monitoring area;
the information reading module is used for reading the information of the communication equipment to obtain the information reading result of the communication equipment, wherein the information reading result of the communication equipment comprises attribute data, positioning data and signal interaction data of the communication equipment;
the first fluctuation mapping module is used for constructing initial acquisition data quality fluctuation mapping according to the attribute data and the environment data set;
the data construction module is used for configuring the interactive cluster nodes of the communication equipment and constructing communication fixed interference data according to the fixed article data set, the communication equipment information reading result and the interactive cluster nodes;
the data reading module is used for interactively obtaining equipment information in the target monitoring area and constructing variable interference data of communication based on the equipment information, the interactive cluster nodes and the communication equipment information reading result;
the data generation module is used for reading the interaction cluster node and the communication node of the communication equipment, and calling the variable interference data and the fixed interference data according to the communication node to generate communication influence data;
the second fluctuation mapping module is used for acquiring a data acquisition time node of the communication equipment and generating acquisition influence data according to the fact that the data acquisition time node is matched with the initial acquisition data quality fluctuation mapping;
and the communication early warning module is used for generating communication early warning information of a communication result according to the communication influence data and the acquisition influence data.
9. A computer readable storage medium, on which a computer program is stored, characterized in that the computer program, when being executed by a processor, implements the steps of the method of any of claims 1 to 7.
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