CN115633321B - Wireless communication network monitoring method and system - Google Patents

Abstract

The invention relates to the technical field of remote monitoring, and particularly discloses a wireless communication network monitoring method and system, wherein the method comprises the steps of receiving monitoring points containing regional parameters input by a user, and determining and configuring a transit gateway according to the monitoring points; acquiring regional data acquired by monitoring equipment based on a transit gateway; generating an area monitoring report according to the area data; wherein the region parameters include a region type and a region range; the zone types include an unmanned zone and a manned zone. The invention receives the monitoring point position input by the user and the monitoring equipment at the monitoring point position, classifies the monitoring point position according to the monitoring equipment, determines the transit gateway, implants the identification model at the transit gateway, and carries out identification screening on the regional image to obtain data more worth transmitting; the invention processes the data acquired by the monitoring equipment through the transfer gateway with the identification function, and improves the data transmission efficiency by adopting a star structure.

Description

Wireless communication network monitoring method and system

Technical Field

The invention relates to the technical field of remote monitoring, in particular to a wireless communication network monitoring method and system.

Background

Wireless monitoring (Wireless monitoring) refers to a monitoring system that uses radio waves to transmit video, sound, data, etc. signals. The wireless monitoring does not need to conduct cable defense arrangement, so that the initial construction cost is greatly reduced, and the wireless monitoring is particularly suitable for large application scenes in a monitored area.

In a wireless monitoring system, the data transmission process is a very important process, the importance of the data transmission process even exceeds that of the image acquisition process, and when the total budget is the same, the wireless monitoring system is likely to have a certain reduction in monitoring quality compared with a wired monitoring system; therefore, how to optimize the data transmission process in the wireless monitoring system and use more cost in improving the monitoring quality is a technical problem to be solved by the technical scheme of the invention.

Disclosure of Invention

The invention aims to provide a wireless communication network monitoring method and system for solving the problems in the background technology.

In order to achieve the above purpose, the present invention provides the following technical solutions:

a method of wireless communication network monitoring, the method comprising:

receiving a monitoring point position containing regional parameters input by a user, and determining and configuring a transit gateway according to the monitoring point position;

acquiring regional data acquired by monitoring equipment based on a transit gateway;

generating an area monitoring report according to the area data;

wherein the region parameters include a region type and a region range; the zone types include an unmanned zone and a manned zone.

As a further scheme of the invention: the step of receiving the monitoring point position containing the regional parameters input by the user and determining and configuring the transit gateway according to the monitoring point position comprises the following steps:

establishing a map with a ruler, and receiving the region range and the region type of the region range input by a user based on the map with the ruler;

reading equipment parameters of alternative monitoring equipment according to the area type, and determining and displaying monitoring points in the area range according to the equipment parameters; the monitoring point position contains the model of monitoring equipment;

receiving selection information input by a user, and determining a monitoring point position according to the selection information;

and clustering the monitoring points according to the model of the monitoring equipment corresponding to the monitoring points, and determining and configuring the transit gateway.

As a further scheme of the invention: the step of establishing the map with the scale and receiving the area range and the area type input by the user based on the map with the scale comprises the following steps:

receiving position information input by a user, and acquiring a map according to the position information;

copying the obtained map, and inserting a scale with preset granularity into the map;

receiving contour information input by a user based on a map containing a scale, and determining a region range according to the contour information;

the open type definition port acquires the zone type of the zone range based on the type definition port.

As a further scheme of the invention: the step of reading the equipment parameters of the alternative monitoring equipment according to the area type and determining and displaying the monitoring point positions in the area range according to the equipment parameters comprises the following steps:

when the area type is an unmanned area, reading alternative monitoring equipment with a color value identification function;

when the zone type is a person zone, reading alternative monitoring equipment with a heat source identification function;

reading equipment parameters of monitoring equipment, and calculating a monitoring range according to the equipment parameters; the equipment parameters comprise equipment height and equipment angle;

and matching the monitoring range with the regional range, and determining and displaying the monitoring point positions.

As a further scheme of the invention: the step of clustering the monitoring points according to the model of the monitoring equipment corresponding to the monitoring points, and determining and configuring the transit gateway comprises the following steps:

the types of the monitoring equipment corresponding to the monitoring points are sequentially read, and the monitoring points with the same types are classified into one type;

sequentially reading monitoring points in the similar monitoring points as reference points, and calculating the distances between other monitoring points and the reference points;

calculating the number of the point positions with the distance smaller than a preset distance threshold value, and taking the number of the point positions as the aggregation degree of the reference point positions;

clustering the monitoring points according to the aggregation degree, setting a transit gateway, and configuring the transit gateway according to the model of the monitoring equipment.

As a further scheme of the invention: the step of acquiring the regional data acquired by the monitoring equipment based on the transit gateway comprises the following steps:

when the region type is an unmanned region, acquiring a region image acquired by the monitoring equipment in real time based on the transit gateway;

inputting the region image into a trained comparison model, comparing the region image with a reserved image, and calculating to obtain a similarity value;

when the similarity value is smaller than a preset similarity threshold value, extracting a retention image in the comparison model, taking the region image as a new retention image, and repeatedly executing the content;

and when the region type is a man-made region, acquiring a region image containing heat source information in real time based on the transfer gateway, and eliminating the unmanned image according to the heat source information.

As a further scheme of the invention: the step of generating the area monitoring report according to the area data comprises the following steps:

reading the reserved image to generate an unmanned area video;

reading and removing the area image of the unmanned image to generate a manned area video;

transmitting the unmanned area video and the manned area video to a preset detection end to obtain an area monitoring report;

wherein, unmanned zone video and have the district video all to contain the time axis.

The technical scheme of the invention also provides a wireless communication network monitoring system, which comprises:

the gateway configuration module is used for receiving the monitoring point positions containing the regional parameters input by the user, and determining and configuring the transit gateway according to the monitoring point positions;

the data acquisition module is used for acquiring the regional data acquired by the monitoring equipment based on the transit gateway;

the report generation module is used for generating an area monitoring report according to the area data;

wherein the region parameters include a region type and a region range; the zone types include an unmanned zone and a manned zone.

As a further scheme of the invention: the gateway configuration module comprises:

the map establishing unit is used for establishing a map with a ruler and receiving the area range and the area type input by a user based on the map with the ruler;

the point replacement unit is used for reading equipment parameters of alternative monitoring equipment according to the area type, and determining and displaying monitoring points in the area range according to the equipment parameters; the monitoring point position contains the model of monitoring equipment;

the point position selecting unit is used for receiving selecting information input by a user and determining a monitoring point position according to the selecting information;

and the clustering unit is used for clustering the monitoring points according to the model of the monitoring equipment corresponding to the monitoring points, and determining and configuring the transit gateway.

As a further scheme of the invention: the map creation unit includes:

the map acquisition unit is used for receiving the position information input by the user and acquiring a map according to the position information;

the staff gauge inserting unit is used for copying the acquired map and inserting a staff gauge with preset granularity into the map;

a range determining unit for receiving contour information input by a user based on a map containing a scale, and determining a region range according to the contour information;

and the type determining unit is used for opening the type definition port and acquiring the area type of the area range based on the type definition port.

Compared with the prior art, the invention has the beneficial effects that: the invention receives the monitoring point position input by the user and the monitoring equipment at the monitoring point position, classifies the monitoring point position according to the monitoring equipment, determines the transit gateway, implants the identification model at the transit gateway, and carries out identification screening on the regional image to obtain data more worth transmitting; the invention processes the data acquired by the monitoring equipment through the transfer gateway with the identification function, and improves the data transmission efficiency by adopting a star structure.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the following description will briefly introduce the drawings that are needed in the embodiments or the description of the prior art, and it is obvious that the drawings in the following description are only some embodiments of the present invention.

FIG. 1 is a flow diagram of a wireless communication network monitoring method;

FIG. 2 is a first sub-flowchart of a wireless communication network monitoring method;

FIG. 3 is a second sub-flowchart of a wireless communication network monitoring method;

FIG. 4 is a third sub-flowchart of a wireless communication network monitoring method;

FIG. 5 is a block diagram of the construction of a wireless communication network monitoring system;

fig. 6 is a block diagram of the configuration of a gateway configuration module in a wireless communication network monitoring system.

Detailed Description

In order to make the technical problems, technical schemes and beneficial effects to be solved more clear, the invention is further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the scope of the invention.

Example 1

Fig. 1 is a flow chart of a wireless communication network monitoring method, and in an embodiment of the present invention, a wireless communication network monitoring method includes:

step S100: receiving a monitoring point position containing regional parameters input by a user, and determining and configuring a transit gateway according to the monitoring point position; the region parameters comprise region types and region ranges; the region type comprises an unmanned region and a manned region;

wireless monitoring (Wireless monitoring) refers to a monitoring system that uses radio waves to transmit video, sound, data, etc. signals. The wireless monitoring does not need to conduct cable defense arrangement, so that the initial construction cost is greatly reduced, and the wireless monitoring is particularly suitable for large application scenes in a monitored area.

In the existing monitoring system, a plurality of monitoring devices are often involved, and the monitoring devices are matched with each other to jointly complete a monitoring task; the installation position and the working parameters of the monitoring equipment need to be set by staff; when the monitoring equipment is set, a transit gateway is provided for similar monitoring equipment and is used for processing and transmitting data acquired by the monitoring equipment.

Step S200: acquiring regional data acquired by monitoring equipment based on a transit gateway;

the transfer gateway can be additionally provided with a data processing function for processing the data acquired by the monitoring equipment, so that the volume of the data acquired by the monitoring equipment is reduced, and the pressure in the data transmission process is relieved; the wireless transmission process occurs at the transfer gateway and the data storage end, the energy consumption in the wireless transmission process is more, and when the number of the monitoring devices reaches a certain degree, a great amount of energy can be saved by small optimization.

Step S300: generating an area monitoring report according to the area data;

the generation of the area monitoring report by the area data can be completed by means of a trained model or manually, and is not particularly limited; if the area monitoring report is made manually, step S300 is actually a data transmission process, i.e., the area data is transmitted to the manual end, and then the area monitoring report fed back by the manual end is received.

Fig. 2 is a first sub-flowchart of a wireless communication network monitoring method, where the step of receiving a monitoring point location containing a regional parameter input by a user, determining and configuring a transit gateway according to the monitoring point location includes:

step S101: establishing a map with a ruler, and receiving the region range and the region type of the region range input by a user based on the map with the ruler;

colloquially, a map with a scale means that points in the map can be represented in coordinates; coordinates may make it easier for the user to enter a range of regions; the determination of the region type occurs after the determination of the region scope, which is equivalent to assigning a value to the tag of the region scope.

Step S102: reading equipment parameters of alternative monitoring equipment according to the area type, and determining and displaying monitoring points in the area range according to the equipment parameters; the monitoring point position contains the model of monitoring equipment;

the equipment model and the equipment parameters thereof which can monitor a certain area range are combined in a plurality of ways, and a computer can quickly determine some allowed monitoring points;

step S103: receiving selection information input by a user, and determining a monitoring point position according to the selection information;

after the allowed monitoring points are determined, receiving selection information input by a user, and determining specific monitoring points.

Step S104: clustering the monitoring points according to the model of the monitoring equipment corresponding to the monitoring points, and determining and configuring a transit gateway;

monitoring equipment with the same model and short distance can be managed by the same transit gateway; in other words, one transit gateway can be connected with a plurality of monitoring devices which are of the same model and are close to each other, and the acquired data can be processed and transmitted.

Further, the step of establishing a map containing a scale, and receiving the area range and the area type of the area range input by the user based on the map containing the scale comprises the following steps:

receiving position information input by a user, and acquiring a map according to the position information;

copying the obtained map, and inserting a scale with preset granularity into the map;

receiving contour information input by a user based on a map containing a scale, and determining a region range according to the contour information;

the open type definition port acquires the zone type of the zone range based on the type definition port.

The above-mentioned contents specifically describe the process of acquiring the area range and the area type, firstly, receiving a piece of position information input by a user, and reading map data according to the position information, which can be completed by means of the existing map function; then copying a map, and inserting mutually perpendicular coordinate axes and coordinate scales into the map; finally, based on the scale, receiving contour information input by a user, and determining a region range; and carrying out region type assignment on the region range.

Wherein, granularity refers to the minimum scale of coordinate axis.

Specifically, the step of reading the device parameters of the alternative monitoring device according to the region type, and determining and displaying the monitoring point location in the region range according to the device parameters includes:

when the area type is an unmanned area, reading alternative monitoring equipment with a color value identification function;

when the zone type is a person zone, reading alternative monitoring equipment with a heat source identification function;

reading equipment parameters of monitoring equipment, and calculating a monitoring range according to the equipment parameters; the equipment parameters comprise equipment height and equipment angle;

and matching the monitoring range with the regional range, and determining and displaying the monitoring point positions.

The area monitored by the technical scheme comprises two areas, wherein one area is an unmanned area and the other area is a manned area; for an unmanned area, the color characteristics are important, so that the corresponding monitoring equipment is required to have a color value recognition function; for people-carrying areas, the characteristics of the people are important, so that the corresponding monitoring equipment is required to have a heat source identification function.

Further, the step of clustering each monitoring point according to the model of the monitoring device corresponding to each monitoring point, and determining and configuring the transit gateway includes:

the types of the monitoring equipment corresponding to the monitoring points are sequentially read, and the monitoring points with the same types are classified into one type;

sequentially reading monitoring points in the similar monitoring points as reference points, and calculating the distances between other monitoring points and the reference points;

calculating the number of the point positions with the distance smaller than a preset distance threshold value, and taking the number of the point positions as the aggregation degree of the reference point positions;

clustering the monitoring points according to the aggregation degree, setting a transit gateway, and configuring the transit gateway according to the model of the monitoring equipment.

Calculating the distance between other monitoring points nearby the monitoring point and the monitoring point, and judging whether the monitoring point is at the middle position according to the distance, wherein the characteristic is called aggregation degree; and (3) aggregating the monitoring points according to the aggregation degree, connecting the same type of monitoring points with the same transit gateway, and constructing a star structure, so that the transmission efficiency can be improved.

Fig. 3 is a second sub-flowchart of the wireless communication network monitoring method, and the step of acquiring the area data acquired by the monitoring device based on the transit gateway includes steps S201 to S204:

step S201: when the region type is an unmanned region, acquiring a region image acquired by the monitoring equipment in real time based on the transit gateway;

step S202: inputting the region image into a trained comparison model, comparing the region image with a reserved image, and calculating to obtain a similarity value;

step S203: when the similarity value is smaller than a preset similarity threshold value, extracting a retention image in the comparison model, taking the region image as a new retention image, and repeatedly executing the content;

step S204: and when the region type is a man-made region, acquiring a region image containing heat source information in real time based on the transfer gateway, and eliminating the unmanned image according to the heat source information.

The above specifically describes the processing procedure of the transfer gateway on the regional image, and for the unmanned area, the acquired regional image is very large because the monitoring device has a color acquisition function; at this time, the number of area images needs to be reduced as much as possible, some area images with low similarity are reserved, and the transmission pressure is reduced.

The process of reducing the number of area images is a process of performing a loop, and steps S202 to S203 are performed continuously and in a loop, when a new image is identical to an old image (the similarity value is high enough), at this time, a next new image is acquired, and when the new image is different from the old image (the similarity value is not high enough), at this time, the new image is inserted into the comparison model as a new and old image.

For the area with people, the area image contains heat source information (temperature layer), the area image with people can be easily positioned by the heat source information, and then the area image without people is removed, so that the number of the area images can be reduced, and the transmission pressure can be reduced.

Fig. 4 is a third sub-flowchart of the wireless communication network monitoring method, and the step of generating the area monitoring report according to the area data includes steps S301 to S303:

step S301: reading the reserved image to generate an unmanned area video;

step S302: reading and removing the area image of the unmanned image to generate a manned area video;

the unmanned area video and the manned area video are typically in GIF format.

Step S303: transmitting the unmanned area video and the manned area video to a preset detection end to obtain an area monitoring report;

wherein, unmanned zone video and have the district video all to contain the time axis.

The detection end is generally a manual detection end containing a preset intelligent recognition model.

Example 2

Fig. 5 is a block diagram of a wireless communication network monitoring system, in which the system 10 includes:

the gateway configuration module 11 is configured to receive a monitoring point location containing a regional parameter input by a user, and determine and configure a transit gateway according to the monitoring point location;

the data acquisition module 12 is used for acquiring the area data acquired by the monitoring equipment based on the transit gateway;

a report generating module 13 for generating an area monitoring report according to the area data;

wherein the region parameters include a region type and a region range; the zone types include an unmanned zone and a manned zone.

Fig. 6 is a block diagram of the composition and structure of a gateway configuration module 11 in a wireless communication network monitoring system, where the gateway configuration module 11 includes:

a map creation unit 111 for creating a map containing a scale, receiving an area range and an area type thereof input by a user based on the map containing the scale;

a point replacement unit 112, configured to read device parameters of a replacement monitoring device according to the region type, and determine and display monitoring points in the region range according to the device parameters; the monitoring point position contains the model of monitoring equipment;

the point location selecting unit 113 is configured to receive selection information input by a user, and determine a monitoring point location according to the selection information;

and the clustering unit 114 is configured to cluster each monitoring point according to the model of the monitoring device corresponding to each monitoring point, and determine and configure the transit gateway.

Further, the map creation unit 111 includes:

the map acquisition unit is used for receiving the position information input by the user and acquiring a map according to the position information;

the staff gauge inserting unit is used for copying the acquired map and inserting a staff gauge with preset granularity into the map;

a range determining unit for receiving contour information input by a user based on a map containing a scale, and determining a region range according to the contour information;

and the type determining unit is used for opening the type definition port and acquiring the area type of the area range based on the type definition port.

The functions that can be implemented by the wireless communication network monitoring method are all completed by a computer device, the computer device comprises one or more processors and one or more memories, at least one program code is stored in the one or more memories, and the program code is loaded and executed by the one or more processors to implement the functions of the wireless communication network monitoring method.

The processor takes out instructions from the memory one by one, analyzes the instructions, then completes corresponding operation according to the instruction requirement, generates a series of control commands, enables all parts of the computer to automatically, continuously and cooperatively act to form an organic whole, realizes the input of programs, the input of data, the operation and the output of results, and the arithmetic operation or the logic operation generated in the process is completed by the arithmetic unit; the Memory comprises a Read-Only Memory (ROM) for storing a computer program, and a protection device is arranged outside the Memory.

For example, a computer program may be split into one or more modules, one or more modules stored in memory and executed by a processor to perform the present invention. One or more of the modules may be a series of computer program instruction segments capable of performing specific functions for describing the execution of the computer program in the terminal device.

It will be appreciated by those skilled in the art that the foregoing description of the service device is merely an example and is not meant to be limiting, and may include more or fewer components than the foregoing description, or may combine certain components, or different components, such as may include input-output devices, network access devices, buses, etc.

The processor may be a central processing unit (Central Processing Unit, CPU), other general purpose processors, digital signal processors (Digital Signal Processor, DSP), application specific integrated circuits (Application Specific Integrated Circuit, ASIC), off-the-shelf programmable gate arrays (Field-Programmable Gate Array, FPGA) or other programmable logic devices, discrete gate or transistor logic devices, discrete hardware components, or the like. The general purpose processor may be a microprocessor or the processor may be any conventional processor or the like, which is the control center of the terminal device described above, and which connects the various parts of the entire user terminal using various interfaces and lines.

The memory may be used for storing computer programs and/or modules, and the processor may implement various functions of the terminal device by running or executing the computer programs and/or modules stored in the memory and invoking data stored in the memory. The memory may mainly include a storage program area and a storage data area, wherein the storage program area may store an operating system, an application program required for at least one function (such as an information acquisition template display function, a product information release function, etc.), and the like; the storage data area may store data created according to the use of the berth status display system (e.g., product information acquisition templates corresponding to different product types, product information required to be released by different product providers, etc.), and so on. In addition, the memory may include high-speed random access memory, and may also include non-volatile memory, such as a hard disk, memory, plug-in hard disk, smart Media Card (SMC), secure Digital (SD) Card, flash Card (Flash Card), at least one disk storage device, flash memory device, or other volatile solid-state storage device.

The modules/units integrated in the terminal device may be stored in a computer readable storage medium if implemented in the form of software functional units and sold or used as separate products. Based on this understanding, the present invention may implement all or part of the modules/units in the system of the above-described embodiments, or may be implemented by instructing the relevant hardware by a computer program, which may be stored in a computer-readable storage medium, and which, when executed by a processor, may implement the functions of the respective system embodiments described above. Wherein the computer program comprises computer program code, which may be in the form of source code, object code, executable files or in some intermediate form, etc. The computer readable medium may include: any entity or device capable of carrying computer program code, a recording medium, a U disk, a removable hard disk, a magnetic disk, an optical disk, a computer Memory, a Read-Only Memory (ROM), a random access Memory (RAM, random Access Memory), an electrical carrier signal, a telecommunications signal, a software distribution medium, and so forth.

It should be noted that, in this document, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus. Without further limitation, an element defined by the phrase "comprising one … …" does not exclude the presence of other like elements in a process, method, article, or apparatus that comprises the element.

The foregoing description is only of the preferred embodiments of the present invention, and is not intended to limit the scope of the invention, but rather is intended to cover any equivalents of the structures or equivalent processes disclosed herein or in the alternative, which may be employed directly or indirectly in other related arts.

Claims (2)

1. A method of wireless communication network monitoring, the method comprising:

receiving a monitoring point position containing regional parameters input by a user, and determining and configuring a transit gateway according to the monitoring point position;

acquiring regional data acquired by monitoring equipment based on a transit gateway;

generating an area monitoring report according to the area data;

wherein the region parameters include a region type and a region range; the region type comprises an unmanned region and a manned region;

the step of receiving the monitoring point position containing the regional parameters input by the user and determining and configuring the transit gateway according to the monitoring point position comprises the following steps:

establishing a map with a ruler, and receiving the region range and the region type of the region range input by a user based on the map with the ruler;

reading equipment parameters of alternative monitoring equipment according to the area type, and determining and displaying monitoring points in the area range according to the equipment parameters; the monitoring point position contains the model of monitoring equipment;

receiving selection information input by a user, and determining a monitoring point position according to the selection information;

clustering the monitoring points according to the model of the monitoring equipment corresponding to the monitoring points, and determining and configuring a transit gateway;

the step of establishing the map with the scale and receiving the area range and the area type input by the user based on the map with the scale comprises the following steps:

receiving position information input by a user, and acquiring a map according to the position information;

copying the obtained map, and inserting a scale with preset granularity into the map;

receiving contour information input by a user based on a map containing a scale, and determining a region range according to the contour information;

an open type definition port, acquiring the region type of the region range based on the type definition port;

the step of reading the equipment parameters of the alternative monitoring equipment according to the area type and determining and displaying the monitoring point positions in the area range according to the equipment parameters comprises the following steps:

when the area type is an unmanned area, reading alternative monitoring equipment with a color value identification function;

when the zone type is a person zone, reading alternative monitoring equipment with a heat source identification function;

reading equipment parameters of monitoring equipment, and calculating a monitoring range according to the equipment parameters; the equipment parameters comprise equipment height and equipment angle;

matching the monitoring range and the regional range, and determining and displaying monitoring points;

the step of clustering the monitoring points according to the model of the monitoring equipment corresponding to the monitoring points, and determining and configuring the transit gateway comprises the following steps:

the types of the monitoring equipment corresponding to the monitoring points are sequentially read, and the monitoring points with the same types are classified into one type;

sequentially reading monitoring points in the similar monitoring points as reference points, and calculating the distances between other monitoring points and the reference points;

calculating the number of the point positions with the distance smaller than a preset distance threshold value, and taking the number of the point positions as the aggregation degree of the reference point positions;

clustering each monitoring point according to the aggregation degree, setting a transit gateway, and configuring the transit gateway according to the model of the monitoring equipment;

the step of acquiring the regional data acquired by the monitoring equipment based on the transit gateway comprises the following steps:

when the region type is an unmanned region, acquiring a region image acquired by the monitoring equipment in real time based on the transit gateway;

inputting the region image into a trained comparison model, comparing the region image with a reserved image, and calculating to obtain a similarity value;

when the similarity value is smaller than a preset similarity threshold value, extracting a retention image in the comparison model, taking the region image as a new retention image, and executing circularly;

when the region type is a man-made region, acquiring a region image containing heat source information in real time based on the transfer gateway, and eliminating an unmanned image according to the heat source information;

the step of generating the area monitoring report according to the area data comprises the following steps:

reading the reserved image to generate an unmanned area video;

reading and removing the area image of the unmanned image to generate a manned area video;

transmitting the unmanned area video and the manned area video to a preset detection end to obtain an area monitoring report;

wherein, unmanned zone video and have the district video all to contain the time axis.

2. A wireless communication network monitoring system, the system comprising:

the gateway configuration module is used for receiving the monitoring point positions containing the regional parameters input by the user, and determining and configuring the transit gateway according to the monitoring point positions;

the data acquisition module is used for acquiring the regional data acquired by the monitoring equipment based on the transit gateway;

the report generation module is used for generating an area monitoring report according to the area data;

wherein the region parameters include a region type and a region range; the region type comprises an unmanned region and a manned region;

the gateway configuration module comprises:

the map establishing unit is used for establishing a map with a ruler and receiving the area range and the area type input by a user based on the map with the ruler;

the point replacement unit is used for reading equipment parameters of alternative monitoring equipment according to the area type, and determining and displaying monitoring points in the area range according to the equipment parameters; the monitoring point position contains the model of monitoring equipment;

the point position selecting unit is used for receiving selecting information input by a user and determining a monitoring point position according to the selecting information;

the clustering unit is used for clustering the monitoring points according to the model of the monitoring equipment corresponding to the monitoring points, and determining and configuring a transit gateway;

the map creation unit includes:

the map acquisition unit is used for receiving the position information input by the user and acquiring a map according to the position information;

the staff gauge inserting unit is used for copying the acquired map and inserting a staff gauge with preset granularity into the map;

a range determining unit for receiving contour information input by a user based on a map containing a scale, and determining a region range according to the contour information;

the type determining unit is used for opening the type definition port and acquiring the area type of the area range based on the type definition port;

the step of reading the equipment parameters of the alternative monitoring equipment according to the area type and determining and displaying the monitoring point positions in the area range according to the equipment parameters comprises the following steps:

when the area type is an unmanned area, reading alternative monitoring equipment with a color value identification function;

when the zone type is a person zone, reading alternative monitoring equipment with a heat source identification function;

reading equipment parameters of monitoring equipment, and calculating a monitoring range according to the equipment parameters; the equipment parameters comprise equipment height and equipment angle;

matching the monitoring range and the regional range, and determining and displaying monitoring points;

clustering the monitoring points according to the model of the monitoring equipment corresponding to the monitoring points, and determining and configuring the content of the transit gateway comprises the following steps:

the types of the monitoring equipment corresponding to the monitoring points are sequentially read, and the monitoring points with the same types are classified into one type;

sequentially reading monitoring points in the similar monitoring points as reference points, and calculating the distances between other monitoring points and the reference points;

calculating the number of the point positions with the distance smaller than a preset distance threshold value, and taking the number of the point positions as the aggregation degree of the reference point positions;

clustering each monitoring point according to the aggregation degree, setting a transit gateway, and configuring the transit gateway according to the model of the monitoring equipment;

the obtaining the content of the region data collected by the monitoring equipment based on the transit gateway comprises the following steps:

when the region type is an unmanned region, acquiring a region image acquired by the monitoring equipment in real time based on the transit gateway;

inputting the region image into a trained comparison model, comparing the region image with a reserved image, and calculating to obtain a similarity value;

when the similarity value is smaller than a preset similarity threshold value, extracting a retention image in the comparison model, taking the region image as a new retention image, and executing circularly;

when the region type is a man-made region, acquiring a region image containing heat source information in real time based on the transfer gateway, and eliminating an unmanned image according to the heat source information;

the content of the area monitoring report generated according to the area data comprises:

reading the reserved image to generate an unmanned area video;

reading and removing the area image of the unmanned image to generate a manned area video;

transmitting the unmanned area video and the manned area video to a preset detection end to obtain an area monitoring report;

wherein, unmanned zone video and have the district video all to contain the time axis.

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