CN111669778B

CN111669778B - Method, device and storage medium for monitoring signal quality

Info

Publication number: CN111669778B
Application number: CN201910171004.9A
Authority: CN
Inventors: 曹楠; 王亮; 周仁贵; 方伟
Original assignee: Chengdu TD Tech Ltd
Current assignee: Chengdu TD Tech Ltd
Priority date: 2019-03-07
Filing date: 2019-03-07
Publication date: 2023-03-31
Anticipated expiration: 2039-03-07
Also published as: CN111669778A

Abstract

The application discloses a method, a device and a storage medium for monitoring signal quality, which specifically comprise the following steps: acquiring signal quality information and position information reported by each terminal; generating a signal coverage map for displaying the signal quality of each terminal according to the signal quality information and the position information; dividing the signal coverage map into a plurality of signal coverage areas; and monitoring the signal quality in each signal coverage area in a preset period. According to the embodiment of the application, the signal quality information reported by the terminal is presented in a geographical way, so that technical personnel can visually monitor the signal quality in a signal coverage area without secondary data processing.

Description

Method, device and storage medium for monitoring signal quality

Technical Field

The present application relates to the field of mobile communications, and in particular, to a method, an apparatus, and a storage medium for monitoring signal quality.

Background

The private network communication refers to a communication network established in an industrial client for meeting the requirements of organization and management, safe production, dispatching and commanding and the like. The wireless private network has a plurality of industries and a dispersed structure. Among them, the largest scale is governments and police, followed by railways, ports, electricity, etc. With the future development of the technology trend towards the broadband Long Term Evolution (LTE) technology, private network communication is gradually shifted from a narrowband system to a broadband communication system based on LTE.

The early private network narrowband system has limited maintenance data and simpler supervision, and does not require technicians to have richer and more complex network supervision knowledge. With the popularization of LTE, network management platforms for daily operation and maintenance become more complex, more operations require order extraction indexes and data secondary processing, results are mainly shown by table numbers, and certain requirements are made on technical capabilities of technicians.

After the broadband wireless network is planned, built and optimized and then delivered for use, various changes can occur to scenes in a network coverage area along with the time, such as new building or dismantling of buildings, cultivation or migration of greening, construction of roads and bridges and the like. These changes may cause changes in wireless signal coverage, so that a place with good coverage originally becomes a weak coverage area, or an area with good channel quality originally becomes an area with severe interference, which directly affects service use of a client.

In the prior art, the above problems require technical personnel to perform network pull drive test on the whole network again, and perform network secondary optimization according to the drive test result. And the drive test mechanism can not be normalized and can not cope with the city landform scene which changes at any time. Meanwhile, the network pull test consumes manpower, time cost is high, daily use cannot be achieved, problems are not found timely, and network quality change needs to be judged through reduction of service perception, so that daily use is affected.

In addition, the quality of the network signal is finally reflected on the terminal, and the information intercommunication between the terminal and the network side is lacked, so that the network side cannot know the detailed condition of the field channel quality.

Disclosure of Invention

The embodiment of the application provides a method for monitoring signal quality, which realizes the effect of conveniently and intuitively monitoring the signal quality by counting the signal quality information of each terminal and performing geographical presentation.

The method comprises the following steps:

acquiring signal quality information and position information reported by each terminal;

generating a signal coverage map for displaying the signal quality of each terminal according to the signal quality information and the position information;

dividing the signal coverage map into a plurality of signal coverage areas;

and monitoring the signal quality in each signal coverage area in a preset period.

Optionally, acquiring a terminal identification number reported by each terminal;

and generating graphic dotting corresponding to each terminal according to the terminal identification number, wherein the graphic dotting is used for generating the signal coverage map.

Optionally, obtaining a value of signal quality information of each terminal;

dotting and rendering the graph corresponding to each terminal into a color corresponding to the signal quality range according to the signal quality range in which the numerical value of the signal quality information of each terminal is positioned, wherein the signal quality range comprises a weak signal quality range;

and marking the rendered graph at a position corresponding to the position information in a geographic map according to the position information of each terminal so as to generate a signal coverage map for displaying the signal intensity of each terminal.

Optionally, when the position information of at least two of the rendered graphic dotting is repeated, marking the rendered graphic dotting carrying the latest time information at a position corresponding to the position information to generate a signal coverage map displaying the signal intensity of each terminal.

Optionally, in each signal coverage area, counting a ratio of the number of rendered graphic dotting in the weak signal quality range to the number of all rendered graphic dotting in the signal coverage area;

and when the proportion is larger than a preset threshold value, marking the signal coverage area as a signal weak coverage area.

And when the ratio is smaller than a preset threshold value, returning to execute the step of acquiring the signal quality information and the position information reported by each terminal and the subsequent steps.

In another embodiment of the present invention, there is provided an apparatus for monitoring signal quality, including:

the first acquisition module is used for acquiring signal quality information and position information reported by each terminal;

a first generating module, configured to generate a signal coverage map that displays the signal quality of each terminal according to the signal quality information and the location information;

a dividing module, configured to divide the signal coverage map into a plurality of signal coverage areas;

and the monitoring module is used for monitoring the signal quality in each signal coverage area in a preset period.

Optionally, the apparatus further comprises:

the second acquisition module is used for acquiring the terminal identification number reported by each terminal;

and the second generation module is used for generating graphic dotting corresponding to each terminal according to the terminal identification number, wherein the graphic dotting is used for generating the signal coverage map.

Optionally, the first generating module comprises:

an acquisition unit configured to acquire a value of signal quality information of each terminal;

the rendering unit is used for dotting and rendering the graphs corresponding to the terminals into colors corresponding to the signal quality ranges of the terminals according to the signal quality ranges of the values of the signal quality information of the terminals;

and the generating unit is used for dotting and marking the rendered graph at a position corresponding to the position information in a geographic map according to the position information of each terminal so as to generate a signal coverage map for displaying the signal intensity of each terminal.

Optionally, the generating unit includes:

and the generating subunit is configured to mark the rendered graphic dotting point carrying the latest time information at a position corresponding to the position information when the position information of at least two rendered graphic dotting points is repeated, so as to generate a signal coverage map displaying the signal intensity of each terminal.

Optionally, the apparatus further comprises:

a counting module, configured to count a ratio between the number of rendered graphic dotting in the weak signal quality range and the number of all rendered graphic dotting in the signal coverage range in each signal coverage area;

and the marking module is used for marking the signal coverage area as a signal weak coverage area when the proportion is greater than a preset threshold value.

And the returning module is used for returning to execute the step of acquiring the signal quality information and the position information reported by each terminal and the subsequent steps when the ratio is smaller than the preset threshold.

In another embodiment of the present invention, a terminal device is provided, which includes a processor for executing the steps of the method for monitoring signal quality.

In another embodiment of the invention, a non-transitory computer readable storage medium is provided, storing instructions that, when executed by a processor, cause the processor to perform the steps of one of the above-described methods of monitoring signal quality.

As can be seen from the above, based on the above embodiments, first, the signal quality information and the location information reported by each terminal are obtained, then, a signal coverage map displaying the signal quality of each terminal is generated according to the signal quality information and the location information, then, the signal coverage map is divided into a plurality of signal coverage areas, and finally, the signal quality in each signal coverage area is monitored in a preset period. The signal quality information reported by the terminal is visually and geographically presented, and the signal quality in the signal coverage area can be visually monitored without secondary data processing of technicians.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present application, the drawings that are required to be used in the embodiments will be briefly described below, it should be understood that the following drawings only illustrate some embodiments of the present application and therefore should not be considered as limiting the scope, and for those skilled in the art, other related drawings can be obtained from the drawings without inventive effort.

Fig. 1 is a schematic diagram illustrating an embodiment 10 of a method for monitoring signal quality provided by an embodiment of the present application;

fig. 2 is a schematic diagram illustrating an embodiment 20 of a method for monitoring signal quality provided by an embodiment of the application;

fig. 3 is a schematic diagram illustrating an apparatus 30 for monitoring signal quality according to an embodiment of the present disclosure;

fig. 4 shows a schematic diagram of a terminal device 40 provided in an embodiment of the present application.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention is further described in detail below with reference to the accompanying drawings and examples.

Based on the problems in the prior art, embodiments of the present application provide a method for monitoring signal quality, which generates a signal overlay capable of displaying signal quality of each terminal according to location information of signal quality information reported by each terminal, so as to achieve an effect of visually and real-timely monitoring signal quality in a preset period, and meanwhile, a technician is not required to perform secondary processing on statistical data.

The application field of the application is mainly the field of mobile communication. An embodiment 10 of the method for monitoring signal quality provided in the embodiment of the present application is shown in fig. 1, and the detailed steps are as follows:

s11, obtaining signal quality information and position information reported by each terminal.

In this step, the signal quality information is mainly reflected on the terminal, and the terminal collects the signal quality information and reports the collected signal quality information to the network side.

Specifically, the signal quality information is collected through a channel detection mechanism of the terminal. According to the Long Term Evolution (LTE) protocol, a hardware base layer (CP) of a terminal can measure Signal Quality information such as Reference Signal Received Power (RSRP), signal to Interference Noise Ratio (SINR), reference Signal Received Quality (RSRQ), and Received Signal Strength Indicator (RSSI), etc. The terminal opens a data path between a CP layer and an Application Processor (AP), transmits the signal quality information acquired at the CP layer to the AP layer, establishes a data path between the terminal and a network side, and transmits the signal quality information acquired by the terminal to the network side.

In addition, the CP layer of the terminal may also collect Cell information, such as Physical Cell Identifier (PCI). The terminal is equipped with a Global Positioning System (GPS) module, and can report the location information of the terminal to the network side in real time.

And S12, generating a signal coverage map for displaying the signal quality of each terminal according to the signal quality information and the position information.

In this step, after the network side obtains the signal quality information reported by the terminal and the location information of the terminal, the signal quality information of each terminal is marked at the corresponding location according to the location information of each terminal. Here, a geographical map including the position of each terminal is set in advance, and the signal quality information of each terminal is marked at a corresponding position on the geographical map according to the position information. Finally, a signal overlay is generated which displays the signal quality information of each terminal.

And S13, dividing the signal coverage map into a plurality of signal coverage areas.

In this step, after the generated signal coverage maps are obtained, the signal coverage maps are divided to obtain a plurality of signal coverage areas. Specifically, the signal coverage map may be rasterized. And rasterizing the signal coverage map to divide the signal coverage map into a plurality of signal coverage areas, so that the signal quality of each terminal in each signal coverage area can be conveniently counted.

And S14, monitoring the signal quality in each signal coverage area in a preset period.

In this step, the preset period may be set according to a service requirement, and is preferably a preset period of 10 s. And monitoring the signal quality in the divided signal coverage area in a preset period. The signal quality is signal quality information reported by each terminal in each signal coverage area. According to various signal quality information reported by each terminal, such as RSRP, RSRQ, RSSI, SINR and the like, the numerical value of one type of signal quality information is selected as a standard for measuring the signal quality of the signal coverage area.

Based on the above embodiment of the present application, first, signal quality information and location information reported by each terminal are obtained, then, a signal coverage map displaying the signal quality of each terminal is generated according to the signal quality information and the location information, then, the signal coverage map is divided into a plurality of signal coverage areas, and finally, the signal quality in each signal coverage area is monitored in a preset period. According to the embodiment of the application, the terminal actively reports the signal quality information and the position information, large-scale statistical data are visually and geographically presented, meanwhile, intelligent judgment is achieved, technical operation of a front-line worker is simplified as much as possible, and real-time performance and accuracy of signal quality monitoring are improved.

The method for monitoring the signal quality in the embodiment of the application mainly comprises the step of displaying the signal quality information and the position information acquired by the terminal in a visualized and geographical mode, so that the signal quality can be monitored conveniently and visually. Fig. 2 is a schematic diagram illustrating a detailed flow of an embodiment 20 of a method for monitoring signal quality in the embodiment of the present application. Wherein, the detailed process of the specific flow is as follows:

and S21, acquiring signal quality information and position information reported by each terminal.

Here, the CP layer of the terminal acquires the time when the signal quality information is acquired and the GPS module acquires the location information. And the AP layer of the terminal sequentially stores the acquired data into a table 1 shown in the following table according to the time stamp, and each row of the data has one piece of independent information so as to represent signal quality information and position information reported by the terminal each time and corresponding time. The information comprises Longitude, latitude, RSRP, SINR, RSRQ, RSSI, PCI and a terminal identification number UserID. A

Time

Longitude

Latitude

RSRP

SINR

RSRQ

RSSI

PCI

UserID

TABLE 1

And S22, generating graphic dotting corresponding to each terminal.

Here, after the signal quality information and the position information reported by each terminal are obtained, the terminal identification number reported by each terminal is obtained at the same time. The terminal identification number corresponds to an identification code of the terminal and corresponds to a unique terminal. Graphic dotting for generating signal overlays

And generating a graphic dotting corresponding to each terminal according to the acquired terminal identification number of each terminal. Wherein, the image dotting is the image dotting.

And S23, dotting the graph and performing color rendering.

Here, after the various types of signal quality information reported by the terminals are obtained, the value of the signal quality information of each terminal is obtained. And dotting and rendering the image corresponding to each terminal into a color corresponding to the signal quality range according to the signal quality range in which the numerical value of the signal quality information of each terminal is positioned, wherein the signal quality range comprises a weak signal quality range.

Specifically, after various types of signal quality information reported by the terminal are acquired at the network side, the signal quality range is determined based on the value of one type of signal quality information. The signal quality range can be divided into a signal weak quality range of-140 dBm to-114 dBm, a signal medium quality range of-114 dBm to-100 dBm, and a signal strong quality range of-100 dBm to-40 dBm, as based on values of RSRP. Three different rendering colors can be determined in three signal quality ranges with different signal strengths, for example, the rendering color in the signal weak quality range is red, the rendering color in the signal medium quality range is yellow, and the rendering color in the signal strong quality range is green.

And performing color rendering on the graphic dotting corresponding to each terminal based on the RSRP value reported by each terminal, and determining the color of the graphic dotting corresponding to each terminal.

And S24, dotting the rendered graph and embedding the same into a geographical map according to the position information to generate a signal coverage map.

Here, the rendered graphic dotting is marked on the position corresponding to the position information in the geographic map according to the position information of each terminal, so as to generate a signal coverage map displaying the signal intensity of each terminal. And each graphic dotting has corresponding longitude and latitude position information, and the rendered graphic dotting is embedded into a corresponding position in a geographic map according to the specific position information.

In addition, when the position information of at least two rendered graphic dotting is repeated, the rendered graphic dotting carrying the latest time information is marked on the position corresponding to the position information so as to generate a signal coverage map for displaying the signal intensity of each terminal. Specifically, the terminal reports the signal quality information and the position information in real time, so that different graphic dotting can be generated, and when the rendered graphic dotting position information of the same terminal is repeated, the graphic dotting with the updated timestamp is selected to be marked at the corresponding position.

And S25, dividing the signal coverage map into a plurality of signal coverage areas.

And S26, judging the ratio of the number of the rendered graphic dotting in the weak signal quality range to the number of all the rendered graphic dotting in the signal coverage range in each signal coverage area to the size of a preset threshold value.

Here, the number of dots of each rendered graphic contained in each signal coverage area in different signal quality ranges is counted. Specifically, in each signal coverage area, there are a plurality of rendered graphic dotting, and the signal quality of each rendered graphic dotting is different. Then, counting the number of the graphic dotting points of the color corresponding to the weak signal quality range, and comparing the ratio of the number of the rendered graphic dotting points in the weak signal quality range to the number of all the rendered graphic dotting points in the signal coverage range with a preset threshold value. The preset threshold value may be preset according to different service requirements, if the requirement for signal coverage in a densely populated area is high, the corresponding preset threshold value should be low, otherwise, if the requirement for signal coverage in a suburban area is high, the preset threshold value may be set relatively high.

And S27, when the ratio of the number of the rendered graphic dotting in the weak signal quality range to the number of all the rendered graphic dotting in the signal coverage range is greater than a preset threshold value in the signal coverage area, marking the signal coverage area as a signal weak coverage area, and prompting.

Here, if the value corresponding to the preset threshold is 5%, when the ratio of the number of rendered graphic dotting in the poor signal quality range counted in a certain signal coverage area to the number of all rendered graphic dotting in the signal coverage area is greater than 5%, the signal coverage area does not meet the service requirement, and the signal coverage area is marked as a signal poor coverage area.

In addition, when the ratio of the number of the rendered graphic dotting in the weak signal quality range to the number of all the rendered graphic dotting in the signal coverage range is smaller than a preset threshold value in the signal coverage area, the steps of acquiring the signal quality information and the position information reported by each terminal and the subsequent steps are returned to be executed.

Here, as can be seen from the above, if the value corresponding to the preset threshold is 5%, when the ratio of the number of rendered graphic dotting in the weak signal quality range counted in a certain signal coverage area to the number of all rendered graphic dotting in the signal coverage area is less than 5%, the signal coverage area meets the service requirement, and the step of obtaining the signal quality information and the position information reported by each terminal and the subsequent steps are continuously executed.

The embodiment of the application realizes the effect of monitoring the signal quality based on the steps.

Based on the same inventive concept, the embodiment of the present application further provides a schematic diagram of an apparatus 30 for monitoring signal quality, where as shown in fig. 3, the apparatus includes:

a first obtaining module 31, configured to obtain signal quality information and location information reported by each terminal;

a first generating module 32, configured to generate a signal coverage map showing signal quality of each terminal according to the signal quality information and the location information;

a dividing module 33, configured to divide the signal coverage map into a plurality of signal coverage areas;

a monitoring module 34, configured to monitor signal quality in each of the signal coverage areas during a preset period.

Optionally, the apparatus further comprises:

a second obtaining module 35, configured to obtain a terminal identification number reported by each terminal;

and a second generating module 36, configured to generate a graphic dotting corresponding to each terminal according to the terminal identification number, where the graphic dotting is used to generate the signal coverage map.

Optionally, the first generating module 32 comprises:

the rendering unit is used for dotting and rendering the graph corresponding to each terminal into the color corresponding to the signal quality range according to the signal quality range in which the numerical value of the signal quality information of each terminal is positioned, wherein the signal quality range comprises a weak signal quality range;

Optionally, the generating unit comprises:

Optionally, the apparatus further comprises:

a counting module 37, configured to count a ratio between the number of rendered graphic dotting in the weak signal quality range and the number of all rendered graphic dotting in the signal coverage range in each signal coverage area;

and a marking module 38, configured to mark the signal coverage area as a signal weak coverage area when the ratio is greater than a preset threshold.

And a returning module 39, configured to, when the ratio is smaller than a preset threshold, return to the step of acquiring the signal quality information and the position information reported by each terminal and the subsequent steps.

In this embodiment, specific functions and interaction manners of the first obtaining module 31, the first generating module 32, the dividing module 33 and the monitoring module 34 may refer to the description of the embodiment corresponding to fig. 1, and are not described herein again.

As shown in fig. 4, a schematic diagram of a terminal device 40 is further provided in another embodiment of the present application, which includes a processor 40, wherein the processor 40 is configured to execute the steps of the method for monitoring signal quality.

As can also be seen from fig. 4, the terminal device provided by the above embodiment further includes a non-transitory computer readable storage medium 41, the non-transitory computer readable storage medium 41 stores thereon a computer program, and the computer program is executed by the processor 40 to perform the steps of the above method for monitoring signal quality.

Specifically, the storage medium can be a general storage medium, such as a mobile disk, a hard disk, a FLASH, and the like, and when a computer program on the storage medium is run, the method for monitoring signal quality can be executed, so that a technician can visually monitor signal quality in a signal coverage area by performing physicochemical presentation on signal quality information reported by a terminal without performing secondary data processing.

Finally, it should be noted that: the above-mentioned embodiments are only specific embodiments of the present application, and are used for illustrating the technical solutions of the present application, but not limiting the same, and the scope of the present application is not limited thereto, and although the present application is described in detail with reference to the foregoing embodiments, those skilled in the art should understand that: any person skilled in the art can modify or easily conceive the technical solutions described in the foregoing embodiments or equivalent substitutes for some technical features within the technical scope disclosed in the present application; such modifications, changes or substitutions do not depart from the spirit and scope of the exemplary embodiments of the present application, and are intended to be covered by the scope of the present application. Therefore, the protection scope of the present application shall be subject to the protection scope of the claims.

Claims

1. A method of monitoring signal quality, comprising:

dividing the signal coverage map into a plurality of signal coverage areas;

monitoring the signal quality in each signal coverage area in a preset period;

wherein, between the step of obtaining the signal quality information and the position information reported by each terminal and the step of generating the signal coverage map for displaying the signal quality of each terminal, the method further comprises the following steps:

acquiring a terminal identification number reported by each terminal;

generating graphic dotting corresponding to each terminal according to the terminal identification number, wherein the graphic dotting is used for generating the signal coverage map;

the step of generating a signal overlay showing the signal quality of each terminal comprises:

acquiring the numerical value of the signal quality information of each terminal;

marking the rendered graph at a position corresponding to the position information in a geographic map according to the position information of each terminal to generate a signal coverage map for displaying the signal intensity of each terminal;

after the step of monitoring the signal quality in each signal coverage area within a preset period, the method further includes:

counting the proportion of the number of the rendered graphic dotting in the weak signal quality range to the number of all the rendered graphic dotting in the signal coverage range in each signal coverage area;

when the proportion is larger than a preset threshold value, marking the signal coverage area as a signal weak coverage area;

and when the ratio is smaller than a preset threshold value, returning to the step of acquiring the signal quality information and the position information reported by each terminal and the subsequent steps.

2. The method of claim 1, wherein the step of marking the rendered graphic dotting on the position corresponding to the position information in the geographic map comprises:

when the position information of at least two rendered graphs is repeated, marking the rendered graphs carrying the latest time information at the position corresponding to the position information to generate a signal coverage map for displaying the signal intensity of each terminal.

3. An apparatus for monitoring signal quality, the apparatus comprising:

the monitoring module is used for monitoring the signal quality in each signal coverage area in a preset period;

wherein the apparatus further comprises:

the second generation module is used for generating graphic dotting corresponding to each terminal according to the terminal identification number, wherein the graphic dotting is used for generating the signal coverage map;

the first generation module comprises:

the rendering unit is used for dotting and rendering the graphs corresponding to the terminals into colors corresponding to the signal quality ranges according to the signal quality ranges where the numerical values of the signal quality information of the terminals are located, wherein the signal quality ranges comprise weak signal quality ranges;

the generating unit is used for dotting and marking the rendered graph at a position corresponding to the position information in a geographic map according to the position information of each terminal so as to generate a signal coverage map for displaying the signal intensity of each terminal;

the device further comprises:

the marking module is used for marking the signal coverage area as a signal weak coverage area when the proportion is larger than a preset threshold value;

and the return module is used for returning to execute the step of acquiring the signal quality information and the position information reported by each terminal and the subsequent steps when the ratio is smaller than the preset threshold.

4. The apparatus of claim 3, wherein the generating unit comprises:

5. A terminal device, comprising a processor configured to perform the steps of the method of monitoring signal quality according to any one of claims 1 to 2.

6. A non-transitory computer readable storage medium storing instructions that, when executed by a processor, cause the processor to perform the steps of the method of monitoring signal quality of any of claims 1-2.