CN104581811B - Signal covering quality rendering method and device - Google Patents

Abstract

The embodiment of the present invention, which provides a kind of signal covering quality rendering method and device, the method, to be included：Obtain N number of MR data that the UE in signal coverage areas in the floor to be presented in building building to be presented is reported, the N is the integer more than or equal to 1, building building to be presented is any building building in signal coverage areas, and floor to be presented is any floor in building building to be presented；According to N number of MR data, mark corresponding with the signal covering quality of the floor to be presented is determined；The exterior of floor to be presented in the 3D simulant buildings building corresponding to the building building to be presented indicates the mark.So as to which telecom operation and maintenance engineer can know that each entity builds the signal covering quality of each floor in building at a glance by all marks to be presented built in the corresponding 3D simulant buildings building in building outside each floor in signal coverage areas, and then the floor of signal covering quality difference can be directly oriented, improve fault location efficiency.

Description

Signal coverage quality presentation method and device

Technical Field

The embodiment of the invention relates to the technical field of communication, in particular to a method and a device for presenting signal coverage quality.

Background

The current telecom operation and maintenance engineers need to monitor coverage signals, cell signals and floor signals of regional base stations in real time, open problems layer by layer and skip to view on different pages; the method specifically comprises the following steps: and checking fault points in the two-dimensional view, expanding the fault points to the overall situation of the community to check the problem of the building, and opening the floor to check the signal coverage condition of the plane view after the fault points are positioned to the building, thereby positioning the floor and the range of the problem. However, the whole process of locating the problem floor and range jumps many times, and the fault information is checked in different pages, which causes the problem locating efficiency to be low.

Disclosure of Invention

The embodiment of the invention provides a signal coverage quality presenting method and a signal coverage quality presenting device, which are used for improving the positioning efficiency of poor floor signal coverage quality.

In a first aspect, an embodiment of the present invention provides a method for presenting signal coverage quality, including:

acquiring N Measurement Report (MR) data reported by User Equipment (UE) in a floor to be presented of a building to be presented in a signal coverage area, wherein N is an integer greater than or equal to 1, the building to be presented is any building in the signal coverage area, and the floor to be presented is any floor in the building to be presented;

determining an identifier corresponding to the signal coverage quality of the floor to be presented according to the N MR data;

and marking the mark outside the floor to be presented in the three-dimensional (3D) building corresponding to the building to be presented.

In a first possible implementation manner of the first aspect, the determining, according to the N MR data, an identifier corresponding to signal coverage quality of the floor to be presented includes:

determining the number M of MR data meeting a preset condition in the N pieces of MR data, wherein M is an integer which is greater than or equal to 1 and less than or equal to N;

and determining an identifier corresponding to the signal coverage quality of the floor to be presented according to the ratio of the M to the N.

With reference to the first possible implementation manner of the first aspect, in a second possible implementation manner of the first aspect, the determining, according to the ratio of M to N, an identifier corresponding to signal coverage quality of the floor to be presented, and determining an identifier corresponding to signal quality of the first floor include:

when the ratio of the M to the N is larger than or equal to a first preset value, determining that an identifier corresponding to the signal coverage quality of the floor to be presented is a first identifier;

when the ratio of the M to the N is smaller than or equal to a second preset value, determining that the identifier corresponding to the signal coverage quality of the floor to be presented is a second identifier;

when the ratio of the M to the N is smaller than the first preset value and larger than the second preset value, determining that the identifier corresponding to the signal coverage quality of the floor to be presented is a third identifier;

wherein the first preset value is greater than the second preset value.

In a third possible implementation manner of the first aspect, the determining, according to the N MR data, an identifier corresponding to signal coverage quality of the floor to be presented includes:

determining the number of the MR data respectively meeting H different preset conditions in the N pieces of MR data, wherein H is an integer greater than or equal to 2, and the sum of the H number of the MR data is equal to N;

and determining an identifier corresponding to the signal coverage quality of the floor to be presented according to the size relation between the determined H number values.

With reference to the third possible implementation manner of the first aspect, in a fourth possible implementation manner of the first aspect, the determining, according to the magnitude relation between the H determined individual values, an identifier corresponding to the signal coverage quality of the floor to be presented includes:

determining the signal coverage quality grade of the floor to be presented according to the magnitude relation among the H numerical values;

determining the identifier corresponding to the signal coverage quality grade according to the signal coverage quality grade of the floor to be presented;

and the marks corresponding to different signal coverage quality grades are different.

With reference to the third possible implementation manner of the first aspect or the fourth possible implementation manner of the first aspect, in a fifth possible implementation manner of the first aspect, when H is 3, the determining the number of MR data that respectively satisfy H different preset conditions in the N MR data includes:

determining the number of MR data meeting a first preset condition in the N pieces of MR data as X, the number of MR data meeting a second preset condition as Y and the number of MR data meeting a third preset condition as Z;

the determining, according to the magnitude relationship between the H numerical values, an identifier corresponding to the signal coverage quality of the floor to be presented includes:

determining an identifier corresponding to the signal coverage quality of the floor to be presented according to the size relationship among the X, the Y and the Z;

wherein X, Y and Z are integers which are respectively greater than or equal to 0 and less than or equal to N, and X + Y + Z is equal to N.

With reference to the fifth possible implementation manner of the first aspect, in a sixth possible implementation manner of the first aspect, if the X is not equal to the Y and the Z, the determining, according to a size relationship between the X, the Y, and the Z, an identifier corresponding to signal coverage quality of the floor to be presented includes:

when said X is equal to said N; or, said Y is equal to 0, said X is greater than said Z; or, said Z is equal to 0, said X is greater than said Y; or when the X is larger than the Y + the Z, determining that the identifier corresponding to the signal coverage quality of the floor to be presented is a first identifier corresponding to the first preset condition;

when said Y is equal to said N; or, said X is equal to 0, said Y is greater than said Z; alternatively, said Z is equal to 0, said X is not greater than said Y; or, said X is less than said Y + said Z, said Y is greater than said Z; or when the X is equal to the Y plus the Z and the Y is not less than the Z, determining that the identifier corresponding to the signal coverage quality of the floor to be presented is a second identifier corresponding to the second preset condition;

when said Z is equal to said N; or, X is equal to 0, Y is not greater than Z, or, Y is equal to 0, X is not greater than Z; or, said X is less than said Y + said Z, said Y is not greater than said Z; or when the X is equal to the Y plus the Z and the Y is smaller than the Z, determining that the identifier corresponding to the signal coverage quality of the floor to be presented is a third identifier corresponding to the third preset condition; or,

if the X is equal to the Y and the Z, determining the identifier corresponding to the signal coverage quality of the floor to be presented according to the size relationship among the X, the Y and the Z, including:

and when the X is equal to the Y and the Z, determining the signal coverage quality grade of the floor to be presented as a second identifier corresponding to the second preset condition.

With reference to the sixth possible implementation manner of the first aspect, in a seventh possible implementation manner of the first aspect, the signal coverage quality corresponding to the first identifier is higher than the signal coverage quality corresponding to the second identifier, and the signal coverage quality corresponding to the second identifier is higher than the signal coverage quality corresponding to the third identifier.

With reference to the first aspect or any one of the first to seventh possible implementation manners of the first aspect, in an eighth possible implementation manner of the first aspect, the identifier includes at least one of: color identification, texture identification, color depth identification and texture density identification.

In a second aspect, an embodiment of the present invention provides a signal coverage quality presenting apparatus, including: the system comprises an acquisition unit, a processing unit and a display unit, wherein the acquisition unit is used for acquiring N MR data reported by UE (user equipment) in floors to be presented of building buildings to be presented in a signal coverage area, N is an integer which is greater than or equal to 1, the building to be presented is any building in the signal coverage area, and the floor to be presented is any floor in the building to be presented;

the determining unit is used for determining an identifier corresponding to the signal coverage quality of the floor to be presented according to the N MR data acquired by the acquiring unit;

and the processing unit is used for marking the identifier determined by the determining unit outside the floor to be presented in the 3D simulation building corresponding to the building to be presented.

In a first possible implementation manner of the second aspect, the determining unit is specifically configured to determine a number M of MR data that satisfy a preset condition in the N MR data, where M is an integer greater than or equal to 1 and less than or equal to N; and determining an identifier corresponding to the signal coverage quality of the floor to be presented according to the ratio of the M to the N.

With reference to the first possible implementation manner of the second aspect, in a second possible implementation manner of the second aspect, the determining unit is configured to determine, according to the ratio of M to N, an identifier corresponding to the signal coverage quality of the floor to be presented, and determine an identifier corresponding to the signal quality of the first floor, and includes: the determining unit is specifically configured to determine, when it is determined that the ratio of M to N is greater than or equal to a first preset value, that an identifier corresponding to the signal coverage quality of the floor to be presented is a first identifier; when the ratio of the M to the N is smaller than or equal to a second preset value, determining that the identifier corresponding to the signal coverage quality of the floor to be presented is a second identifier; when the ratio of M to N is smaller than the first preset value and larger than the second preset value, determining that the identifier corresponding to the signal coverage quality of the floor to be presented is a third identifier; wherein the first preset value is greater than the second preset value.

In a third possible implementation manner of the second aspect, the determining unit is specifically configured to determine values of numbers of MR data that respectively satisfy H different preset conditions in the N MR data, where H is an integer greater than or equal to 2, and a sum of the H numbers of values is equal to N; and determining an identifier corresponding to the signal coverage quality of the floor to be presented according to the magnitude relation between the determined H number values.

With reference to the third possible implementation manner of the second aspect, in a fourth possible implementation manner of the second aspect, the determining unit is configured to determine, according to a magnitude relationship between the H determined individual values, an identifier corresponding to signal coverage quality of the floor to be presented, and includes: the determining unit is specifically configured to determine, according to a magnitude relationship between the H numerical values, a signal coverage quality level of the floor to be presented; determining the identifier corresponding to the signal coverage quality grade according to the signal coverage quality grade of the floor to be presented; and the marks corresponding to different signal coverage quality grades are different.

With reference to the third possible implementation manner of the second aspect or the fourth possible implementation manner of the second aspect, in a fifth possible implementation manner of the second aspect, when H is 3, the determining unit is configured to determine the number of MR data that respectively satisfy H different preset conditions in the N MR data, and the determining unit includes: the determining unit is specifically configured to determine that, of the N MR data, the number of MR data meeting a first preset condition is X, the number of MR data meeting a second preset condition is Y, and the number of MR data meeting a third preset condition is Z;

the determining unit is configured to determine, according to the magnitude relationship between the H numerical values, an identifier corresponding to the signal coverage quality of the floor to be presented, and includes: the determining unit is specifically configured to determine, according to a size relationship among the X, the Y, and the Z, an identifier corresponding to the signal coverage quality of the floor to be presented; wherein X, Y and Z are integers which are respectively greater than or equal to 0 and less than or equal to N, and X + Y + Z is equal to N.

With reference to the fifth possible implementation manner of the second aspect, in a sixth possible implementation manner of the second aspect, if X is not equal to Y and Z, the determining unit is configured to determine, according to a size relationship between X, Y and Z, an identifier corresponding to signal coverage quality of the floor to be presented, and the determining unit includes: the determining unit is specifically configured to, when it is determined that X is equal to N; or, said Y is equal to 0, said X is greater than said Z; or, said Z is equal to 0, said X is greater than said Y; or when the X is larger than the Y + the Z, determining that the identifier corresponding to the signal coverage quality of the floor to be presented is a first identifier corresponding to the first preset condition; and when it is determined that Y is equal to N; or, said X is equal to 0, said Y is greater than said Z; alternatively, said Z is equal to 0, said X is not greater than said Y; or, said X is less than said Y + said Z, said Y is greater than said Z; or when the X is equal to the Y plus the Z and the Y is not less than the Z, determining that the identifier corresponding to the signal coverage quality of the floor to be presented is a second identifier corresponding to the second preset condition; and when said Z is equal to said N; or, X is equal to 0, Y is not greater than Z, or, Y is equal to 0, X is not greater than Z; or, said X is less than said Y + said Z, said Y is not greater than said Z; or when the X is equal to the Y plus the Z and the Y is smaller than the Z, determining that the identifier corresponding to the signal coverage quality of the floor to be presented is a third identifier corresponding to the third preset condition; or,

if the X is equal to the Y and the Z, the determining unit is configured to determine, according to a magnitude relationship between the X, the Y, and the Z, an identifier corresponding to the signal coverage quality of the floor to be presented, including: the determining unit is specifically configured to determine, according to the fact that X is equal to Y and Z, that the signal coverage quality level of the floor to be presented is a second identifier corresponding to the second preset condition.

With reference to the sixth possible implementation manner of the second aspect, in a seventh possible implementation manner of the second aspect, the signal coverage quality corresponding to the first identifier is higher than the signal coverage quality corresponding to the second identifier, and the signal coverage quality corresponding to the second identifier is higher than the signal coverage quality corresponding to the third identifier.

With reference to the second aspect or any one of the first to seventh possible implementation manners of the second aspect, in an eighth possible implementation manner of the second aspect, the identifier determined by the determining unit includes at least one of: color identification, texture identification, color depth identification and texture density identification.

The embodiment of the invention provides a method and a device for presenting signal coverage quality, wherein N MR data reported by UE (user equipment) in a floor to be presented of a building to be presented in a signal coverage area are acquired; determining an identifier corresponding to the signal coverage quality of the floor to be presented according to the N MR data; and marking the identifier outside the floor to be presented in the 3D simulation building corresponding to the building to be presented. Therefore, telecommunication operation and maintenance engineers can clearly know the signal coverage quality of each floor in each entity building through the marks outside each floor in the 3D simulation building corresponding to all buildings to be presented in the signal coverage area, and then can directly position the floor with poor signal coverage quality, and the fault positioning efficiency is improved.

Drawings

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

Fig. 1 is a flowchart of a first embodiment of a method for presenting signal coverage quality according to the present invention;

FIG. 2 is a schematic diagram of a texture marker provided in accordance with an embodiment of the present invention;

FIG. 3 is a flowchart illustrating a second embodiment of a method for presenting signal coverage quality according to the present invention;

FIG. 4 is a flowchart of a third embodiment of a method for presenting signal coverage quality according to the present invention;

FIG. 5 is a flowchart illustrating a fourth embodiment of a method for presenting signal coverage quality according to the present invention;

fig. 6 is a schematic structural diagram of a signal coverage quality presenting apparatus according to a first embodiment of the present invention;

fig. 7 is a schematic structural diagram of a second embodiment of a signal coverage quality presenting apparatus according to the present invention.

Detailed Description

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

Fig. 1 is a flowchart of a first embodiment of a method for presenting signal coverage quality in the present invention, as shown in fig. 1, an execution subject of the present embodiment is a signal coverage quality presenting apparatus, and the method of the present embodiment may include:

s101, N MR data reported by UE in floors to be presented of building buildings to be presented in a signal coverage area are obtained, wherein N is an integer larger than or equal to 1, the building to be presented is any building in the signal coverage area, and the floor to be presented is any floor in the building to be presented.

In this embodiment, one of the buildings to be presented in the signal coverage area is taken as an example, and the other floors to be presented in the floors to be presented are similar, and the other buildings to be presented in the signal coverage area are similar. The signal coverage quality presenting device can acquire N MR data reported by UE (user equipment) in a floor to be presented of a building to be presented in a signal coverage area, namely MR data reported by all UE in the floor to be presented, wherein the number of the MR data reported by all the UE is N. For example: and the signal coverage quality presenting device acquires the MR data reported by all the UE from the base station.

Wherein the MR data may comprise at least one of: station height, station spacing, road overlapping coverage, cell overlapping coverage, the number of over-coverage affected cells, the number of isolated cells, Circuit Switching (CS) domain high Block Error rate (BLER) cell fraction, Packet Switching (PS) domain high BLER cell fraction, Uplink Pilot Channel (UpPCH) interfering cell fraction, Uplink interfering cell fraction, UE high transmit Power cell fraction, Uplink average Received Signal Code Power (RSCP), average antenna arrival angle, average upper (lower) row Signal-to-noise Ratio, and average Signal-to-noise Ratio target.

S102, determining an identifier corresponding to the signal coverage quality of the floor to be presented according to the N MR data.

In this embodiment, after the N MR data are obtained, the MR data may reflect the signal coverage quality of the floor to be presented where the UE reporting the MR data is located, and then the signal coverage quality of the floor to be presented may be determined according to the N MR data, so that an identifier corresponding to the signal coverage quality may be used to identify the signal coverage quality.

S103, marking the identifier outside the floor to be presented in the 3D simulation building corresponding to the building to be presented.

In this embodiment, a user can obtain, through computer software simulation signals, each building to be represented in a coverage area, a 3D simulation building corresponding to each building to be represented, where the 3D simulation building is the same as the building to be represented. After determining the identifier for representing the signal coverage quality of the floor to be presented, the identifier determined in the above step S102 is marked outside the floor to be presented in the 3D simulation building corresponding to the building to be presented. For example: and if the identifier of the signal coverage quality of the 3 rd floor of the building to be presented is determined, marking the identifier outside the 3 rd floor of the 3D simulation building corresponding to the building to be presented.

Optionally, the identification may include at least one of: color identification, texture identification, color depth identification and texture density identification.

When the mark is a color mark, the mark is marked outside a floor to be presented in the 3D simulation building corresponding to the building to be presented, and the method comprises the following steps: and marking the color corresponding to the signal coverage quality outside the floor to be presented in the 3D simulation building corresponding to the building to be presented, and marking different colors outside the floor to be presented in the 3D simulation building by different marks. For example: if the signal coverage quality is good, the external mark of the floor to be presented in the 3D simulation building is green, if the signal coverage quality is medium, the external mark of the floor to be presented in the 3D simulation building is red, and if the signal coverage quality is poor, the external mark of the floor to be presented in the 3D simulation building is yellow.

When the mark is a color depth mark, marking the mark outside a floor to be presented in the 3D simulation building corresponding to the building to be presented, including: and marking the color of the depth corresponding to the signal coverage quality outside the floor to be presented in the 3D simulation building corresponding to the building to be presented, and marking different depths of the same color outside the floor to be presented in the 3D simulation building by different marks. For example: if the signal coverage quality is good, the external mark of the floor to be presented in the 3D simulation building is dark green, if the signal coverage quality is medium, the external mark of the floor to be presented in the 3D simulation building is light green, and if the signal coverage quality is poor, the external mark of the floor to be presented in the 3D simulation building is white.

When the mark is a texture mark, marking the mark outside a floor to be presented in the 3D simulation building corresponding to the building to be presented, including: and marking the texture corresponding to the signal coverage quality outside the floor to be presented in the 3D simulation building corresponding to the building to be presented, and marking different textures outside the floor to be presented in the 3D simulation building by different marks. For example: if the signal coverage quality is good, the texture corresponding to (a) in fig. 2 is indicated by the external mark of the floor to be presented in the 3D simulation building, if the signal coverage quality is medium, the texture corresponding to (B) in fig. 2 is indicated by the external mark of the floor to be presented in the 3D simulation building, and if the signal coverage quality is poor, the texture corresponding to (C) in fig. 2 is indicated by the external mark of the floor to be presented in the 3D simulation building.

When the mark is a texture density mark, marking the mark outside a floor to be presented in the 3D simulation building corresponding to the building to be presented, including: and marking the texture of the sparse density corresponding to the signal coverage quality outside the floor to be presented in the 3D simulation building corresponding to the building to be presented, and marking different sparse densities of the same texture outside the floor to be presented in the 3D simulation building by different marks. For example: if the signal coverage quality is good, the texture of the external mark of the floor to be presented in the 3D simulation building is dense, if the signal coverage quality is medium, the texture of the external mark of the floor to be presented in the 3D simulation building is sparse, and if the signal coverage quality is poor, the texture of the external mark of the floor to be presented in the 3D simulation building is sparse.

In this embodiment, the signal coverage quality of one to-be-presented floor of the building to be presented can be identified through the above S101 to S103, and the signal coverage quality of all to-be-presented floors of the building to be presented can be identified through the execution of the above S101 to S103 for each to-be-presented floor. And then, processing the building to be presented according to the method, and identifying the signal coverage quality of all floors to be presented of all buildings to be presented in the signal coverage area. Therefore, telecommunication operation and maintenance engineers can clearly know the signal coverage quality of each floor in each entity building through the marks outside each floor in the 3D simulation building corresponding to all buildings to be presented in the signal coverage area, and then can directly position the floor with poor signal coverage quality, and the fault positioning efficiency is improved.

In this embodiment, N MR data reported by UE on a floor to be represented of a building to be represented in a signal coverage area are acquired; determining an identifier corresponding to the signal coverage quality of the floor to be presented according to the N MR data; and marking the identifier outside the floor to be presented in the 3D simulation building corresponding to the building to be presented. Therefore, telecommunication operation and maintenance engineers can clearly know the signal coverage quality of each floor in each entity building through the marks outside each floor in the 3D simulation building corresponding to all buildings to be presented in the signal coverage area, and then can directly position the floor with poor signal coverage quality, and the fault positioning efficiency is improved.

Fig. 3 is a flowchart of a second embodiment of the signal coverage quality presenting method of the present invention, as shown in fig. 3, the method of this embodiment may include:

s201, obtaining N MR data reported by UE in floors to be presented of building buildings to be presented in a signal coverage area, wherein N is an integer greater than or equal to 1, the building to be presented is any building in the signal coverage area, and the floor to be presented is any floor in the building to be presented.

In this embodiment, the specific implementation process of S201 may refer to the relevant record in S101 in the first embodiment of the method of the present invention, and details are not described here.

S202, determining the number M of MR data meeting preset conditions in the N pieces of MR data, wherein M is an integer which is greater than or equal to 1 and less than or equal to N.

In this embodiment, the number of MR data satisfying the preset condition may be determined from the N MR data, where the number is M, and the M is between 1 and N. If the embodiment needs to identify the floor with the signal coverage quality not meeting the use requirement, the signal coverage quality indicated by the MR data meeting the preset condition is poor; and if the signal coverage quality indicated by the MR data which do not meet the preset conditions meets the floor with the use requirement, the signal coverage quality indicated by the MR data which meet the preset conditions is good.

S203, determining an identifier corresponding to the signal coverage quality of the floor to be presented according to the ratio of M to N.

In this embodiment, after the number of MR data satisfying the preset condition is determined to be M, the M is compared with the N to obtain a ratio of the M to the N, and the ratio may reflect a ratio occupied by the MR data satisfying the preset condition. And thus, according to the ratio of the M to the N, determining the identifier corresponding to the signal coverage quality of the floor to be presented.

Specifically, if the signal coverage quality is divided into two categories, that is, the signal coverage quality is good or the signal coverage quality is poor, the relationship between the ratio of M to N and a preset value may be determined, and if the ratio of M to N is greater than the preset value, the identifier corresponding to the signal coverage quality of the floor to be presented may be determined to be the identifier corresponding to the good signal coverage quality (in another implementation, the identifier corresponding to the poor signal coverage quality); if the ratio of M to N is not greater than the preset value, it may be determined that the identifier corresponding to the signal coverage quality of the floor to be presented is an identifier corresponding to poor signal coverage quality (in another implementation, the identifier corresponding to good signal coverage quality).

Specifically, if the signal coverage quality is classified into three categories, the signal coverage quality is good, medium, and poor. Judging the relation between the ratio of M to N, a first preset value and a second preset value, wherein the first preset value is larger than the second preset value; if the ratio of the M to the N is greater than or equal to the first preset value, determining that the identifier corresponding to the signal coverage quality of the floor to be presented is a first identifier; if the ratio of the M to the N is greater than a second preset value and less than a first preset value, determining that the identifier corresponding to the signal coverage quality of the floor to be presented is a second identifier; if the ratio of the M to the N is less than or equal to the second preset value, determining that the identifier corresponding to the signal coverage quality of the floor to be presented is a third identifier; in a first possible implementation manner, the first identifier is an identifier corresponding to good signal coverage quality, the second identifier is a corresponding identifier in signal coverage quality, and the third identifier is an identifier corresponding to poor signal coverage quality; in a second possible implementation manner, the first identifier is an identifier corresponding to poor signal coverage quality, the second identifier is a corresponding identifier in signal coverage quality, and the third identifier is an identifier corresponding to good signal coverage quality.

In the following, MR data is taken as an example of the uplink average Received Signal Code Power (RSCP) and the flag is a color flag. Determining the number of the uplink average RSCPs larger than-75 dBm in the N uplink average RSCP as M, and if the ratio of the M to the N is larger than or equal to 80%, determining that the mark corresponding to the signal coverage quality of the floor to be presented is green, so that the green color can be rendered outside the floor to be presented of the 3D simulation building; if the ratio of the M to the N is more than 60% and less than 80%, determining that the identifier corresponding to the signal coverage quality of the floor to be presented is yellow, so that yellow can be rendered outside the floor to be presented of the 3D simulation building; and if the ratio of the M to the N is less than or equal to 60%, determining that the identifier corresponding to the signal coverage quality of the floor to be presented is red, so that the red can be rendered outside the floor to be presented of the 3D simulation building.

And S204, marking the identifier outside the floor to be presented in the 3D simulation building corresponding to the building to be presented.

In this embodiment, the specific implementation process of S204 may refer to the relevant record in S103 in the first embodiment of the method of the present invention, and is not described herein again.

In this embodiment, N MR data reported by UE on a floor to be represented of a building to be represented in a signal coverage area are acquired; determining the number M of MR data meeting preset conditions in the N MR data, and determining an identifier corresponding to the signal coverage quality of the floor to be presented according to the ratio of the M to the N; and marking the identifier outside the floor to be presented in the 3D simulation building corresponding to the building to be presented. Therefore, telecommunication operation and maintenance engineers can clearly know the signal coverage quality of each floor in each entity building through the marks outside each floor in the 3D simulation building corresponding to all buildings to be presented in the signal coverage area, and then can directly position the floor with poor signal coverage quality, and the fault positioning efficiency is improved.

Fig. 4 is a flowchart of a third embodiment of a method for presenting signal coverage quality of the present invention, as shown in fig. 4, the method of this embodiment may include:

s301, N MR data reported by UE in floors to be presented of building buildings to be presented in a signal coverage area are obtained, wherein N is an integer larger than or equal to 1, the building to be presented is any building in the signal coverage area, and the floor to be presented is any floor in the building to be presented.

In this embodiment, the specific implementation process of S301 may refer to the relevant record in S101 in the first embodiment of the method of the present invention, and is not described herein again.

S302, determining the number of the MR data respectively meeting H different preset conditions in the N pieces of MR data, wherein the sum of the H number of the MR data is equal to N.

In this embodiment, for example, the H different preset conditions are respectively the 1 st preset condition, the 2 nd preset condition, … … and the H th preset condition, wherein the 1 st preset condition, the 2 nd preset condition, … … and the H th preset condition are different from each other; determining a value of the number of MR data satisfying the 1 st preset condition among the N MR data as H1, determining values of the number of MR data satisfying the 1 st preset condition among the N MR data as H2, … …, determining a value of the number of MR data satisfying the 1 st preset condition among the N MR data as HH, and H1+ H2+ … + HH being equal to the N.

S303, determining an identifier corresponding to the signal coverage quality of the floor to be presented according to the size relationship between the determined H number values.

In this embodiment, after determining the number of MR data satisfying H different preset conditions in the N pieces of MR data, that is, after determining the number of H pieces of MR data (H1, H2, and … HH, respectively), the identifier corresponding to the signal coverage quality of the floor to be presented is determined according to the magnitude relationship among the H pieces of data values, that is, according to the magnitude relationship among H1, H2, and … HH.

Optionally, the determining, according to the magnitude relationship between the H determined individual numerical values, an identifier corresponding to the signal coverage quality of the floor to be presented includes: determining the signal coverage quality grade of the floor to be presented according to the magnitude relation among the H numerical values; determining the identifier corresponding to the signal coverage quality grade according to the signal coverage quality grade of the floor to be presented; and the marks corresponding to different signal coverage quality grades are different. Specifically, the signal coverage quality classes may be divided into H different signal coverage quality classes, each signal coverage quality class has an identifier corresponding thereto, and the identifiers corresponding to different signal coverage quality classes are different. Taking H equal to 2 as an example, determining whether the signal coverage quality grade of the floor to be presented is a first signal coverage quality grade or a second signal coverage quality grade according to the magnitude relation among the values of the 2 numbers; and then determining an identifier corresponding to the first signal coverage quality level according to the first signal coverage quality level, or determining an identifier corresponding to the second signal coverage quality level according to the second signal coverage quality level.

In the following, taking H equal to 3 provided in the fourth embodiment of the method of the present invention as an example, how to determine the identifier corresponding to the signal coverage quality of the floor to be presented according to the size relationship between the determined values of the H numbers is described in detail, and a specific implementation manner of determining the identifier corresponding to the signal coverage quality of the floor to be presented according to the size relationship between the determined values of the H numbers when determining that H is equal to 2, 4, and 5 … can be determined by a person skilled in the art according to the fourth embodiment of the method of the present invention.

S304, marking the identifier outside the floor to be presented in the 3D simulation building corresponding to the building to be presented.

In this embodiment, the specific implementation process of S304 may refer to the relevant record in S103 in the first embodiment of the method of the present invention, and is not described herein again.

In this embodiment, N MR data reported by UE on a floor to be represented of a building to be represented in a signal coverage area are acquired; determining the number of MR data respectively meeting H different preset conditions in the N pieces of MR data; determining an identifier corresponding to the signal coverage quality of the floor to be presented according to the magnitude relation between the determined H number values; and marking the identifier outside the floor to be presented in the 3D simulation building corresponding to the building to be presented. Therefore, telecommunication operation and maintenance engineers can clearly know the signal coverage quality of each floor in each entity building through the marks outside each floor in the 3D simulation building corresponding to all buildings to be presented in the signal coverage area, and then can directly position the floor with poor signal coverage quality, and the fault positioning efficiency is improved.

Fig. 5 is a flowchart of a fourth embodiment of the method for presenting signal coverage quality of the present invention, as shown in fig. 5, in this embodiment, H is equal to 3 as an example for description, and the method of this embodiment may include:

s401, N MR data reported by UE in floors to be presented of building buildings to be presented in a signal coverage area are obtained, wherein N is an integer larger than or equal to 1, the building to be presented is any building in the signal coverage area, and the floor to be presented is any floor in the building to be presented.

In this embodiment, the specific implementation process of S401 may refer to the relevant record in S101 in the first embodiment of the method of the present invention, and is not described herein again.

S402, determining the number of the MR data meeting a first preset condition in the N pieces of MR data to be X, the number of the MR data meeting a second preset condition to be Y and the number of the MR data meeting a third preset condition to be Z.

In this embodiment, the range of the MR data may be divided into three types, one type is MR data satisfying a first preset condition, one type is MR data satisfying a second preset condition, and one type is MR data satisfying a third preset condition; from the N pieces of MR data, it may be determined that the number of pieces of MR data satisfying the first preset condition is X, the number of pieces of MR data satisfying the second preset condition is Y, and the number of pieces of MR data satisfying the third preset condition is Z, where X + Y + Z is N.

S403, determining an identifier corresponding to the signal coverage quality of the floor to be presented according to the size relationship among the X, the Y and the Z.

In this embodiment, the identifier corresponding to the signal coverage quality of the floor to be presented may be determined according to the magnitude relationship among the X, the Y, and the Z. Optionally, the signal coverage quality level of the floor to be presented may be determined according to the magnitude relationship among the X, the Y, and the Z, and then the identifier corresponding to the signal coverage quality level may be determined according to the signal coverage quality level; for example: if the determined signal coverage quality grade is a signal coverage quality grade corresponding to a first preset condition, determining the identifier as a first identifier according to the signal coverage quality grade; if the determined signal coverage quality grade is a signal coverage quality grade corresponding to a second preset condition, determining the identifier as a second identifier according to the signal coverage quality grade; if the determined signal coverage quality level is a signal coverage quality level corresponding to the third preset condition, the identifier may be determined to be the third identifier according to the signal coverage quality level.

In a first possible implementation, the N MR data all satisfy the same preset condition.

If N MR data all satisfy a first preset condition, X is N, Y is 0, Z is 0, and the identifier corresponding to the signal coverage quality of the floor to be presented may be determined as the first identifier corresponding to the first preset condition. If N MR data all satisfy a second preset condition, Y is N, X is 0, Z is 0, and the identifier corresponding to the signal coverage quality of the floor to be presented may be determined as a second identifier corresponding to the second preset condition. If N MR data all satisfy the third preset condition, Z is N, X is 0, and Y is 0, then the identifier corresponding to the signal coverage quality of the floor to be presented may be determined as the third identifier corresponding to the second preset condition.

In a second possible implementation manner, a part of the N MR data satisfies one of the preset conditions, and another part of the MR data satisfies another one of the preset conditions.

If X MR data of the N MR data satisfy a first preset condition, Y MR data satisfy a second preset condition, and X + Y is N, Z is 0; when X is greater than Y, it may be determined that the identifier corresponding to the signal coverage quality of the floor to be presented is the first identifier corresponding to the first preset condition; when X is smaller than Y, it may be determined that the identifier corresponding to the signal coverage quality of the floor to be presented is the second identifier corresponding to the second preset condition. If X is equal to Y, it may be determined that the identifier corresponding to the signal coverage quality of the floor to be presented is the second identifier corresponding to the second preset condition, where the signal coverage quality corresponding to the second identifier is lower than the signal coverage quality corresponding to the first identifier.

If X MR data of the N MR data satisfy a first preset condition, Z MR data satisfy a third preset condition, and X + Z is N, Y is 0; when X is greater than Z, it may be determined that the identifier corresponding to the signal coverage quality of the floor to be presented is the first identifier corresponding to the first preset condition; when X is smaller than Z, it may be determined that the identifier corresponding to the signal coverage quality of the floor to be presented is a third identifier corresponding to the third preset condition. If X is equal to Z, it may be determined that the identifier corresponding to the signal coverage quality of the floor to be presented is a third identifier corresponding to the third preset condition, where the signal coverage quality corresponding to the third identifier is lower than the signal coverage quality corresponding to the first identifier.

If Y MR data of the N MR data satisfy the second preset condition, Z MR data satisfy the third preset condition, and Y + Z is N, X is 0; when Y is greater than Z, it may be determined that the identifier corresponding to the signal coverage quality of the floor to be presented is a second identifier corresponding to the second preset condition; when Y is smaller than Z, it may be determined that the identifier corresponding to the signal coverage quality of the floor to be presented is a third identifier corresponding to the third preset condition. If Y is equal to Z, it may be determined that the identifier corresponding to the signal coverage quality of the floor to be presented is a third identifier corresponding to the third preset condition, where the signal coverage quality corresponding to the third identifier is lower than the signal coverage quality corresponding to the second identifier.

In a third possible implementation manner, X MR data of the N MR data satisfy the first preset condition, Y MR data satisfy the second preset condition, Z MR data satisfy the third preset condition, and X + Y + Z is equal to N.

Under the condition that X is not equal to Y and is not equal to Z, when X is larger than Y + Z, determining that the identifier corresponding to the signal coverage quality of the floor to be presented is a first identifier corresponding to the first preset condition; when X is smaller than Y + Z and Y is larger than Z, it may be determined that the identifier corresponding to the signal coverage quality of the floor to be presented is a second identifier corresponding to the second preset condition; when X is less than Y + Z and Y is less than or equal to Z, it may be determined that the identifier corresponding to the signal coverage quality of the floor to be presented is a third identifier corresponding to the third preset condition; when X is equal to Y + Z and Y is greater than or equal to Z, it may be determined that the identifier corresponding to the signal coverage quality of the floor to be presented is a second identifier corresponding to the second preset condition; when X is equal to Y + Z and Y is less than Z, it may be determined that the identifier corresponding to the signal coverage quality of the floor to be presented is a third identifier corresponding to the third preset condition.

In case X equals Y and X also equals Z, it may be determined that the identifier corresponding to the signal coverage quality of the floor to be presented is the second identifier corresponding to the second preset condition.

And the signal coverage quality corresponding to the first identifier is higher than that corresponding to the second identifier, and the signal coverage quality corresponding to the second identifier is higher than that corresponding to the third identifier.

S404, marking the identifier outside the floor to be presented in the 3D simulation building corresponding to the building to be presented.

In this embodiment, the specific implementation process of S304 may refer to the relevant record in S103 in the first embodiment of the method of the present invention, and is not described herein again.

In this embodiment, N MR data reported by UE on a floor to be represented of a building to be represented in a signal coverage area are acquired; determining the number of MR data meeting a first preset condition in the N pieces of MR data as X, the number of MR data meeting a second preset condition as Y and the number of MR data meeting a third preset condition as Z; determining an identifier corresponding to the signal coverage quality of the floor to be presented according to the size relation of X, Y, Z; and marking the identifier outside the floor to be presented in the 3D simulation building corresponding to the building to be presented. Therefore, telecommunication operation and maintenance engineers can clearly know the signal coverage quality of each floor in each entity building through the marks outside each floor in the 3D simulation building corresponding to all buildings to be presented in the signal coverage area, and then can directly position the floor with poor signal coverage quality, and the fault positioning efficiency is improved.

The technical solution of the fourth embodiment of the method of the present invention is described in detail below by using a specific implementation manner. Taking MR data as uplink average RSCP, a first preset condition of being more than or equal to-60 dBm, a second preset condition of being more than-85 dBm and less than-60 dBm, a third preset condition of being less than or equal to-85 dBm, a mark as a color mark, a first mark corresponding to the first preset condition as green (representing good signal coverage quality), a second mark corresponding to the second preset condition as yellow (representing in signal coverage quality), and a third mark corresponding to the third preset condition as red (representing poor signal coverage quality). Wherein the number of MR data of which the number of MR data is greater than or equal to-60 dBm among the N pieces of MR data is X, N, the number of MR data of which the number of MR data is greater than-85 dBm and less than-60 dBm among the N pieces of MR data is Y, N, and the number of MR data of which the number of MR data is less than or equal to-85 dBm among the N pieces of MR data is Z.

In a first possible implementation, the N MR data all satisfy the same preset condition.

When the N pieces of MR data are all larger than or equal to-60 dBm, namely X is equal to N, the identifier corresponding to the signal coverage quality of the floor to be presented is determined to be green, and then the green is rendered outside the floor to be presented of the building to be presented in the 3D simulation mode.

And when the N pieces of MR data are all larger than-85 dBm and smaller than-60 dBm, namely Y is equal to N, determining that the mark corresponding to the signal coverage quality of the floor to be presented is yellow, and then rendering the yellow outside the floor to be presented of the building to be presented in a 3D simulation mode.

When the N data are all smaller than or equal to-85 dBm, namely Z is equal to N, the identifier corresponding to the signal coverage quality of the floor to be presented is determined to be red, and then the red is rendered outside the floor to be presented of the building to be presented in the 3D simulation mode.

In a second possible implementation manner, a part of the N MR data satisfies one of the preset conditions, and another part of the MR data satisfies another one of the preset conditions.

If none of the N MR data is less than or equal to-85 dBm; when X is larger than Y, determining that the identifier corresponding to the signal coverage quality of the floor to be presented is green, and then rendering green outside the floor to be presented of the building to be presented in the 3D simulation mode; when X is not larger than Y, determining that the identifier corresponding to the signal coverage quality of the floor to be presented is yellow, and then rendering yellow outside the floor to be presented of the building to be presented in the 3D simulation mode.

If none of the N MR data is larger than-85 dBm and smaller than-60 dBm; when X is larger than Z, determining that the identifier corresponding to the signal coverage quality of the floor to be presented is green, and then rendering green outside the floor to be presented of the building to be presented in the 3D simulation mode; and when the X is not more than Z, determining that the identifier corresponding to the signal coverage quality of the floor to be presented is red, and then rendering the red outside the floor to be presented of the building to be presented in the 3D simulation.

If none of the N MR data is larger than or equal to-60 dBm; when Y is larger than Z, determining that the identifier corresponding to the signal coverage quality of the floor to be presented is yellow, and then rendering yellow outside the floor to be presented of the building to be presented in a 3D simulation mode; and when Y is not more than Z, determining that the identifier corresponding to the signal coverage quality of the floor to be presented is red, and then rendering red outside the floor to be presented of the building to be presented in the 3D simulation.

In a third possible implementation, there are MR data of greater than or equal to-60 dBm, also MR data of greater than-85 dBm and less than-60 dBm, and also MR data of less than or equal to-85 dBm of the N MR data.

In the case where X is not equal to Y, and X is not equal to Z.

And when X is larger than Y + Z, determining that the identifier corresponding to the signal coverage quality of the floor to be presented is green, and then rendering green outside the floor to be presented of the building to be presented in the 3D simulation.

When X is smaller than Y + Z and Y is larger than Z, determining that the identifier corresponding to the signal coverage quality of the floor to be presented is yellow, and then rendering yellow outside the floor to be presented of the building to be presented in the 3D simulation mode.

When X is smaller than Y + Z and Y is smaller than or equal to Z, determining that the identifier corresponding to the signal coverage quality of the floor to be presented is red, and then rendering red outside the floor to be presented of the building to be presented in the 3D simulation mode.

When X is equal to Y + Z and Y is larger than or equal to Z, determining that the identifier corresponding to the signal coverage quality of the floor to be presented is yellow, and then rendering yellow outside the floor to be presented of the building to be presented in the 3D simulation mode.

When X is equal to Y + Z and Y is less than Z, determining that the identifier corresponding to the signal coverage quality of the floor to be presented is red, and then rendering the red outside the floor to be presented of the building to be presented in the 3D simulation.

In the case where X is equal to Y and X is also equal to Z, the identifier corresponding to the signal coverage quality of the floor to be presented is determined as yellow, and then yellow is rendered outside the floor to be presented of the building to be presented in a 3D simulation.

Fig. 6 is a schematic structural diagram of a first embodiment of a signal coverage quality presenting apparatus according to the present invention, as shown in fig. 6, the apparatus of the present embodiment may include: an acquisition unit 11, a determination unit 12 and a processing unit 13; the acquiring unit 11 is configured to acquire N MR data reported by UE on floors to be presented of buildings to be presented in a signal coverage area, where N is an integer greater than or equal to 1, the building to be presented is any building in the signal coverage area, and the floor to be presented is any floor in the building to be presented; a determining unit 12, configured to determine, according to the N MR data acquired by the acquiring unit 11, an identifier corresponding to the signal coverage quality of the floor to be presented; and the processing unit 13 is configured to mark the identifier determined by the determining unit 12 outside the 3D simulation building corresponding to the building to be represented.

Optionally, the determining unit 12 is specifically configured to determine a number M of MR data that meet a preset condition in the N MR data, where M is an integer greater than or equal to 1 and less than or equal to N; and determining an identifier corresponding to the signal coverage quality of the floor to be presented according to the ratio of the M to the N.

Optionally, the determining unit 12 is configured to determine, according to the ratio of M to N, an identifier corresponding to the signal coverage quality of the floor to be presented, and determine an identifier corresponding to the signal quality of the first floor, including: the determining unit 12 is specifically configured to, when it is determined that the ratio of M to N is greater than or equal to a first preset value, determine that an identifier corresponding to the signal coverage quality of the floor to be presented is a first identifier; when the ratio of the M to the N is smaller than or equal to a second preset value, determining that the identifier corresponding to the signal coverage quality of the floor to be presented is a second identifier; when the ratio of M to N is smaller than the first preset value and larger than the second preset value, determining that the identifier corresponding to the signal coverage quality of the floor to be presented is a third identifier; wherein the first preset value is greater than the second preset value.

Optionally, the determining unit 12 is specifically configured to determine values of numbers of MR data that respectively satisfy H different preset conditions in the N MR data, where H is an integer greater than or equal to 2, and a sum of the H numbers of values is equal to the N; and determining an identifier corresponding to the signal coverage quality of the floor to be presented according to the magnitude relation between the determined H number values.

Optionally, the determining unit 12 is configured to determine, according to the magnitude relationship between the H numerical values, an identifier corresponding to the signal coverage quality of the floor to be presented, and includes: the determining unit 12 is specifically configured to determine, according to a magnitude relationship between the H numerical values, a signal coverage quality level of the floor to be presented; determining the identifier corresponding to the signal coverage quality grade according to the signal coverage quality grade of the floor to be presented; and the marks corresponding to different signal coverage quality grades are different.

Optionally, when H is 3, the determining unit 12 is configured to determine the number of MR data respectively satisfying H different preset conditions in the N MR data, and includes: the determining unit 12 is specifically configured to determine that, of the N MR data, the number of MR data meeting a first preset condition is X, the number of MR data meeting a second preset condition is Y, and the number of MR data meeting a third preset condition is Z;

the determining unit 12 is configured to determine, according to the magnitude relationship between the H numerical values, an identifier corresponding to the signal coverage quality of the floor to be presented, including: the determining unit 12 is specifically configured to determine, according to a size relationship among the X, the Y, and the Z, an identifier corresponding to the signal coverage quality of the floor to be presented; wherein X, Y and Z are integers which are respectively greater than or equal to 0 and less than or equal to N, and X + Y + Z is equal to N.

Optionally, if the X is not equal to the Y and the Z, the determining unit 12 is configured to determine, according to a size relationship between the X, the Y and the Z, an identifier corresponding to the signal coverage quality of the floor to be presented, and includes: the determining unit 12 is specifically configured to, when it is determined that X is equal to N; or, said Y is equal to 0, said X is greater than said Z; or, said Z is equal to 0, said X is greater than said Y; or when the X is larger than the Y + the Z, determining that the identifier corresponding to the signal coverage quality of the floor to be presented is a first identifier corresponding to the first preset condition; and when it is determined that Y is equal to N; or, said X is equal to 0, said Y is greater than said Z; alternatively, said Z is equal to 0, said X is not greater than said Y; or, said X is less than said Y + said Z, said Y is greater than said Z; or when the X is equal to the Y plus the Z and the Y is not less than the Z, determining that the identifier corresponding to the signal coverage quality of the floor to be presented is a second identifier corresponding to the second preset condition; and when said Z is equal to said N; or, X is equal to 0, Y is not greater than Z, or, Y is equal to 0, X is not greater than Z; or, said X is less than said Y + said Z, said Y is not greater than said Z; or when the X is equal to the Y plus the Z and the Y is smaller than the Z, determining that the identifier corresponding to the signal coverage quality of the floor to be presented is a third identifier corresponding to the third preset condition; or,

if X is equal to Y and Z, the determining unit 12 is configured to determine, according to a size relationship between X, Y and Z, an identifier corresponding to the signal coverage quality of the floor to be presented, including: the determining unit 12 is specifically configured to determine, according to the time when the X is equal to the Y and the Z, that the signal coverage quality level of the floor to be presented is a second identifier corresponding to the second preset condition.

Optionally, the signal coverage quality corresponding to the first identifier is higher than the signal coverage quality corresponding to the second identifier, and the signal coverage quality corresponding to the second identifier is higher than the signal coverage quality corresponding to the third identifier.

Optionally, the identifier determined by the determining unit 12 includes at least one of: color identification, texture identification, color depth identification and texture density identification.

Fig. 7 is a schematic structural diagram of a second embodiment of the signal coverage quality presenting apparatus according to the present invention, as shown in fig. 7, a memory 21 and a processor 22; wherein the memory 21 is used for storing codes for executing the signal coverage quality presenting method; the Memory 21 may include a Non-volatile Memory (Non-volatile Memory). Processor 22 may be a Central Processing Unit (CPU), or an Application Specific Integrated Circuit (ASIC), or one or more Integrated circuits configured to implement embodiments of the present invention. The processor 22 is configured to call the code and perform the following operations: acquiring N MR data reported by UE (user equipment) in floors to be presented of building buildings to be presented in a signal coverage area, wherein N is an integer greater than or equal to 1, the building to be presented is any building in the signal coverage area, and the floor to be presented is any floor in the building to be presented; determining an identifier corresponding to the signal coverage quality of the floor to be presented according to the N MR data; and marking the identifier outside the floor to be presented in the three-dimensional 3D building corresponding to the building to be presented.

The processor 22 is configured to determine, according to the N MR data, an identifier corresponding to the signal coverage quality of the floor to be presented, including: the processor 22 is specifically configured to determine a number M of MR data that satisfy a preset condition in the N MR data, where M is an integer greater than or equal to 1 and less than or equal to N; and determining an identifier corresponding to the signal coverage quality of the floor to be presented according to the ratio of the M to the N.

Optionally, the processor 22 is configured to determine, according to the ratio of M to N, an identifier corresponding to the signal coverage quality of the floor to be presented, and determine an identifier corresponding to the signal quality of the first floor, including: the processor 22 is specifically configured to, when it is determined that the ratio of M to N is greater than or equal to a first preset value, determine that an identifier corresponding to the signal coverage quality of the floor to be presented is a first identifier; when the ratio of the M to the N is smaller than or equal to a second preset value, determining that the identifier corresponding to the signal coverage quality of the floor to be presented is a second identifier; when the ratio of M to N is smaller than the first preset value and larger than the second preset value, determining that the identifier corresponding to the signal coverage quality of the floor to be presented is a third identifier; wherein the first preset value is greater than the second preset value.

Optionally, the processor 22 is configured to determine, according to the N MR data, an identifier corresponding to the signal coverage quality of the floor to be presented, including: the processor 22 is specifically configured to determine values of numbers of MR data that respectively satisfy H different preset conditions in the N MR data, where H is an integer greater than or equal to 2, and a sum of the H numbers of values is equal to N; and determining an identifier corresponding to the signal coverage quality of the floor to be presented according to the magnitude relation between the determined H number values.

Optionally, the processor 22 is configured to determine, according to the magnitude relationship between the H numerical values, an identifier corresponding to the signal coverage quality of the floor to be presented, including: the processor 22 is specifically configured to determine, according to a magnitude relationship between the H numerical values, a signal coverage quality level of the floor to be presented; determining the identifier corresponding to the signal coverage quality grade according to the signal coverage quality grade of the floor to be presented; and the marks corresponding to different signal coverage quality grades are different.

Optionally, when H is 3, the processor 22 is configured to determine the number of MR data of the N MR data that respectively satisfy H different preset conditions, including: the processor 22 is specifically configured to determine that, of the N MR data, the number of MR data that satisfy a first preset condition is X, the number of MR data that satisfy a second preset condition is Y, and the number of MR data that satisfy a third preset condition is Z;

the processor 22 is configured to determine, according to the magnitude relationship between the H numerical values, an identifier corresponding to the signal coverage quality of the floor to be presented, including: the processor 22 is specifically configured to determine, according to a size relationship among the X, the Y, and the Z, an identifier corresponding to the signal coverage quality of the floor to be presented; wherein X, Y and Z are integers which are respectively greater than or equal to 0 and less than or equal to N, and X + Y + Z is equal to N.

Optionally, if the X is not equal to the Y and the Z, the processor 22 is configured to determine, according to a size relationship among the X, the Y and the Z, an identifier corresponding to the signal coverage quality of the floor to be presented, including: the processor 22 is specifically configured to, when it is determined that X is equal to N; or, said Y is equal to 0, said X is greater than said Z; or, said Z is equal to 0, said X is greater than said Y; or when the X is larger than the Y + the Z, determining that the identifier corresponding to the signal coverage quality of the floor to be presented is a first identifier corresponding to the first preset condition; and when it is determined that Y is equal to N; or, said X is equal to 0, said Y is greater than said Z; alternatively, said Z is equal to 0, said X is not greater than said Y; or, said X is less than said Y + said Z, said Y is greater than said Z; or when the X is equal to the Y plus the Z and the Y is not less than the Z, determining that the identifier corresponding to the signal coverage quality of the floor to be presented is a second identifier corresponding to the second preset condition; and when said Z is equal to said N; or, X is equal to 0, Y is not greater than Z, or, Y is equal to 0, X is not greater than Z; or, said X is less than said Y + said Z, said Y is not greater than said Z; or when the X is equal to the Y plus the Z and the Y is smaller than the Z, determining that the identifier corresponding to the signal coverage quality of the floor to be presented is a third identifier corresponding to the third preset condition; or,

if the X is equal to the Y and the Z, the processor 22 is configured to determine, according to a size relationship among the X, the Y, and the Z, an identifier corresponding to the signal coverage quality of the floor to be presented, including: the processor 22 is specifically configured to determine, when X is equal to Y and Z, that the signal coverage quality level of the floor to be presented is a second identifier corresponding to the second preset condition.

Optionally, the signal coverage quality corresponding to the first identifier is higher than the signal coverage quality corresponding to the second identifier, and the signal coverage quality corresponding to the second identifier is higher than the signal coverage quality corresponding to the third identifier.

Optionally, the identification determined by the processor 22 comprises at least one of: color identification, texture identification, color depth identification and texture density identification.

Those of ordinary skill in the art will understand that: all or a portion of the steps of implementing the above-described method embodiments may be performed by hardware associated with program instructions. The program may be stored in a computer-readable storage medium. When executed, the program performs steps comprising the method embodiments described above; and the aforementioned storage medium includes: Read-Only Memory (ROM), Random Access Memory (RAM), magnetic or optical disk, and other various media capable of storing program codes.

Finally, it should be noted that: the above embodiments are only used to illustrate the technical solution of the present invention, and not to limit the same; while the invention has been described in detail and with reference to the foregoing embodiments, it will be understood by those skilled in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some or all of the technical features may be equivalently replaced; and the modifications or the substitutions do not make the essence of the corresponding technical solutions depart from the scope of the technical solutions of the embodiments of the present invention.

Claims (14)

1. A method for presenting signal coverage quality, comprising:

acquiring N measurement report MR data reported by User Equipment (UE) in floors to be presented of building buildings to be presented in a signal coverage area, wherein N is an integer greater than or equal to 1, the building to be presented is any building in the signal coverage area, and the floor to be presented is any floor in the building to be presented;

determining an identifier corresponding to the signal coverage quality of the floor to be presented according to the N MR data;

marking the mark outside the floor to be presented in the three-dimensional 3D simulation building corresponding to the building to be presented;

the determining, according to the N MR data, an identifier corresponding to the signal coverage quality of the floor to be presented includes:

determining the number M of MR data meeting a preset condition in the N pieces of MR data, wherein M is an integer which is greater than or equal to 1 and less than or equal to N;

determining an identifier corresponding to the signal coverage quality of the floor to be presented according to the ratio of the M to the N;

or, the determining, according to the N MR data, an identifier corresponding to the signal coverage quality of the floor to be presented includes:

determining the number of the MR data respectively meeting H different preset conditions in the N pieces of MR data, wherein H is an integer greater than or equal to 2, and the sum of the H number of the MR data is equal to N;

and determining an identifier corresponding to the signal coverage quality of the floor to be presented according to the size relation between the determined H number values.

2. The method of claim 1, wherein determining the identifier corresponding to the signal coverage quality of the floor to be presented according to the ratio of M to N comprises:

when the ratio of the M to the N is larger than or equal to a first preset value, determining that an identifier corresponding to the signal coverage quality of the floor to be presented is a first identifier;

when the ratio of the M to the N is smaller than or equal to a second preset value, determining that the identifier corresponding to the signal coverage quality of the floor to be presented is a second identifier;

when the ratio of the M to the N is smaller than the first preset value and larger than the second preset value, determining that the identifier corresponding to the signal coverage quality of the floor to be presented is a third identifier;

wherein the first preset value is greater than the second preset value.

3. The method according to claim 1, wherein said determining an identifier corresponding to the signal coverage quality of the floor to be presented according to the determined magnitude relationship between the H numerical values comprises:

determining the signal coverage quality grade of the floor to be presented according to the magnitude relation among the H numerical values;

determining the identifier corresponding to the signal coverage quality grade according to the signal coverage quality grade of the floor to be presented;

and the marks corresponding to different signal coverage quality grades are different.

4. The method according to claim 1 or 3, wherein when the H is 3, the determining the number of the MR data which respectively satisfy the H different preset conditions in the N MR data comprises:

determining the number of MR data meeting a first preset condition in the N pieces of MR data as X, the number of MR data meeting a second preset condition as Y and the number of MR data meeting a third preset condition as Z;

the determining, according to the magnitude relationship between the H numerical values, an identifier corresponding to the signal coverage quality of the floor to be presented includes:

determining an identifier corresponding to the signal coverage quality of the floor to be presented according to the size relationship among the X, the Y and the Z;

wherein X, Y and Z are integers which are respectively greater than or equal to 0 and less than or equal to N, and X + Y + Z is equal to N.

5. The method according to claim 4, wherein if X is not equal to Y and Z, the determining an identifier corresponding to the signal coverage quality of the floor to be presented according to the size relationship between X, Y and Z comprises:

when said X is equal to said N; or, said Y is equal to 0, said X is greater than said Z; or, said Z is equal to 0, said X is greater than said Y; or when the X is larger than the Y + the Z, determining that the identifier corresponding to the signal coverage quality of the floor to be presented is a first identifier corresponding to the first preset condition;

when said Y is equal to said N; or, said X is equal to 0, said Y is greater than said Z; alternatively, said Z is equal to 0, said X is not greater than said Y; or, said X is less than said Y + said Z, said Y is greater than said Z; or when the X is equal to the Y plus the Z and the Y is not less than the Z, determining that the identifier corresponding to the signal coverage quality of the floor to be presented is a second identifier corresponding to the second preset condition;

when said Z is equal to said N; or, X is equal to 0, Y is not greater than Z, or, Y is equal to 0, X is not greater than Z; or, said X is less than said Y + said Z, said Y is not greater than said Z; or when the X is equal to the Y plus the Z and the Y is smaller than the Z, determining that the identifier corresponding to the signal coverage quality of the floor to be presented is a third identifier corresponding to the third preset condition; or,

if the X is equal to the Y and the Z, determining the identifier corresponding to the signal coverage quality of the floor to be presented according to the size relationship among the X, the Y and the Z, including:

and when the X is equal to the Y and the Z, determining the signal coverage quality grade of the floor to be presented as a second identifier corresponding to the second preset condition.

6. The method of claim 5, wherein the signal coverage quality corresponding to the first identifier is higher than the signal coverage quality corresponding to the second identifier, and wherein the signal coverage quality corresponding to the second identifier is higher than the signal coverage quality corresponding to the third identifier.

7. The method of any of claims 1-3, wherein the identifying comprises at least one of: color identification, texture identification, color depth identification and texture density identification.

8. A signal coverage quality presentation apparatus, comprising:

the system comprises an acquisition unit, a processing unit and a processing unit, wherein the acquisition unit is used for acquiring N measurement report MR data reported by User Equipment (UE) in floors to be presented of building to be presented in a signal coverage area, N is an integer larger than or equal to 1, the building to be presented is any building in the signal coverage area, and the floor to be presented is any floor in the building to be presented;

the determining unit is used for determining an identifier corresponding to the signal coverage quality of the floor to be presented according to the N MR data acquired by the acquiring unit;

the processing unit is used for marking the identifier determined by the determining unit outside the floor to be presented in the three-dimensional 3D simulation building corresponding to the building to be presented;

the determining unit is specifically configured to determine a number M of MR data that meet a preset condition in the N MR data, where M is an integer greater than or equal to 1 and less than or equal to N; determining an identifier corresponding to the signal coverage quality of the floor to be presented according to the ratio of the M to the N;

or, the determining unit is specifically configured to determine values of numbers of MR data that respectively satisfy H different preset conditions in the N MR data, where H is an integer greater than or equal to 2, and a sum of the values of the H numbers is equal to the N; and determining an identifier corresponding to the signal coverage quality of the floor to be presented according to the magnitude relation between the determined H number values.

9. The apparatus according to claim 8, wherein the determining unit is configured to determine the identifier corresponding to the signal coverage quality of the floor to be presented according to the ratio of M to N, and includes: the determining unit is specifically configured to determine, when it is determined that the ratio of M to N is greater than or equal to a first preset value, that an identifier corresponding to the signal coverage quality of the floor to be presented is a first identifier; when the ratio of the M to the N is smaller than or equal to a second preset value, determining that the identifier corresponding to the signal coverage quality of the floor to be presented is a second identifier; when the ratio of M to N is smaller than the first preset value and larger than the second preset value, determining that the identifier corresponding to the signal coverage quality of the floor to be presented is a third identifier; wherein the first preset value is greater than the second preset value.

10. The apparatus according to claim 8, wherein the determining unit is configured to determine, according to the magnitude relationship between the H determined numerical values, an identifier corresponding to the signal coverage quality of the floor to be presented, and includes: the determining unit is specifically configured to determine, according to a magnitude relationship between the H numerical values, a signal coverage quality level of the floor to be presented; determining the identifier corresponding to the signal coverage quality grade according to the signal coverage quality grade of the floor to be presented; and the marks corresponding to different signal coverage quality grades are different.

11. The apparatus according to claim 8 or 10, wherein when H is 3, the determining unit is configured to determine the number of MR data satisfying H different preset conditions in the N MR data, respectively, and includes: the determining unit is specifically configured to determine that, of the N MR data, the number of MR data meeting a first preset condition is X, the number of MR data meeting a second preset condition is Y, and the number of MR data meeting a third preset condition is Z;

the determining unit is configured to determine, according to the magnitude relationship between the H numerical values, an identifier corresponding to the signal coverage quality of the floor to be presented, and includes: the determining unit is specifically configured to determine, according to a size relationship among the X, the Y, and the Z, an identifier corresponding to the signal coverage quality of the floor to be presented; wherein X, Y and Z are integers which are respectively greater than or equal to 0 and less than or equal to N, and X + Y + Z is equal to N.

12. The apparatus according to claim 11, wherein if X is not equal to Y and Z, the determining unit is configured to determine an identifier corresponding to the signal coverage quality of the floor to be presented according to a size relationship between X, Y and Z, and includes: the determining unit is specifically configured to, when it is determined that X is equal to N; or, said Y is equal to 0, said X is greater than said Z; or, said Z is equal to 0, said X is greater than said Y; or when the X is larger than the Y + the Z, determining that the identifier corresponding to the signal coverage quality of the floor to be presented is a first identifier corresponding to the first preset condition; and when it is determined that Y is equal to N; or, said X is equal to 0, said Y is greater than said Z; alternatively, said Z is equal to 0, said X is not greater than said Y; or, said X is less than said Y + said Z, said Y is greater than said Z; or when the X is equal to the Y plus the Z and the Y is not less than the Z, determining that the identifier corresponding to the signal coverage quality of the floor to be presented is a second identifier corresponding to the second preset condition; and when said Z is equal to said N; or, X is equal to 0, Y is not greater than Z, or, Y is equal to 0, X is not greater than Z; or, said X is less than said Y + said Z, said Y is not greater than said Z; or when the X is equal to the Y plus the Z and the Y is smaller than the Z, determining that the identifier corresponding to the signal coverage quality of the floor to be presented is a third identifier corresponding to the third preset condition; or,

if the X is equal to the Y and the Z, the determining unit is configured to determine, according to a magnitude relationship between the X, the Y, and the Z, an identifier corresponding to the signal coverage quality of the floor to be presented, including: the determining unit is specifically configured to determine, according to the fact that X is equal to Y and Z, that the signal coverage quality level of the floor to be presented is a second identifier corresponding to the second preset condition.

13. The apparatus of claim 12, wherein the signal coverage quality corresponding to the first identifier is higher than the signal coverage quality corresponding to the second identifier, and wherein the signal coverage quality corresponding to the second identifier is higher than the signal coverage quality corresponding to the third identifier.

14. The apparatus according to any one of claims 8-10, wherein the identifier determined by the determining unit comprises at least one of: color identification, texture identification, color depth identification and texture density identification.