CN108235334A - A kind of adjacent section planning check method and device - Google Patents

A kind of adjacent section planning check method and device Download PDF

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Publication number
CN108235334A
CN108235334A CN201611200130.5A CN201611200130A CN108235334A CN 108235334 A CN108235334 A CN 108235334A CN 201611200130 A CN201611200130 A CN 201611200130A CN 108235334 A CN108235334 A CN 108235334A
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cell
adjacent
main
neighbor
cells
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CN108235334B (en
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刘明娜
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China Mobile Communications Group Co Ltd
China Mobile Group Hunan Co Ltd
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China Mobile Communications Group Co Ltd
China Mobile Group Hunan Co Ltd
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    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04WWIRELESS COMMUNICATION NETWORKS
    • H04W16/00Network planning, e.g. coverage or traffic planning tools; Network deployment, e.g. resource partitioning or cells structures
    • H04W16/18Network planning tools
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04WWIRELESS COMMUNICATION NETWORKS
    • H04W24/00Supervisory, monitoring or testing arrangements
    • H04W24/08Testing, supervising or monitoring using real traffic
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04WWIRELESS COMMUNICATION NETWORKS
    • H04W24/00Supervisory, monitoring or testing arrangements
    • H04W24/10Scheduling measurement reports ; Arrangements for measurement reports

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  • Engineering & Computer Science (AREA)
  • Computer Networks & Wireless Communication (AREA)
  • Signal Processing (AREA)
  • Mobile Radio Communication Systems (AREA)

Abstract

The present invention provides a kind of adjacent section planning check method and device, the method includes:According to the overlapping area coverage between cell pair and switching statistical data, the correlation values between main plot and each adjacent cell are obtained;According to the correlation values between the main plot and each adjacent cell, what the adjacent cell of choosing preset quantity generated the main plot answers matched adjacent zone table;By the existing net of matched adjacent zone table and the main plot of answering of the main plot, matched adjacent zone table matches, obtains in the adjacent cell for answering and existing and be not present in the existing net matched adjacent zone table in the table of matched adjacent zone, generates miss-configured neighboring cells table.The present invention can solve fitting user using perception problems, and can reduce requirement of the scheme to work ginseng accuracy, and can excavate miss-configured neighboring cells before event occurs, and realize " taking precautions against in advance ".

Description

Neighbor cell planning and checking method and device
Technical Field
The invention relates to the technical field of wireless communication, in particular to a method and a device for checking neighbor cell planning.
Background
The radio network planning work for mobile communication is a very important part of the construction of mobile networks. The adjacent cell planning is an important link in the wireless network planning, and whether the adjacent cell planning reasonably and directly affects the network performance.
The existing adjacent cell planning and checking method is mainly divided into two application scenes: planning adjacent areas among systems in an LTE new station system; and checking the adjacent cells between systems in the existing network LTE cell system. The technical scheme of planning the inter-system neighbor cell in the LTE new station system is mainly based on the linear distance between LTE cells, LTE and GSM cells and the normal angle of an azimuth angle, a threshold is set (for example, the distance is less than 1KM, and the normal angle of the azimuth angle is less than 30 degrees), and the threshold is the neighbor cell to be matched; the technical scheme for checking the neighbor cells of the same system of the existing network LTE cell mainly depends on the following steps: a. setting a threshold for linear distance and azimuth normal included angle among LTE cells, LTE and GSM cells, and satisfying the requirement of adding adjacent cells to the threshold and otherwise deleting the adjacent cells; b. neighbor cell handover statistics for assisting in judging the reasonability of the neighbor cells already configured in the current network (for example, deleting the neighbor cells with the handover statistics frequency of 0 or the handover success rate of less than 10%); c. and based on the test problem event and the user complaint, finding the missing neighbor cell.
In the process of implementing the embodiment of the invention, the inventor finds that the existing method mostly directly performs threshold comparison or comprehensively sets weight comparison according to basic working parameters (inter-cell distance and azimuth normal direction included angle information) to complete deletion and addition of the adjacent cell, the requirement on the accuracy of the working parameters is high, and the existing working parameters can not meet the accuracy requirement temporarily. The existing network adjacent cell checking scheme based on the working parameters does not consider the actual overlapping coverage condition of the existing network signals and user distribution, is applied in a complex wireless environment, has limitations and cannot be perceptively attached to users; in the prior art, the missed neighbor cells are found through test problem events and user complaints, the efficiency is low, the cost is high, the 'post remedy' is mostly adopted, and the 'precaution' cannot be realized; in the prior art, after the neighbor cell planning verification result is output, correction such as PCI conflict confusion verification and defective cell elimination is not performed, and the switching performance between output missing neighbor cell pairs cannot be ensured.
Disclosure of Invention
Aiming at the defects of the prior art, the invention provides a method and a device for checking adjacent cell planning, which can solve the problems that the requirement on the accuracy of working parameters is high, the accuracy of an output scheme is limited, and the output of a missing adjacent cell can not be counted in a background in the prior art.
In a first aspect, the present invention provides a method for checking neighbor cell planning, where the method includes:
obtaining correlation values between the main cell and each adjacent cell according to the overlapping coverage area between the cell pairs and the switching statistical data;
selecting a preset number of adjacent cells to generate a neighbor area table to be allocated to the main cell according to the correlation value between the main cell and each adjacent cell;
and matching the adjacent region table to be configured of the main cell with the existing network configured adjacent region table of the main cell, acquiring adjacent cells which exist in the adjacent region table to be configured and do not exist in the existing network configured adjacent region table, and generating a missing configuration adjacent region table.
Optionally, the obtaining a correlation value between the main cell and each neighboring cell according to the overlapping coverage area between the cell pairs and the handover statistical data includes:
when the main cell and the adjacent cell belong to the adjacent cells of the same system of the LTE cell, obtaining a correlation value between the main cell and the adjacent cell according to the overlapping coverage area between the cell pairs and the switching statistical data;
and when the main cell and the adjacent cell belong to the adjacent cells between systems in the LTE new station system, obtaining a correlation value between the main cell and the adjacent cell according to the overlapping coverage area between the cell pairs, the event triggered measurement report MRE, the sample type measurement report MRO and the switching statistical data.
Optionally, the obtaining a correlation value between the primary cell and the neighboring cell according to the overlapping coverage area between the cell pairs, the MRE, the MRO, and the handover statistical data includes:
calculating to obtain a first correlation value between the main cell and each adjacent cell according to the overlapping coverage area between the cell pairs;
calculating to obtain a second correlation value between the main cell and each adjacent cell according to MRE data of each adjacent cell of the main cell;
calculating to obtain a third correlation value between the main cell and each adjacent cell according to the MRO data of the main cell;
counting the successful times of switching between the main cell and each adjacent cell, and calculating to obtain a fourth correlation value between the main cell and each adjacent cell;
and selecting the maximum value of the first correlation value, the second correlation value, the third correlation value and the fourth correlation value as the correlation value between the main cell and each adjacent cell.
Optionally, the calculating, according to the overlapping coverage area between the cell pair, to obtain a first correlation value between the primary cell and each neighboring cell includes:
calculating the coverage radius of the macro cell;
and according to the coverage relation between the main cell and each adjacent cell, calculating by adopting a corresponding preset formula to obtain a first correlation value:
wherein, the coverage relation between the main cell and each adjacent cell includes: macro cells and macro cells with overlapping coverage areas, macro cells and indoor cells with overlapping coverage areas, and indoor cells and macro cells with overlapping coverage areas.
Optionally, the calculating, according to the MRE data of each neighboring cell of the main cell, a second correlation value between the main cell and each neighboring cell includes:
for an A3 measurement event, an A4 measurement event and an A5 measurement event in MRE data of each adjacent cell of the main cell, correlating the measurement event values according to the frequency points and the PCI reported by measurement and the engineering parameter information of the main cell to obtain the measurement event values as MRE value values;
and obtaining an MRE preset range corresponding to the MRE quantity value according to the MRE quantity value corresponding to each adjacent cell, and taking a preset MRE correlation value corresponding to the MRE preset range as a second correlation value between the main cell and each adjacent cell.
Optionally, the calculating, according to the MRO data of the main cell, a third correlation value between the main cell and each neighboring cell includes:
correlating the adjacent cell frequency points and the PCI in the MRO of the main cell with the engineering parameters of each adjacent cell to obtain the MRO quantity value corresponding to each adjacent cell;
and acquiring an MRO preset range corresponding to the MRO quantity value of each adjacent cell, and taking a preset MRO correlation value corresponding to the MRO preset range as a third correlation value between the main cell and each adjacent cell.
Optionally, the counting the number of successful handovers between the primary cell and each neighboring cell, and calculating to obtain a fourth correlation value between the primary cell and each neighboring cell includes:
counting the successful times of switching between the main cell and each adjacent cell;
and obtaining a preset HO range corresponding to the successful times of switching between the main cell and each adjacent cell, and taking a preset HO correlation value corresponding to the preset HO range as a fourth correlation value between the main cell and each adjacent cell.
Optionally, after selecting a preset number of neighboring cells to generate a neighbor cell list to be configured for the main cell according to the correlation value between the main cell and each neighboring cell, the method further includes:
and performing conflict confusion check on the physical cell identification PCIs of the adjacent cells in the main cell and the corresponding adjacent cell list, and performing conflict confusion check on the PCIs between the adjacent cells in the corresponding adjacent cell list.
Optionally, the performing collision confusion checking on the physical cell identifiers PCIs of the primary cell and the neighboring cells in the corresponding neighbor cell list, and performing collision confusion checking on the PCIs between the neighboring cells in the corresponding neighbor cell list includes:
checking the PCI configuration of the adjacent cell in the primary cell and the adjacent cell table to be configured, judging whether the correlation value between the primary cell and the adjacent cell is lower than a preset PCI correlation threshold value when the PCI of the primary cell is the same as the PCI of the adjacent cell, and deleting the adjacent cell from the adjacent cell table to be configured if the correlation value is lower than the preset PCI correlation threshold value;
checking the PCI configuration between any two adjacent cells in the adjacent area table to be configured, respectively judging whether the correlation value between the main cell and the adjacent cell is lower than a preset PCI correlation threshold value when the PCIs of the two adjacent cells are the same, and if so, deleting the corresponding adjacent cell from the adjacent area table to be configured.
Optionally, the method further comprises:
matching the adjacent area table to be allocated of the main cell with the adjacent area table allocated to the current network of the main cell, acquiring adjacent cells which do not exist in the adjacent area table to be allocated and exist in the adjacent area table allocated to the current network, selecting adjacent cells of which the MRO number value is lower than a first preset threshold value, the MRE number value is lower than a second preset threshold value, the switching success frequency is lower than a third preset threshold value, and the distance between the adjacent cells and the main cell is larger than a first preset distance, and generating a redundant adjacent area table;
matching the adjacent region table to be configured of the main cell with the existing network configured adjacent region table of the main cell, acquiring adjacent cells which exist in the adjacent region table to be configured and do not exist in the existing network configured adjacent region table, selecting adjacent cells of which the distance from the main cell is greater than a second preset distance, and generating an over-long missing configuration adjacent region table;
matching the adjacent region table to be allocated of the main cell with the existing network allocated adjacent region table of the main cell, acquiring adjacent cells existing in the adjacent region table to be allocated and existing in the existing network allocated adjacent region table, selecting adjacent cells of which the distance from the main cell is greater than a third preset distance, and generating an excessively far allocated adjacent region table;
and matching the neighbor cell table to be allocated of the main cell with the existing network allocated neighbor cell table of the main cell, acquiring neighbor cells which do not exist in the neighbor cell table to be allocated and exist in the existing network allocated neighbor cell table, selecting neighbor cells of which the correlation value of the overlapping coverage area between the macro station and the macro station is lower than a fourth preset threshold value and the switching success rate is lower than a fifth preset threshold value, and generating a reverse neighbor cell table.
In a second aspect, the present invention provides a neighbor cell planning and checking apparatus, where the apparatus includes:
the correlation calculation unit is used for obtaining correlation values between the main cell and each adjacent cell according to the overlapping coverage area between the cell pairs and the switching statistical data;
a should-be-configured neighbor cell list generating unit, configured to select a preset number of neighbor cells to generate a should-be-configured neighbor cell list of the main cell according to the correlation value between the main cell and each neighbor cell;
and the missed neighbor cell list generating unit is used for matching the neighbor cell list to be configured of the main cell with the existing network configured neighbor cell list of the main cell, acquiring neighbor cells which exist in the neighbor cell list to be configured and do not exist in the existing network configured neighbor cell list, and generating the missed neighbor cell list.
According to the technical scheme, the invention provides a method and a device for checking adjacent cell planning, which are used for obtaining correlation values between a main cell and each adjacent cell according to overlapping coverage areas between cell pairs, switching statistical data and the like; selecting a preset number of adjacent cells to generate a neighbor area table to be allocated to the main cell according to the correlation value between the main cell and each adjacent cell; and matching the adjacent region table to be matched of the main cell with the existing network matched adjacent region table of the main cell to generate a missed adjacent region table. Therefore, the correlation value is determined based on the overlapping coverage area and the switching statistical data, and the adjacent area table to be configured is determined based on the correlation value, so that the problem of use perception of a fit user can be solved, and the requirement of a scheme on the accuracy of the working parameters can be reduced; the invention can excavate the missing adjacent area before the event happens, thus realizing the precaution.
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, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to these drawings without creative efforts.
Fig. 1 is a schematic flowchart of a method for checking a neighboring cell planning according to an embodiment of the present invention;
fig. 2 is a schematic diagram illustrating a macro cell coverage radius calculation according to another embodiment of the present invention;
fig. 3 is a schematic diagram of a method for calculating an overlapping coverage area between macro stations according to another embodiment of the present invention;
FIG. 4 is a schematic diagram of a method for calculating a macro station-cell overlap coverage area correlation according to another embodiment of the present invention;
FIG. 5 is a schematic diagram of a method for calculating a correlation between overlapping coverage areas of a cell and a macro station according to another embodiment of the present invention;
fig. 6 is a schematic flowchart of a method for checking neighboring cell planning according to another embodiment of the present invention;
fig. 7 is a flowchart illustrating a method for checking a neighboring cell planning according to another embodiment of the present invention;
fig. 8 is a schematic structural diagram of an apparatus for checking neighboring cell planning according to an embodiment of the present invention;
fig. 9 is a schematic structural diagram of an apparatus for checking neighboring cell planning according to another embodiment of the present invention;
fig. 10 is a schematic structural diagram of an apparatus for checking neighboring cell planning according to another embodiment of the present invention;
fig. 11 is a block diagram of a neighboring cell planning and checking device according to an embodiment of the present invention.
Detailed Description
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 only a part of the embodiments of the present invention, and not all of the embodiments. 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 schematic flow chart of a method for checking neighboring cell planning in an embodiment of the present invention, where an execution subject of the embodiment is a server, and the method includes the following steps:
s1: and obtaining a correlation value between the main cell and each adjacent cell according to the overlapping coverage area between the cell pairs and the switching statistical data.
Specifically, when the primary cell and the neighboring cell belong to the same-system neighboring cells of the LTE cell, that is, when both the primary cell and the neighboring cell belong to the LTE cell, a correlation value between the primary cell and each neighboring cell is obtained according to an overlapping coverage area between cell pairs and handover statistical data; and when the main cell and the adjacent cell belong to the adjacent cells between systems in the LTE new station system, obtaining correlation values between the main cell and each adjacent cell according to the overlapping coverage area between the cell pairs, the event triggered measurement report MRE, the sample type measurement report MRO and the switching statistical data.
Understandably, the larger the correlation value between the primary cell and the neighboring cell is, the higher the probability that the neighboring cell is the neighboring cell to be configured of the primary cell is. Therefore, the neighbor cell can be evaluated according to the correlation value.
The working parameter algorithm based on the inter-cell overlapping coverage area and the switching statistical data is used for planning the inter-system neighbor cells in the LTE new station system, and meanwhile, the measurement data such as MRE, MRO, GSM MR and the like reported by the actual measurement of the current network of a user are added in the optimization scene of the inter-system neighbor cells of the LTE cell of the current network, so that the problem of user perception of the fit user can be solved, and the requirement of the scheme on the accuracy of the working parameters can be reduced.
S2: and selecting a preset number of adjacent cells to generate a neighbor area table to be matched with the main cell according to the correlation value between the main cell and each adjacent cell.
Specifically, a correlation value COR between the main cell and each adjacent cell is determinediSorting from big to small, and taking NUM in the frontMAXAnd the neighbor cell is contained in the neighbor cell table to be matched. Wherein NUMMAXTo add the maximum number of neighbor cells, i represents the ith neighbor cell, and 0<i is less than or equal to the total number of the adjacent cells.
NUM may be further specifiedMAXJudging the correlation value corresponding to each adjacent cell, if the correlation value CORi<CORTHRThen the cell does not include the list of the corresponding neighbor cell. COR (continuous operating reference)THRThe correlation threshold value of the adjacent cell can be added according to the actual system.
S3: and matching the adjacent region table to be configured of the main cell with the existing network configured adjacent region table of the main cell, acquiring adjacent cells which exist in the adjacent region table to be configured and do not exist in the existing network configured adjacent region table, and generating a missing configuration adjacent region table.
And comparing the adjacent region table to be configured of the main cell with the existing network configured adjacent region table of the main cell, acquiring adjacent cells which exist in the adjacent region table to be configured and do not exist in the existing network configured adjacent region table, and summarizing the adjacent cells to generate a missed adjacent region table.
In this embodiment, correlation values between the main cell and each neighboring cell are obtained according to the overlapping coverage area between the cell pairs, the handover statistical data, and the like; selecting a preset number of adjacent cells to generate a neighbor area table to be allocated to the main cell according to the correlation value between the main cell and each adjacent cell; and matching the adjacent region table to be matched of the main cell with the existing network matched adjacent region table of the main cell to generate a missed adjacent region table. Therefore, the embodiment determines the correlation value based on the overlapping coverage area and the switching statistical data, and determines the adjacent area table to be configured based on the correlation value, so that the problem of use perception of a fit user can be solved, and the requirement of a scheme on the accuracy of the working parameters can be reduced; the invention can excavate the missing adjacent area before the event happens, thus realizing the precaution.
Specifically, in an optional embodiment of the present invention, when the primary cell and the neighboring cell belong to a system neighboring cell of an LTE cell, the step S1 specifically includes the following sub-steps:
s11: calculating to obtain a first correlation value between the main cell and each adjacent cell according to the overlapping coverage area between the cell pairs;
s12: calculating to obtain a second correlation value between the main cell and each adjacent cell according to MRE data of each adjacent cell of the main cell;
s13: calculating to obtain a third correlation value between the main cell and each adjacent cell according to the MRO data of the main cell;
s14: counting the successful times of switching between the main cell and each adjacent cell, and calculating to obtain a fourth correlation value between the main cell and each adjacent cell;
s15: and selecting the maximum value of the first correlation value, the second correlation value, the third correlation value and the fourth correlation value as the correlation value between the main cell and each adjacent cell.
It should be noted that, steps S11 to S14 have no sequence, i.e., no timing requirement.
It should be noted that the steps S11 to S14 are only applicable to the scenario of planning the neighboring cells of the LTE cell in the same system, that is, the primary cell and the neighboring cells are both LTE cells. If the scenario is planned for the inter-system neighboring cell in the LTE new station system, if the primary cell and the neighboring cell are the LTE cell and the GSM cell, respectively, only S11 and S14 are considered, and the larger value of the first correlation value calculated in S11 and the fourth correlation value calculated in S14 is selected as the final correlation value between the primary cell and each neighboring cell, without considering steps S12 to S14.
Specifically, the step S11 specifically includes:
s111: the coverage radius of the macro cell is calculated.
The macro cell may be a primary cell or a neighbor cell.
The method for calculating the coverage radius of the macro cell is shown in fig. 2. Consider the vertical lobe with an upper and lower half-power angle theta-3. The calculation formula of the cell coverage radius R is as follows:
R=H/tan(θ-3) (1)
wherein H is the height difference of the antenna.
S112: and calculating by adopting a corresponding preset formula according to the coverage relation between the main cell and each adjacent cell to obtain a first correlation value.
Wherein, the coverage relation between the main cell and each adjacent cell includes: macro cells and macro cells with overlapping coverage areas, macro cells and indoor cells with overlapping coverage areas, and indoor cells and macro cells with overlapping coverage areas.
1. If the coverage relationship between the main cell and each neighboring cell is: there are macro cells and macro cells that overlap the coverage area.
The coverage area of the macro cell of the current network is α +2 β -degree sector area, wherein the main lobe is α degrees, the side lobe is β degrees, α and β can be further processed according to the actual system valueAnd (4) setting rows. Defining the coverage area of the cell as a sector with weight, and the weight in the range of the main lobe is COR0SMMSide lobe weight of COR1SMMWeight COR0SMMAnd COR1SMMCan be set according to the actual system. Calculating the ratio of the overlapping coverage area of the two sectors to the total area to obtain the correlation between the two cells, wherein the weight of the overlapping part of the main lobe and the main lobe is 2COR0SMMThe weight of the overlapping region of the main lobe and the side lobe is COR0SMM+COR1SMMThe side lobe and the side lobe overlap region weight is COR1SMM
Cell a in fig. 3: the radius R is obtained from the macrocell coverage radius calculation formula (1) in step S111; the coverage area of the main lobe region is SA mainThe coverage area of the side lobe area is SSide A(ii) a And a cell B: the radius r is obtained from the macrocell coverage radius calculation formula (1) in step S111; the coverage area of the main lobe region is SB mainThe coverage area of the side lobe area is SSide B
Then as shown in fig. 3, the area of the main lobe and the main lobe overlapping region is: sA main and B main(ii) a The area of the overlapped area of the main lobe and the side lobe is as follows: sSide A and side B+SA main side and B side(ii) a The area of the overlapped area of the side lobe and the side lobe is as follows: sBeside A and beside B
SMM based on macro site-macro site overlap coverage area correlationCORiThe calculation formula of (2) is as follows:
2. if the coverage relationship between the main cell and each neighboring cell is: there are macro cells and room cells that overlap the coverage area.
Fig. 4 depicts a method of calculating a macro-cell-to-cell coverage area correlation. As shown in fig. 4, 500 meters around the macro cell is screened out by using the indoor sub-cells, and the coverage of the indoor sub-cells is divided into 3 coverage ranges according to the coverage radius (macro cell coverage radius), 2 times of the coverage radius and the main side lobe angleThe interval 1 is a sector region with radius R and main lobe α degrees, and the area correlation of the region is COR0SMRAs shown in FIG. 4, the interval 2 comprises two parts, namely a first part which is a sector with a radius R and a side lobe of β degrees, and a second part which is a sector with a radius between R and 2R and a main lobe of α degrees, wherein the area correlation of the sector is COR1SMRThe interval 3 is a sector area with radius between R and 2R and side lobe β deg. and has COR2 area correlationSMR
SMR based on macro site-to-room overlapping coverage area correlationCORiThe calculation formula of (2) is as follows:
wherein, the station in area 1 indicates that the chamber is located in the section 1, the station in area 2 indicates that the chamber is located in the section 2, and the station in area3 indicates that the chamber is located in the section 3. Understandably, COR0SMR>COR1SMR>COR2SMR
3. If the coverage relationship between the main cell and each neighboring cell is: there are room-divided cells and macrocells with overlapping coverage areas.
Figure 5 illustrates a method for calculating the coverage area correlation of the indoor sub-macro station, as shown in figure 5, macro cells within 500 meters of the periphery of the indoor sub-cell are screened, the coverage of the macro cells is divided into 3 intervals according to the coverage radius (the coverage radius of the macro cell) and 2 times of the coverage radius, and the angle of a main side lobe, wherein the interval 1 is a sector area with the radius R and the main lobe α degrees in the figure, and the area correlation of the sector area is COR0SRMAs shown in FIG. 5, the interval 2 comprises two parts, namely a first part which is a sector with a radius R and a side lobe of β degrees, and a second part which is a sector with a radius between R and 2R and a main lobe of α degrees, wherein the area correlation of the sector is COR1SRMThe interval 3 is a sector area with radius between R and 2R and side lobe β deg. and has COR2 area correlationSRM
SRM (space division-macro station) based on overlapping coverage area correlationCORiThe calculation formula of (2) is as follows:
wherein, the station in area 1 indicates that the macro station is located in the section 1, the station in area 2 indicates that the macro station is located in the section 2, and the station in area3 indicates that the macro station is located in the section 3. Understandably, COR0SRM>COR1SRM>COR2SRM
Specifically, the step S12 specifically includes:
s121: and for the A3 measurement event, the A4 measurement event and the A5 measurement event in the MRE data of each adjacent cell of the main cell, correlating the measurement event value according to the frequency point and the PCI reported by measurement and the engineering parameter information of the main cell to obtain the measurement event value as an MRE value.
S122: and obtaining an MRE preset range corresponding to the MRE quantity value according to the MRE quantity value corresponding to each adjacent cell, and taking a preset MRE correlation value corresponding to the MRE preset range as a second correlation value between the main cell and each adjacent cell.
In this embodiment, one of the measurement events A3, a4, and a5 of MREs in all the neighboring cells of the main cell is selected, and the MRE quantity value obtained by correlating the reported frequency point, PCI, and the working parameter of the main cell is measured by using the MREiDenotes, where i denotes the ith neighbor cell, and 0<i is less than or equal to the total number of the adjacent cells. Further combining all MREsiArranged in descending order of the MRE correlation value MRECORi(i.e., the second correlation value) is calculated as:
wherein TOPN represents the MRE number value MREiThe largest N cells. MRENUM0,MRENUM1,MRENUM2,MRENUM3,MRENUM4,MRENUM5,MRENUM6,MRENUM7For MRE quantity value MREiThe threshold judgment value (i.e. the upper and lower limit values of the MRE preset range) of (a) may be set according to an actual system. COR1MRE,COR2MRE,COR3MRE,COR4MRE,COR5MRE,COR6MRE,COR7MRE,COR8MREThe correlation values of the preset MRE corresponding to different preset MRE preset ranges can be set according to an actual system.
Specifically, the step S13 specifically includes:
s131: and correlating the adjacent cell frequency points and the PCI in the MRO of the main cell with the engineering parameters of each adjacent cell to obtain the MRO quantity value corresponding to each adjacent cell.
S132: and acquiring an MRO preset range corresponding to the MRO quantity value of each adjacent cell, and taking a preset MRO correlation value corresponding to the MRO preset range as a third correlation value between the main cell and each adjacent cell.
In this embodiment, the MRO quantity value of the neighbor cell obtained by correlating the frequency point, the pci, and the power parameter for each neighbor cell in the MR data in the MRO of the main cell is used as the MROiDenotes, where i denotes the ith neighbor cell, and 0<i is less than or equal to the total number of the adjacent cells. Further combining all MROsiArranged in descending order of the MRO correlation value MROCORi(i.e., the third correlation value) is calculated as:
wherein TOPN represents the MRO quantity value MROiThe largest N cells. MRONUM0,MRONUM1,MRONUM2,MRONUM3,MRONUM4,MRONUM5,MRONUM6,MRONUM7Is MRO quantity value MROiDoor (2)The limit judgment value (i.e., the upper and lower limit values of the MRO preset range) may be set according to an actual system. COR1MRO,COR2MRO,COR3MRO,COR4MRO,COR5MRO,COR6MRO,COR7MRO,COR8MROThe preset MRO correlation values corresponding to different preset MRO preset ranges can be set according to an actual system.
Specifically, the step S14 specifically includes:
s141: and counting the successful times of switching between the main cell and each adjacent cell.
S142: and obtaining a preset HO range corresponding to the successful times of switching between the main cell and each adjacent cell, and taking a preset HO correlation value corresponding to the preset HO range as a fourth correlation value between the main cell and each adjacent cell.
In this embodiment, the successful handover times HO of all neighboring cell pairs in the cell are countediWherein i represents the ith neighbor cell, and 0<i is less than or equal to the total number of the adjacent cells. All HO will beiArranged in descending order of magnitude, HO correlation valuesCORiThe calculation formula is as follows:
wherein TOPN represents the HO number valueiThe largest N cells. HONUM0,HONUM1,HONUM2,HONUM3,HONUM4,HONUM5,HONUM6,HONUM7Is an HO number valueiThe threshold judgment value (i.e. the upper and lower limit values of the HO preset range) of (a) can be set according to an actual system. COR1HO,COR2HO,COR3HO,COR4HO,COR5HO,COR6HO,COR7HO,COR8HOThe preset HO correlation values corresponding to different preset HO preset ranges can be set according to an actual system.
Further, step S15 specifically includes:
the calculation formula for calculating the correlation value between the main cell and each adjacent cell is as follows:
CORi=max(SCORi,MRECORi,MROCORi,HOCORi) (8)
in an alternative embodiment of the present invention, as shown in fig. 6, after the step S2, the method further includes:
s2': and performing conflict confusion check on the physical cell identification PCIs of the adjacent cells in the main cell and the corresponding adjacent cell list, and performing conflict confusion check on the PCIs between the adjacent cells in the corresponding adjacent cell list.
Specifically, the step S2' includes:
s21': checking the PCI configuration of the adjacent cell in the main cell and the adjacent cell table to be configured, judging whether the correlation value between the main cell and the adjacent cell is lower than a preset PCI correlation threshold value when the PCI of the main cell is the same as the PCI of the adjacent cell, and deleting the adjacent cell from the adjacent cell table to be configured if the correlation value is lower than the preset PCI correlation threshold value.
Specifically, whether the correlation value between the primary cell and the neighboring cell is lower than a preset PCI correlation threshold value is judged, if yes, the neighboring cell is deleted from the to-be-allocated neighbor list, and otherwise, a remark is marked.
S22': checking the PCI configuration between any two adjacent cells in the adjacent area table to be configured, respectively judging whether the correlation value between the main cell and the adjacent cell is lower than a preset PCI correlation threshold value when the PCIs of the two adjacent cells are the same, and if so, deleting the corresponding adjacent cell from the adjacent area table to be configured.
Specifically, whether the correlation value between the primary cell and the adjacent cell is lower than a preset PCI correlation threshold value is judged, if yes, the corresponding adjacent cell is deleted from the neighbor area table to be allocated, and otherwise, a remark is marked. The PCI correlation threshold is a threshold for PCI correlation detection, and may be set according to an actual system.
Therefore, secondary correction of the neighbor cell planning and checking result is achieved in the embodiment, and therefore the planning and checking accuracy is greatly improved. In the prior art, PCI conflict confusion check is not performed after the neighbor cell planning check result is output, and the switching performance between output missing neighbor cell pairs cannot be ensured.
In an alternative embodiment of the present invention, as shown in fig. 7, the method further comprises the steps of:
s4: and checking redundant adjacent cells, over-distant adjacent cells and back adjacent cells.
Specifically, the step S5 may specifically include:
s41: and matching the adjacent region table to be allocated of the main cell with the adjacent region table allocated to the current network of the main cell, acquiring adjacent cells which do not exist in the adjacent region table to be allocated and exist in the adjacent region table allocated to the current network, selecting the adjacent cells of which the MRO number value is lower than a first preset threshold value, the MRE number value is lower than a second preset threshold value, the switching success frequency is lower than a third preset threshold value, and the distance between the adjacent cells and the main cell is greater than a first preset distance, and generating a redundant adjacent region table.
Specifically, the neighbor table to be allocated to the primary cell a is matched with the neighbor table allocated to the current network of the cell a, and the MRO table that is not present in the neighbor table to be allocated but present in the neighbor table allocated to the current network is obtainedi<MRORDUND&&HOi<HORDUND&&MREi<MRERDUND&&Distance between main adjacent cells>DISTTHR0And summarizing to generate a redundant neighbor area table. Wherein MRORDUND,HORDUND,MRERDUNDCounting threshold for sample, DISTTHR0The redundant adjacent cell distance threshold value can be set according to an actual system.
S42: and matching the adjacent region table to be configured of the main cell with the existing network configured adjacent region table of the main cell, acquiring adjacent cells which exist in the adjacent region table to be configured and do not exist in the existing network configured adjacent region table, selecting the adjacent cell of which the distance from the main cell is greater than a second preset distance, and generating an over-long missing configuration adjacent region table.
Specifically, the neighbor table to be allocated to the primary cell a is matched with the neighbor table allocated to the current network of the cell a, and the distance between the primary neighbor cell and the primary neighbor cell existing in the neighbor table to be allocated but not existing in the neighbor table allocated to the current network is obtained>DISTTHR1And summarizing and generating the far missing-configuration neighbor cell list. Wherein DISTTHR1The threshold value of the distance between the adjacent regions is omitted for too far, and the threshold value can be set according to an actual system.
S43: and matching the adjacent region table to be allocated of the main cell with the existing network allocated adjacent region table of the main cell, acquiring adjacent cells existing in the adjacent region table to be allocated and the existing network allocated adjacent region table, selecting adjacent cells of which the distance from the main cell is greater than a third preset distance, and generating an excessively far allocated adjacent region table.
Specifically, the neighbor table to be allocated to the primary cell a is matched with the neighbor table allocated to the current network of the cell a, and the distances between the primary and the neighboring cells, which exist in the neighbor table to be allocated and also exist in the neighbor table allocated to the current network, are obtained>DISTTHR2The too far allocated neighbor list is generated by summarizing the cell pairs. Wherein DISTTHR2The threshold value of the distance of the neighboring cell allocated too far can be set according to the actual system.
S44: and matching the neighbor cell table to be allocated of the main cell with the existing network allocated neighbor cell table of the main cell, acquiring neighbor cells which do not exist in the neighbor cell table to be allocated and exist in the existing network allocated neighbor cell table, selecting neighbor cells of which the correlation value of the overlapping coverage area between the macro station and the macro station is lower than a fourth preset threshold value and the switching success rate is lower than a fifth preset threshold value, and generating a reverse neighbor cell table.
Specifically, the neighbor table to be allocated to the main cell a is matched with the neighbor table already allocated to the current network of the cell a, and the neighbor table to be allocated is obtained, wherein the neighbor table to be allocated does not exist but exists in the current network allocated neighbor table, and the SMM existsCORi<SMMCORTHR&&Handover success rate<HOTHRThe cell pairs of (2) are summarized to generate a back-to-neighbor list. SMMCORTHRIf the ratio threshold value is the overlapping coverage area ratio between the macro station and the macro station, the main cell A and the neighbor cells in the back neighbor cell list are the macro cells; HOTHRThe switching success rate threshold value can be set according to an actual system.
Therefore, the embodiment realizes the check of the abnormal adjacent cells such as the redundancy, the too far, the back and the like of the current network through the combination of various thresholds and conditions so as to eliminate the adjacent cells with various problems and ensure the switching function between the output missed-matching adjacent cell pairs.
Fig. 8 is a schematic structural diagram of a neighboring cell planning and checking apparatus in an embodiment of the present invention, and as shown in fig. 8, the apparatus includes: a correlation calculation unit 801, an on-demand neighbor table generation unit 802, and a missed neighbor table generation unit 803. Wherein:
the correlation calculation unit 801 is configured to obtain correlation values between the main cell and each neighboring cell according to the overlapping coverage area between the cell pairs and the handover statistical data; the to-be-configured neighbor cell list generating unit 802 is configured to select a preset number of neighbor cells to generate an to-be-configured neighbor cell list of the main cell according to the correlation values between the main cell and each neighbor cell; the missed neighbor cell table generating unit 803 is configured to match the neighbor cell table to be configured of the primary cell with the existing network configured neighbor cell table of the primary cell, acquire neighbor cells that exist in the neighbor cell table to be configured and do not exist in the existing network configured neighbor cell table, and generate a missed neighbor cell table.
In this embodiment, the correlation calculation unit 801 obtains correlation values between the main cell and each neighboring cell according to the overlapping coverage area between the cell pairs, the handover statistical data, and the like; the to-be-configured neighbor cell list generating unit 802 selects a preset number of neighbor cells to generate an to-be-configured neighbor cell list of the main cell according to the correlation values between the main cell and each neighbor cell; the missed neighbor cell table generating unit 803 matches the neighbor cell table to be configured of the primary cell with the neighbor cell table already configured in the current network of the primary cell to generate a missed neighbor cell table. Therefore, the embodiment determines the correlation value based on the overlapping coverage area and the switching statistical data, and determines the adjacent area table to be configured based on the correlation value, so that the problem of use perception of a fit user can be solved, and the requirement of a scheme on the accuracy of the working parameters can be reduced; the invention can excavate the missing adjacent area before the event happens, thus realizing the precaution.
Specifically, the correlation calculation unit 801 is specifically configured to:
when the main cell and the adjacent cell belong to the adjacent cells of the same system of the LTE cell, obtaining a correlation value between the main cell and the adjacent cell according to the overlapping coverage area between the cell pairs and the switching statistical data;
and when the main cell and the adjacent cell belong to the adjacent cells between systems in the LTE new station system, obtaining a correlation value between the main cell and the adjacent cell according to the overlapping coverage area between the cell pairs, the event triggered measurement report MRE, the sample type measurement report MRO and the switching statistical data.
In an optional embodiment of the present invention, the correlation calculation unit 801 further includes: a first correlation calculation module, a second correlation calculation module, a third correlation calculation module, a fourth correlation calculation module, and a correlation calculation module, wherein:
the first correlation calculation module is used for calculating to obtain a first correlation value between the main cell and each adjacent cell according to the overlapping coverage area between the cell pairs;
the second correlation calculation module is used for calculating a second correlation value between the main cell and each adjacent cell according to MRE data of each adjacent cell of the main cell;
the third correlation calculation module is used for calculating a third correlation value between the main cell and each adjacent cell according to the MRO data of the main cell;
the fourth correlation calculation module is used for counting the switching success times between the main cell and each adjacent cell and calculating to obtain a fourth correlation value between the main cell and each adjacent cell;
the correlation calculation module is configured to select a largest value of the first correlation value, the second correlation value, the third correlation value, and the fourth correlation value as a correlation value between the primary cell and each neighboring cell.
Specifically, the first correlation calculation module is specifically configured to:
calculating the coverage radius of the macro cell;
and according to the coverage relation between the main cell and each adjacent cell, calculating by adopting a corresponding preset formula to obtain a first correlation value:
wherein, the coverage relation between the main cell and each adjacent cell includes: macro cells and macro cells with overlapping coverage areas, macro cells and indoor cells with overlapping coverage areas, and indoor cells and macro cells with overlapping coverage areas.
Specifically, the second correlation calculation module is specifically configured to:
for an A3 measurement event, an A4 measurement event and an A5 measurement event in MRE data of each adjacent cell of the main cell, correlating the measurement event values according to the frequency points and the PCI reported by measurement and the engineering parameter information of the main cell to obtain the measurement event values as MRE value values;
and obtaining an MRE preset range corresponding to the MRE quantity value according to the MRE quantity value corresponding to each adjacent cell, and taking a preset MRE correlation value corresponding to the MRE preset range as a second correlation value between the main cell and each adjacent cell.
Specifically, the third correlation calculation module is specifically configured to:
correlating the adjacent cell frequency points and the PCI in the MRO of the main cell with the engineering parameters of each adjacent cell to obtain the MRO quantity value corresponding to each adjacent cell;
and acquiring an MRO preset range corresponding to the MRO quantity value of each adjacent cell, and taking a preset MRO correlation value corresponding to the MRO preset range as a third correlation value between the main cell and each adjacent cell.
Specifically, the fourth correlation calculation module is specifically configured to:
counting the successful times of switching between the main cell and each adjacent cell;
and obtaining a preset HO range corresponding to the successful times of switching between the main cell and each adjacent cell, and taking a preset HO correlation value corresponding to the preset HO range as a fourth correlation value between the main cell and each adjacent cell.
In an alternative embodiment of the present invention, as shown in fig. 9, the apparatus further comprises: a PCI conflict checking unit 804, configured to:
and performing conflict confusion check on the physical cell identification PCIs of the adjacent cells in the main cell and the corresponding adjacent cell list, and performing conflict confusion check on the PCIs between the adjacent cells in the corresponding adjacent cell list.
Specifically, the PCI collision checking unit 804 is specifically configured to:
checking the PCI configuration of the adjacent cell in the primary cell and the adjacent cell table to be configured, judging whether the correlation value between the primary cell and the adjacent cell is lower than a preset PCI correlation threshold value when the PCI of the primary cell is the same as the PCI of the adjacent cell, and deleting the adjacent cell from the adjacent cell table to be configured if the correlation value is lower than the preset PCI correlation threshold value;
checking the PCI configuration between any two adjacent cells in the adjacent area table to be configured, respectively judging whether the correlation value between the main cell and the adjacent cell is lower than a preset PCI correlation threshold value when the PCIs of the two adjacent cells are the same, and if so, deleting the corresponding adjacent cell from the adjacent area table to be configured.
In an alternative embodiment of the present invention, as shown in fig. 10, the apparatus further comprises: the abnormal neighboring cell checking unit 805 is specifically configured to:
matching the adjacent area table to be allocated of the main cell with the adjacent area table allocated to the current network of the main cell, acquiring adjacent cells which do not exist in the adjacent area table to be allocated and exist in the adjacent area table allocated to the current network, selecting adjacent cells of which the MRO number value is lower than a first preset threshold value, the MRE number value is lower than a second preset threshold value, the switching success frequency is lower than a third preset threshold value, and the distance between the adjacent cells and the main cell is larger than a first preset distance, and generating a redundant adjacent area table;
matching the adjacent region table to be configured of the main cell with the existing network configured adjacent region table of the main cell, acquiring adjacent cells which exist in the adjacent region table to be configured and do not exist in the existing network configured adjacent region table, selecting adjacent cells of which the distance from the main cell is greater than a second preset distance, and generating an over-long missing configuration adjacent region table;
matching the adjacent region table to be allocated of the main cell with the existing network allocated adjacent region table of the main cell, acquiring adjacent cells existing in the adjacent region table to be allocated and existing in the existing network allocated adjacent region table, selecting adjacent cells of which the distance from the main cell is greater than a third preset distance, and generating an excessively far allocated adjacent region table;
and matching the neighbor cell table to be allocated of the main cell with the existing network allocated neighbor cell table of the main cell, acquiring neighbor cells which do not exist in the neighbor cell table to be allocated and exist in the existing network allocated neighbor cell table, selecting neighbor cells of which the correlation value of the overlapping coverage area between the macro station and the macro station is lower than a fourth preset threshold value and the switching success rate is lower than a fifth preset threshold value, and generating a reverse neighbor cell table.
For the device embodiment, since it is basically similar to the method embodiment, the description is simple, and for the relevant points, refer to the partial description of the method embodiment.
Fig. 11 is a block diagram of a neighboring cell planning and checking device in an embodiment of the present invention.
Referring to fig. 11, the neighbor cell optimization device includes: a processor (processor)1101, a memory (memory)1102, a communication Interface (Communications Interface)1103, and a communication bus 1104; wherein,
the processor 1101, the memory 1102 and the communication interface 1103 complete mutual communication through the communication bus 1104;
the communication interface 1103 is used for information transmission between the neighboring cell planning checking device and the user equipment UE;
the processor 1101 is configured to call the program instructions in the memory 1102 to perform the methods provided by the above-mentioned method embodiments, for example, including: obtaining correlation values between the main cell and each adjacent cell according to the overlapping coverage area between the cell pairs and the switching statistical data; selecting a preset number of adjacent cells to generate a neighbor area table to be allocated to the main cell according to the correlation value between the main cell and each adjacent cell; and matching the adjacent region table to be configured of the main cell with the existing network configured adjacent region table of the main cell, acquiring adjacent cells which exist in the adjacent region table to be configured and do not exist in the existing network configured adjacent region table, and generating a missing configuration adjacent region table.
An embodiment of the present invention discloses a computer program product, the computer program product comprising a computer program stored on a non-transitory computer-readable storage medium, the computer program comprising program instructions, which when executed by a computer, enable the computer to perform the methods provided by the above-mentioned method embodiments, for example, including: obtaining correlation values between a main cell and each adjacent cell according to the overlapping coverage area between the cell pairs and switching statistical data; selecting a preset number of adjacent cells to generate a neighbor area table to be allocated to the main cell according to the correlation value between the main cell and each adjacent cell; and matching the adjacent region table to be configured of the main cell with the existing network configured adjacent region table of the main cell, acquiring adjacent cells which exist in the adjacent region table to be configured and do not exist in the existing network configured adjacent region table, and generating a missing configuration adjacent region table.
An embodiment of the present invention provides a non-transitory computer-readable storage medium storing computer instructions that cause a computer to perform a method provided by the above method embodiments, for example, including: obtaining correlation values between the main cell and each adjacent cell according to the overlapping coverage area between the cell pairs and the switching statistical data; selecting a preset number of adjacent cells to generate a neighbor area table to be allocated to the main cell according to the correlation value between the main cell and each adjacent cell; and matching the adjacent region table to be configured of the main cell with the existing network configured adjacent region table of the main cell, acquiring adjacent cells which exist in the adjacent region table to be configured and do not exist in the existing network configured adjacent region table, and generating a missing configuration adjacent region table.
Those of ordinary skill in the art will understand that: all or part of the steps for implementing the method embodiments may be implemented by hardware related to program instructions, and the program may be stored in a computer readable storage medium, and when executed, the program performs the steps including the method embodiments; and the aforementioned storage medium includes: various media that can store program codes, such as ROM, RAM, magnetic or optical disks.
The above-described embodiments of the test equipment and the like of the display device are merely illustrative, wherein the units described as separate parts may or may not be physically separate, and the parts displayed as units may or may not be physical units, may be located in one place, or may be distributed on a plurality of network units. Some or all of the modules may be selected according to actual needs to achieve the purpose of the solution of the present embodiment. One of ordinary skill in the art can understand and implement it without inventive effort.
Through the above description of the embodiments, those skilled in the art will clearly understand that each embodiment can be implemented by software plus a necessary general hardware platform, and certainly can also be implemented by hardware. With this understanding in mind, the above-described technical solutions may be embodied in the form of a software product, which can be stored in a computer-readable storage medium such as ROM/RAM, magnetic disk, optical disk, etc., and includes instructions for causing a computer device (which may be a personal computer, a server, or a network device, etc.) to execute the methods described in the embodiments or some parts of the embodiments.
It is further noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus. Without further limitation, an element defined by the phrase "comprising an … …" does not exclude the presence of other identical elements in a process, method, article, or apparatus that comprises the element.
The above examples are only intended to illustrate the technical solution of the present invention, but not to limit it; although the present invention has been described in detail with reference to the foregoing embodiments, it will be understood by those of ordinary skill in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some technical features may be equivalently replaced; and such modifications or substitutions do not depart from the spirit and scope of the corresponding technical solutions of the embodiments of the present invention.

Claims (10)

1. A neighbor cell planning checking method is characterized by comprising the following steps:
obtaining correlation values between the main cell and each adjacent cell according to the overlapping coverage area between the cell pairs and the switching statistical data;
selecting a preset number of adjacent cells to generate a neighbor area table to be allocated to the main cell according to the correlation value between the main cell and each adjacent cell;
and matching the adjacent region table to be configured of the main cell with the existing network configured adjacent region table of the main cell, acquiring adjacent cells which exist in the adjacent region table to be configured and do not exist in the existing network configured adjacent region table, and generating a missing configuration adjacent region table.
2. The method of claim 1, wherein obtaining correlation values between the primary cell and each neighboring cell according to the overlapping coverage area between the cell pairs and the handover statistical data comprises:
when the main cell and the adjacent cell belong to the adjacent cells of the same system of the LTE cell, obtaining a correlation value between the main cell and the adjacent cell according to the overlapping coverage area between the cell pairs and the switching statistical data;
and when the main cell and the adjacent cell belong to the adjacent cells between systems in the LTE new station system, obtaining a correlation value between the main cell and the adjacent cell according to the overlapping coverage area between the cell pairs, the event triggered measurement report MRE, the sample type measurement report MRO and the switching statistical data.
3. The method of claim 2, wherein obtaining the correlation value between the primary cell and the neighboring cell according to the overlapping coverage area between the cell pair, the MRE, the MRO, and the handover statistics comprises:
calculating to obtain a first correlation value between the main cell and each adjacent cell according to the overlapping coverage area between the cell pairs;
calculating to obtain a second correlation value between the main cell and each adjacent cell according to MRE data of each adjacent cell of the main cell;
calculating to obtain a third correlation value between the main cell and each adjacent cell according to the MRO data of the main cell;
counting the successful times of switching between the main cell and each adjacent cell, and calculating to obtain a fourth correlation value between the main cell and each adjacent cell;
and selecting the maximum value of the first correlation value, the second correlation value, the third correlation value and the fourth correlation value as the correlation value between the main cell and each adjacent cell.
4. The method according to claim 3, wherein the calculating a first correlation value between the primary cell and each neighboring cell according to the overlapping coverage area between the cell pair comprises:
calculating the coverage radius of the macro cell;
and according to the coverage relation between the main cell and each adjacent cell, calculating by adopting a corresponding preset formula to obtain a first correlation value:
wherein, the coverage relation between the main cell and each adjacent cell includes: macro cells and macro cells with overlapping coverage areas, macro cells and indoor cells with overlapping coverage areas, and indoor cells and macro cells with overlapping coverage areas.
5. The method according to claim 3, wherein the calculating a second correlation value between the main cell and each neighboring cell according to the MRE data of each neighboring cell of the main cell includes:
for an A3 measurement event, an A4 measurement event and an A5 measurement event in MRE data of each adjacent cell of the main cell, correlating the measurement event values according to the frequency points and the PCI reported by measurement and the engineering parameter information of the main cell to obtain the measurement event values as MRE value values;
obtaining an MRE preset range corresponding to the MRE quantity value according to the MRE quantity value corresponding to each adjacent cell, and taking a preset MRE correlation value corresponding to the MRE preset range as a second correlation value between the main cell and each adjacent cell;
the calculating to obtain a third correlation value between the main cell and each neighboring cell according to the MRO data of the main cell includes:
correlating the adjacent cell frequency points and the PCI in the MRO of the main cell with the engineering parameters of each adjacent cell to obtain the MRO quantity value corresponding to each adjacent cell;
and acquiring an MRO preset range corresponding to the MRO quantity value of each adjacent cell, and taking a preset MRO correlation value corresponding to the MRO preset range as a third correlation value between the main cell and each adjacent cell.
6. The method according to claim 3, wherein the counting the number of times of successful handover between the primary cell and each neighboring cell, and calculating a fourth correlation value between the primary cell and each neighboring cell comprises:
counting the successful times of switching between the main cell and each adjacent cell;
and obtaining a preset HO range corresponding to the successful times of switching between the main cell and each adjacent cell, and taking a preset HO correlation value corresponding to the preset HO range as a fourth correlation value between the main cell and each adjacent cell.
7. The method of claim 1, wherein after the selecting a preset number of neighbor cells to generate the neighbor cell list to be configured for the primary cell according to the correlation value between the primary cell and each neighbor cell, the method further comprises:
and performing conflict confusion check on the physical cell identification PCIs of the adjacent cells in the main cell and the corresponding adjacent cell list, and performing conflict confusion check on the PCIs between the adjacent cells in the corresponding adjacent cell list.
8. The method according to claim 7, wherein the performing collision confusion checking on the physical cell identities PCIs of the primary cell and the neighbor cells in the neighbor list to be allocated and performing collision confusion checking on the PCIs between the neighbor cells in the neighbor list to be allocated comprises:
checking the PCI configuration of the adjacent cell in the primary cell and the adjacent cell table to be configured, judging whether the correlation value between the primary cell and the adjacent cell is lower than a preset PCI correlation threshold value when the PCI of the primary cell is the same as the PCI of the adjacent cell, and deleting the adjacent cell from the adjacent cell table to be configured if the correlation value is lower than the preset PCI correlation threshold value;
checking the PCI configuration between any two adjacent cells in the adjacent area table to be configured, respectively judging whether the correlation value between the main cell and the adjacent cell is lower than a preset PCI correlation threshold value when the PCIs of the two adjacent cells are the same, and if so, deleting the corresponding adjacent cell from the adjacent area table to be configured.
9. The method according to any one of claims 2 to 8, further comprising:
matching the adjacent area table to be allocated of the main cell with the adjacent area table allocated to the current network of the main cell, acquiring adjacent cells which do not exist in the adjacent area table to be allocated and exist in the adjacent area table allocated to the current network, selecting adjacent cells of which the MRO number value is lower than a first preset threshold value, the MRE number value is lower than a second preset threshold value, the switching success frequency is lower than a third preset threshold value, and the distance between the adjacent cells and the main cell is larger than a first preset distance, and generating a redundant adjacent area table;
matching the adjacent region table to be configured of the main cell with the existing network configured adjacent region table of the main cell, acquiring adjacent cells which exist in the adjacent region table to be configured and do not exist in the existing network configured adjacent region table, selecting adjacent cells of which the distance from the main cell is greater than a second preset distance, and generating an over-long missing configuration adjacent region table;
matching the adjacent region table to be allocated of the main cell with the existing network allocated adjacent region table of the main cell, acquiring adjacent cells existing in the adjacent region table to be allocated and existing in the existing network allocated adjacent region table, selecting adjacent cells of which the distance from the main cell is greater than a third preset distance, and generating an excessively far allocated adjacent region table;
and matching the neighbor cell table to be allocated of the main cell with the existing network allocated neighbor cell table of the main cell, acquiring neighbor cells which do not exist in the neighbor cell table to be allocated and exist in the existing network allocated neighbor cell table, selecting neighbor cells of which the correlation value of the overlapping coverage area between the macro station and the macro station is lower than a fourth preset threshold value and the switching success rate is lower than a fifth preset threshold value, and generating a reverse neighbor cell table.
10. An apparatus for neighbor cell planning verification, the apparatus comprising:
the correlation calculation unit is used for obtaining correlation values between the main cell and each adjacent cell according to the overlapping coverage area between the cell pairs and the switching statistical data;
a should-be-configured neighbor cell list generating unit, configured to select a preset number of neighbor cells to generate a should-be-configured neighbor cell list of the main cell according to the correlation value between the main cell and each neighbor cell;
and the missed neighbor cell list generating unit is used for matching the neighbor cell list to be configured of the main cell with the existing network configured neighbor cell list of the main cell, acquiring neighbor cells which exist in the neighbor cell list to be configured and do not exist in the existing network configured neighbor cell list, and generating the missed neighbor cell list.
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