CN113747477A - Method, device and processor for realizing verification processing aiming at co-constructed 5G network base station and computer readable storage medium thereof - Google Patents

Method, device and processor for realizing verification processing aiming at co-constructed 5G network base station and computer readable storage medium thereof Download PDF

Info

Publication number
CN113747477A
CN113747477A CN202111216258.1A CN202111216258A CN113747477A CN 113747477 A CN113747477 A CN 113747477A CN 202111216258 A CN202111216258 A CN 202111216258A CN 113747477 A CN113747477 A CN 113747477A
Authority
CN
China
Prior art keywords
base station
mhz
base stations
frequency band
matching
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Granted
Application number
CN202111216258.1A
Other languages
Chinese (zh)
Other versions
CN113747477B (en
Inventor
叶干云
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Shanghai TransCom Instruments Co Ltd
Original Assignee
Shanghai TransCom Instruments Co Ltd
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Shanghai TransCom Instruments Co Ltd filed Critical Shanghai TransCom Instruments Co Ltd
Priority to CN202111216258.1A priority Critical patent/CN113747477B/en
Publication of CN113747477A publication Critical patent/CN113747477A/en
Application granted granted Critical
Publication of CN113747477B publication Critical patent/CN113747477B/en
Active legal-status Critical Current
Anticipated expiration legal-status Critical

Links

Images

Classifications

    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04WWIRELESS COMMUNICATION NETWORKS
    • H04W24/00Supervisory, monitoring or testing arrangements
    • H04W24/02Arrangements for optimising operational condition
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04WWIRELESS COMMUNICATION NETWORKS
    • H04W24/00Supervisory, monitoring or testing arrangements
    • H04W24/08Testing, supervising or monitoring using real traffic

Landscapes

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

Abstract

The invention relates to a method for realizing verification processing aiming at a co-constructed 5G network base station, which comprises the following steps: acquiring the construction condition of a 5G base station, calculating and counting the cell registration rate, and analyzing the condition of a legal base station; acquiring drive test data, and adjusting a cell registration rate calculation mode according to actually measured base station data; optimizing the calculation mode of the cell registration rate according to the characteristics of the actually measured base station data and the registration station data; the number of unregistered 5G base stations is reduced. By adopting the method, the device, the processor and the computer readable storage medium for realizing the verification processing aiming at the co-constructed 5G network base station, the problem of low cell registration rate is caused because the total number of the legal 5G base stations which are actually put into operation by an operator is larger than the total number of the 5G base stations registered by the station library in the registration station database of the existing radio management department. The technical scheme reduces the number of illegal base stations extracted by a radio management department in the base station information verification, thereby reducing the workload of manually verifying the illegal base stations.

Description

Method, device and processor for realizing verification processing aiming at co-constructed 5G network base station and computer readable storage medium thereof
Technical Field
The invention relates to the field of 5G base stations, in particular to the field of 5G shared base station checking, and specifically relates to a method, a device, a processor and a computer readable storage medium for realizing checking processing for a co-constructed 5G network base station.
Background
In order to realize 5G network coverage quickly, form 5G service capability quickly and enhance market competitiveness of the 5G network and service, China Unicom and China telecom jointly create a first global 5G co-construction shared network. Through co-construction and sharing, the coverage doubling, the speed doubling and the service excellence are realized, and the client can enjoy the 5G network service with larger bandwidth, higher speed and wider coverage. At present, both parties open a 5G co-construction shared base station in 24 provinces and cities in China.
According to the cooperation agreement, China Unicom and China telecom cooperate with each other to build a 5G access network nationwide, and two parties divide areas and build partitions and are respectively responsible for the related work of 5G network construction in a specified area, namely who builds, invests, maintains and bears the network operation cost.
Therefore, for a 5G shared base station, the constructor configures a CGI (base station cell identity) of the opposite operator code in addition to a CGI of the own operator code. However, when the constructor imports the 5G shared base station information into the registration station database of the radio management section, only the constructor's own 5G base station information is provided.
This results in the sharer having legitimate physical base stations approved by the radio regulatory authority for the 5G shared base station and being monitored by the radio monitoring equipment but not matching the radio regulatory authority's registered station library data. If the radio management department wants to check the illegal base station (the actually used base station which cannot be matched with the registered station base), the checking workload of the radio management department is increased by the part of the legal 5G shared base station, so that a base station checking method comprising a connected telecommunication co-building 5G network is needed.
Disclosure of Invention
The invention aims to overcome the defects of the prior art and provides a method, a device, a processor and a computer readable storage medium thereof for realizing the checking treatment of the co-constructed 5G network base station, which have the advantages of high accuracy, simple and convenient operation and wide application range.
In order to achieve the above object, the method, the apparatus, the processor and the computer readable storage medium for implementing the checking process for the co-established 5G network base station of the present invention are as follows:
the method for realizing the checking treatment aiming at the co-constructed 5G network base station is mainly characterized by comprising the following steps:
(1) acquiring the construction condition of a 5G base station, calculating and counting the cell registration rate, and analyzing the condition of a legal base station;
(2) acquiring drive test data, and adjusting a cell registration rate calculation mode according to actually measured base station data;
(3) optimizing the calculation mode of the cell registration rate according to the characteristics of the actually measured base station data and the registration station data, and improving the cell registration rate;
(4) the number of unregistered 5G base stations is reduced, and the calculation mode of illegal base stations is optimized.
Preferably, the calculating the cell registration rate in step (1) includes:
the cell registration rate is calculated according to the following formula:
the cell registration rate (measured base station number on the CGI match with the registered base station ÷ measured base station total number) × 100%.
Preferably, the cell registration rate in step (1) further includes a cell registration rate of the 5G base station, specifically:
calculating the cell registration rate of the 5G base station according to the following formula:
Figure BDA0003310749750000021
wherein R is cell registration rate, CM2.5 matchingThe number of base stations and CT (computed tomography) matched with CGI (common gateway interface) of the 5G base station and the registered 5G base station are actually measured for the 2515 MHz-2675 MHz frequency band of the first base station construction party3.4 matchingThe number of base stations, CUs, on CGI (common gateway interface) matching between the actually measured 5G base station and the registered 5G base station for the 3400 MHz-3500 MHz frequency band of the second base station construction party3.4 matchingThe number of base stations on CGI (common gateway interface) matching between the actually measured 5G base station and the registered 5G base station for the 3400 MHz-3500 MHz frequency band of the third base station construction party, CT (computed tomography)3.5 matchingActually measured 5G base station for 3500 MHz-3600 MHz frequency band of second base station construction partyNumber of base stations, CU, matched to CGI of a registered 5G base station3.5 matchingActually measuring the number of base stations on CGI (common gateway interface) matching between the 5G base station and the registered 5G base station for 3500 MHz-3600 MHz frequency band of a third base station construction party, and obtaining the number of the base stations by CM4.8 matchingActually measuring the number of base stations on CGI (common gateway interface) matching between the 5G base station and the registered 5G base station for the 4800 MHz-4900 MHz frequency band of the first base station constructor, and obtaining the number of the base stations and the CM2.5 TotalActually measuring the total number of 5G base stations and CT for the 2515 MHz-2675 MHz frequency band of the first base station construction party3.4 TotalActually measuring the total number of 5G base stations and CUs for 3400 MHz-3500 MHz frequency band of a second base station construction party3.4 TotalActually measuring the total number of 5G base stations and CT for 3400 MHz-3500 MHz frequency band of a third base station construction method3.5 TotalActually measuring the total number of 5G base stations and CUs for 3500 MHz-3600 MHz frequency band of a second base station construction party3.5 TotalActually measuring the total number of 5G base stations and CM for 3500 MHz-3600 MHz frequency band of a third base station construction party4.8 TotalAnd actually measuring the total number of the 5G base stations for the 4800 MHz-4900 MHz frequency band of the first base station construction party.
Preferably, the drive test data acquisition of step (2) specifically includes the following steps:
and acquiring a base station cell identification code CGI of the 5G base station, and demodulating a mobile network code MNC, a mobile country code MCC and a network communication interface NCI.
Preferably, the cell registration rate adjusted in step (2) specifically includes:
calculating the adjusted cell registration rate according to the following formula:
Figure BDA0003310749750000031
wherein R is1For adjusted cell registration rate, CM2.5 matchingThe number of base stations and CT (computed tomography) matched with CGI (common gateway interface) of the 5G base station and the registered 5G base station are actually measured for the 2515 MHz-2675 MHz frequency band of the first base station construction party3.4 matchingThe number of base stations, CUs, on CGI (common gateway interface) matching between the actually measured 5G base station and the registered 5G base station for the 3400 MHz-3500 MHz frequency band of the second base station construction party3.5 matchingActually measuring the number of base stations on CGI (common gateway interface) matching between the 5G base station and the registered 5G base station for 3500 MHz-3600 MHz frequency band of a third base station construction party, and obtaining the number of the base stations by CM4.8 matchingFor the first base station builder 4The number of base stations, CM, on CGI (common gateway interface) matching between actually measured 5G base station and registered 5G base station in 800 MHz-4900 MHz frequency band2.5 TotalActually measuring the total number of 5G base stations and CT for the 2515 MHz-2675 MHz frequency band of the first base station construction party3.4 TotalActually measuring the total number of 5G base stations and CUs for 3400 MHz-3500 MHz frequency band of a second base station construction party3.5 TotalActually measuring the total number of 5G base stations and CM for 3500 MHz-3600 MHz frequency band of a third base station construction party4.8 TotalAnd actually measuring the total number of the 5G base stations for the 4800 MHz-4900 MHz frequency band of the first base station construction party.
Preferably, the step (3) specifically includes the following steps:
(3.1) deleting the total number of actually measured 5G base stations of the third base station construction party in the frequency band of 3400 MHz-3500 MHz, and deleting the total number of actually measured 5G base stations of the second base station construction party in the frequency band of 3500 MHz-3600 MHz;
and (3.2) updating the cell registration rate calculation mode.
Preferably, the cell registration rate updated in step (3.2) specifically includes:
calculating the updated cell registration rate according to the following formula:
Figure BDA0003310749750000032
wherein R is2For updated cell registration rate, CM2.5 matchingThe number of base stations and CT (computed tomography) matched with CGI (common gateway interface) of the 5G base station and the registered 5G base station are actually measured for the 2515 MHz-2675 MHz frequency band of the first base station construction party3.4 matchingThe number of base stations, CUs, on CGI (common gateway interface) matching between the actually measured 5G base station and the registered 5G base station for the 3400 MHz-3500 MHz frequency band of the second base station construction party3.5 matchingActually measuring the number of base stations on CGI (common gateway interface) matching between the 5G base station and the registered 5G base station for 3500 MHz-3600 MHz frequency band of a third base station construction party, and obtaining the number of the base stations by CM4.8 matchingActually measuring the number of base stations on CGI (common gateway interface) matching between the 5G base station and the registered 5G base station for the 4800 MHz-4900 MHz frequency band of the first base station constructor, and obtaining the number of the base stations and the CM2.5 TotalActually measuring the total number of 5G base stations and CT for the 2515 MHz-2675 MHz frequency band of the first base station construction party3.4 TotalActually measuring the total number of 5G base stations and CUs for 3400 MHz-3500 MHz frequency band of a second base station construction party3.5 TotalFor the third base station constructionActually measuring the total number of 5G base stations and CM in 3500 MHz-3600 MHz frequency band4.8 TotalAnd actually measuring the total number of the 5G base stations for the 4800 MHz-4900 MHz frequency band of the first base station construction party.
Preferably, the number of unregistered 5G base stations in step (4) is specifically:
the number of unregistered 5G base stations is calculated according to the following formula:
unR2=(CM2.5 Total+CT3.4 Total+CU3.5 Total+CM4.8 Total)-(CM2.5 matching+CT3.4 matching+CU3.5 matching+CM4.8 matching);
Wherein, CM2.5 matchingThe number of base stations and CT (computed tomography) matched with CGI (common gateway interface) of the 5G base station and the registered 5G base station are actually measured for the 2515 MHz-2675 MHz frequency band of the first base station construction party3.4 matchingThe number of base stations, CUs, on CGI (common gateway interface) matching between the actually measured 5G base station and the registered 5G base station for the 3400 MHz-3500 MHz frequency band of the second base station construction party3.5 matchingActually measuring the number of base stations on CGI (common gateway interface) matching between the 5G base station and the registered 5G base station for 3500 MHz-3600 MHz frequency band of a third base station construction party, and obtaining the number of the base stations by CM4.8 matchingActually measuring the number of base stations on CGI (common gateway interface) matching between the 5G base station and the registered 5G base station for the 4800 MHz-4900 MHz frequency band of the first base station constructor, and obtaining the number of the base stations and the CM2.5 TotalActually measuring the total number of 5G base stations and CT for the 2515 MHz-2675 MHz frequency band of the first base station construction party3.4 TotalActually measuring the total number of 5G base stations and CUs for 3400 MHz-3500 MHz frequency band of a second base station construction party3.5 TotalActually measuring the total number of 5G base stations and CM for 3500 MHz-3600 MHz frequency band of a third base station construction party4.8 TotalAnd actually measuring the total number of the 5G base stations for the 4800 MHz-4900 MHz frequency band of the first base station construction party.
The device for realizing the checking treatment aiming at the co-constructed 5G network base station is mainly characterized by comprising the following steps:
a processor configured to execute computer-executable instructions;
and the memory stores one or more computer-executable instructions, and when the computer-executable instructions are executed by the processor, the memory implements the steps of the method for implementing the checking process for the co-established 5G network base station.
The processor for implementing the checking process for the co-established 5G network base station is mainly characterized in that the processor is configured to execute computer-executable instructions, and when the computer-executable instructions are executed by the processor, the steps of the method for implementing the checking process for the co-established 5G network base station are implemented.
The computer readable storage medium is mainly characterized in that a computer program is stored thereon, and the computer program can be executed by a processor to realize the steps of the method for realizing the checking process for the co-established 5G network base station.
By adopting the method, the device, the processor and the computer readable storage medium for realizing the verification processing aiming at the co-constructed 5G network base station, the problem of low cell registration rate is caused because the total number of legal 5G base stations which are actually put into operation by an operator is greater than the total number of 5G base stations registered by a station library on the basis that 5G base station data in a registration station database of the existing radio management department lack of 5G base station data of a shared operator. The technical scheme reduces the number of illegal base stations extracted by a radio management department in the base station information verification, thereby reducing the workload of manually verifying the illegal base stations.
Drawings
Fig. 1 is a flowchart of a method for implementing a checking process for a co-established 5G network base station according to the present invention.
Fig. 2 is a schematic diagram of base station demodulation for implementing the method for performing the verification process on the co-established 5G network base station according to the present invention.
Fig. 3 is a schematic diagram of a 5G actual measurement base station matched with a registration station library in china mobile in 2515-2675MHz frequency band for implementing a method for performing verification processing on a co-constructed 5G network base station according to the present invention.
Fig. 4 is a schematic diagram of a 5G actual measurement base station in matching of the 3400-3500MHz frequency band chinese telecommunications and the registration station library in the method for implementing the verification process for the co-established 5G network base station of the present invention.
Fig. 5 is a schematic diagram of a 5G actual measurement base station in matching between chinese communications in the frequency band of 3500-3600MHz and a registration station library in the method for implementing the verification process for the co-established 5G network base station according to the present invention.
Detailed Description
In order to more clearly describe the technical contents of the present invention, the following further description is given in conjunction with specific embodiments.
The method for realizing the verification processing aiming at the co-constructed 5G network base station comprises the following steps:
(1) acquiring the construction condition of a 5G base station, calculating and counting the cell registration rate, and analyzing the condition of a legal base station;
(2) acquiring drive test data, and adjusting a cell registration rate calculation mode according to actually measured base station data;
(3) optimizing the calculation mode of the cell registration rate according to the characteristics of the actually measured base station data and the registration station data, and improving the cell registration rate;
(4) the number of unregistered 5G base stations is reduced, and the calculation mode of illegal base stations is optimized.
As a preferred embodiment of the present invention, the calculating the cell registration rate in step (1) specifically includes:
the cell registration rate is calculated according to the following formula:
the cell registration rate (measured base station number on the CGI match with the registered base station ÷ measured base station total number) × 100%.
As a preferred embodiment of the present invention, the cell registration rate in step (1) further includes a cell registration rate of a 5G base station, specifically:
calculating the cell registration rate of the 5G base station according to the following formula:
Figure BDA0003310749750000051
wherein R is cell registration rate, CM2.5 matchingThe number of base stations and CT (computed tomography) matched with CGI (common gateway interface) of the 5G base station and the registered 5G base station are actually measured for the 2515 MHz-2675 MHz frequency band of the first base station construction party3.4 matchingThe number of base stations, CUs, on CGI (common gateway interface) matching between the actually measured 5G base station and the registered 5G base station for the 3400 MHz-3500 MHz frequency band of the second base station construction party3.4 matchingAs a third base stationThe number of base stations, CT, on CGI (common gateway interface) matching between actually measured 5G base station and registered 5G base station of 3400 MHz-3500 MHz frequency band of construction party3.5 matchingActually measuring the number of base stations, CUs (China Unicode common practice) matched with CGI (common gateway interface) of 5G base station and registered 5G base station for 3500 MHz-3600 MHz frequency band of second base station construction party3.5 matchingActually measuring the number of base stations on CGI (common gateway interface) matching between the 5G base station and the registered 5G base station for 3500 MHz-3600 MHz frequency band of a third base station construction party, and obtaining the number of the base stations by CM4.8 matchingActually measuring the number of base stations on CGI (common gateway interface) matching between the 5G base station and the registered 5G base station for the 4800 MHz-4900 MHz frequency band of the first base station constructor, and obtaining the number of the base stations and the CM2.5 TotalActually measuring the total number of 5G base stations and CT for the 2515 MHz-2675 MHz frequency band of the first base station construction party3.4 TotalActually measuring the total number of 5G base stations and CUs for 3400 MHz-3500 MHz frequency band of a second base station construction party3.4 TotalActually measuring the total number of 5G base stations and CT for 3400 MHz-3500 MHz frequency band of a third base station construction method3.5 TotalActually measuring the total number of 5G base stations and CUs for 3500 MHz-3600 MHz frequency band of a second base station construction party3.5 TotalActually measuring the total number of 5G base stations and CM for 3500 MHz-3600 MHz frequency band of a third base station construction party4.8 TotalAnd actually measuring the total number of the 5G base stations for the 4800 MHz-4900 MHz frequency band of the first base station construction party.
As a preferred embodiment of the present invention, the drive test data acquisition in step (2) specifically includes the following steps:
and acquiring a base station cell identification code CGI of the 5G base station, and demodulating a mobile network code MNC, a mobile country code MCC and a network communication interface NCI.
As a preferred embodiment of the present invention, the adjusted cell registration rate in step (2) specifically includes:
calculating the adjusted cell registration rate according to the following formula:
Figure BDA0003310749750000061
wherein R is1For adjusted cell registration rate, CM2.5 matchingThe number of base stations and CT (computed tomography) matched with CGI (common gateway interface) of the 5G base station and the registered 5G base station are actually measured for the 2515 MHz-2675 MHz frequency band of the first base station construction party3.4 matchingActually measuring 3400 MHz-3500 MHz frequency band of second base station construction partyNumber of base stations, CU, in CGI matching of 5G base station and registered 5G base station3.5 matchingActually measuring the number of base stations on CGI (common gateway interface) matching between the 5G base station and the registered 5G base station for 3500 MHz-3600 MHz frequency band of a third base station construction party, and obtaining the number of the base stations by CM4.8 matchingActually measuring the number of base stations on CGI (common gateway interface) matching between the 5G base station and the registered 5G base station for the 4800 MHz-4900 MHz frequency band of the first base station constructor, and obtaining the number of the base stations and the CM2.5 TotalActually measuring the total number of 5G base stations and CT for the 2515 MHz-2675 MHz frequency band of the first base station construction party3.4 TotalActually measuring the total number of 5G base stations and CUs for 3400 MHz-3500 MHz frequency band of a second base station construction party3.5 TotalActually measuring the total number of 5G base stations and CM for 3500 MHz-3600 MHz frequency band of a third base station construction party4.8 TotalAnd actually measuring the total number of the 5G base stations for the 4800 MHz-4900 MHz frequency band of the first base station construction party.
As a preferred embodiment of the present invention, the step (3) specifically comprises the following steps:
(3.1) deleting the total number of actually measured 5G base stations of the third base station construction party in the frequency band of 3400 MHz-3500 MHz, and deleting the total number of actually measured 5G base stations of the second base station construction party in the frequency band of 3500 MHz-3600 MHz;
and (3.2) updating the cell registration rate calculation mode.
As a preferred embodiment of the present invention, the cell registration rate updated in step (3.2) specifically includes:
calculating the updated cell registration rate according to the following formula:
Figure BDA0003310749750000071
wherein R is2For updated cell registration rate, CM2.5 matchingThe number of base stations and CT (computed tomography) matched with CGI (common gateway interface) of the 5G base station and the registered 5G base station are actually measured for the 2515 MHz-2675 MHz frequency band of the first base station construction party3.4 matchingThe number of base stations, CUs, on CGI (common gateway interface) matching between the actually measured 5G base station and the registered 5G base station for the 3400 MHz-3500 MHz frequency band of the second base station construction party3.5 matchingActually measuring the number of base stations on CGI (common gateway interface) matching between the 5G base station and the registered 5G base station for 3500 MHz-3600 MHz frequency band of a third base station construction party, and obtaining the number of the base stations by CM4.8 matching4800 MHz-4900 MHz frequency for first base station construction partyNumber of base stations, CM, on CGI match between segment-measured 5G base station and registered 5G base station2.5 TotalActually measuring the total number of 5G base stations and CT for the 2515 MHz-2675 MHz frequency band of the first base station construction party3.4 TotalActually measuring the total number of 5G base stations and CUs for 3400 MHz-3500 MHz frequency band of a second base station construction party3.5 TotalActually measuring the total number of 5G base stations and CM for 3500 MHz-3600 MHz frequency band of a third base station construction party4.8 TotalAnd actually measuring the total number of the 5G base stations for the 4800 MHz-4900 MHz frequency band of the first base station construction party.
As a preferred embodiment of the present invention, the number of unregistered 5G base stations in step (4) is specifically:
the number of unregistered 5G base stations is calculated according to the following formula:
unR2=(CM2.5 Total+CT3.4 Total+CU3.5 Total+CM4.8 Total)-(CM2.5 matching+CT3.4 matching+CU3.5 matching+CM4.8 matching);
Wherein, CM2.5 matchingThe number of base stations and CT (computed tomography) matched with CGI (common gateway interface) of the 5G base station and the registered 5G base station are actually measured for the 2515 MHz-2675 MHz frequency band of the first base station construction party3.4 matchingThe number of base stations, CUs, on CGI (common gateway interface) matching between the actually measured 5G base station and the registered 5G base station for the 3400 MHz-3500 MHz frequency band of the second base station construction party3.5 matchingActually measuring the number of base stations on CGI (common gateway interface) matching between the 5G base station and the registered 5G base station for 3500 MHz-3600 MHz frequency band of a third base station construction party, and obtaining the number of the base stations by CM4.8 matchingActually measuring the number of base stations on CGI (common gateway interface) matching between the 5G base station and the registered 5G base station for the 4800 MHz-4900 MHz frequency band of the first base station constructor, and obtaining the number of the base stations and the CM2.5 TotalActually measuring the total number of 5G base stations and CT for the 2515 MHz-2675 MHz frequency band of the first base station construction party3.4 TotalActually measuring the total number of 5G base stations and CUs for 3400 MHz-3500 MHz frequency band of a second base station construction party3.5 TotalActually measuring the total number of 5G base stations and CM for 3500 MHz-3600 MHz frequency band of a third base station construction party4.8 TotalAnd actually measuring the total number of the 5G base stations for the 4800 MHz-4900 MHz frequency band of the first base station construction party.
The device for implementing the verification process for the co-established 5G network base station of the invention comprises:
a processor configured to execute computer-executable instructions;
and the memory stores one or more computer-executable instructions, and when the computer-executable instructions are executed by the processor, the memory implements the steps of the method for implementing the checking process for the co-established 5G network base station.
The processor for implementing the checking process for the co-established 5G network base station is configured to execute computer-executable instructions, and when the computer-executable instructions are executed by the processor, the steps of the method for implementing the checking process for the co-established 5G network base station are implemented.
The computer readable storage medium of the present invention has a computer program stored thereon, where the computer program is executable by a processor to implement the above-mentioned steps of implementing the method for performing the checking process for the co-established 5G network base station.
In the specific implementation of the present invention, as shown in fig. 1, relating to the field of radio station management, a method for checking a base station of a 5G network including a connected telecommunication infrastructure is provided in view of the requirement of radio station management service, and the method is divided into three steps. In the specification of the invention, a first base station construction party refers to China Mobile, a second base station construction party refers to China telecom, and a third base station construction party refers to China Unicom.
The first step is as follows: acquiring the construction condition of the 5G base station, carrying out cell registration rate statistics, and analyzing the condition of a legal base station
In radio station management, the cell registration rate is an important index for checking a registered base station. The cell registration rate is high, which indicates that more legal base stations and fewer illegal base stations exist, and the management efficiency of a radio management department on the legal base stations can be improved, and the checking work of the radio management department on the illegal base stations can be reduced.
The algorithm of the cell registration rate is as follows:
cell registration rate (measured base station number matched to the CGI of the registered base station ÷ measured base station total number) × 100% … … (1)
At present, in the established 5G base stations, the frequency range and sharing condition of the 5G base stations of china mobile, china unicom and china telecom are shown in the following table:
base station construction method Spectral range Base station sharing situation
China Mobile 2515MHz~2675MHz China mobile exclusive 5G base station
China telecom 3400MHz~3500MHz China telecom, China Unicom sharing 5G base station
China Unicom 3500MHz~3600MHz China telecom, China Unicom sharing 5G base station
China Mobile 4800MHz~4900MHz China mobile exclusive 5G base station
According to the station establishment condition of the 5G base station, the cell registration rate algorithm formula (1) of the 5G base station is refined as follows:
Figure BDA0003310749750000081
wherein R is cell registration rate, CM2.5 matchingThe number of base stations and CT (computed tomography) matched with CGI (common gateway interface) of the 5G base station and the registered 5G base station are actually measured for the 2515 MHz-2675 MHz frequency band of the first base station construction party3.4 matchingThe number of base stations, CUs, on CGI (common gateway interface) matching between the actually measured 5G base station and the registered 5G base station for the 3400 MHz-3500 MHz frequency band of the second base station construction party3.4 matchingThe number of base stations on CGI (common gateway interface) matching between the actually measured 5G base station and the registered 5G base station for the 3400 MHz-3500 MHz frequency band of the third base station construction party, CT (computed tomography)3.5 matchingActually measuring the number of base stations, CUs (China Unicode common practice) matched with CGI (common gateway interface) of 5G base station and registered 5G base station for 3500 MHz-3600 MHz frequency band of second base station construction party3.5 matchingActually measuring the number of base stations on CGI (common gateway interface) matching between the 5G base station and the registered 5G base station for 3500 MHz-3600 MHz frequency band of a third base station construction party, and obtaining the number of the base stations by CM4.8 matchingActually measuring the number of base stations on CGI (common gateway interface) matching between the 5G base station and the registered 5G base station for the 4800 MHz-4900 MHz frequency band of the first base station constructor, and obtaining the number of the base stations and the CM2.5 TotalActually measuring the total number of 5G base stations and CT for the 2515 MHz-2675 MHz frequency band of the first base station construction party3.4 TotalActually measuring the total number of 5G base stations and CUs for 3400 MHz-3500 MHz frequency band of a second base station construction party3.4 TotalActually measuring the total number of 5G base stations and CT for 3400 MHz-3500 MHz frequency band of a third base station construction method3.5 TotalActually measuring the total number of 5G base stations and CUs for 3500 MHz-3600 MHz frequency band of a second base station construction party3.5 TotalActually measuring the total number of 5G base stations and CM for 3500 MHz-3600 MHz frequency band of a third base station construction party4.8 TotalAnd actually measuring the total number of the 5G base stations for the 4800 MHz-4900 MHz frequency band of the first base station construction party.
The second step is that: algorithm for acquiring drive test data and adjusting cell registration rate according to actually measured base station data
The layer 3 information of the 5G system constituting the CGI is as follows:
systems of CGI composition
5G MCC+MNC+NCI(gNB ID+Cell ID)
The CGI is a common gateway interface and is a base station cell identification code; MCC is mobile country code, China is 460; the MNC is a mobile network code used for identifying a mobile communication network to which a mobile user belongs, and is composed of 2-3 digits. China mobile uses 00, 02, 04, 07, 08 and 13, China Unicom uses 01, 06, 09 and 10, and China telecom uses 03, 11 and 12; NCI is a network communication interface; the gNB ID is a 5G base station code; cell ID is a Cell identity.
During drive test data acquisition, the base station demodulation device can simultaneously demodulate 2 base stations with different MNC codes and completely same MCC and NCI in a coverage area of a 5G shared base station, as shown in fig. 2.
For the 5G shared base station in the frequency band of 3400 MHz-3500 MHz, the construction is by China telecommunication, the registration station library only registers the 5G registration base station data of China telecommunication in the frequency band, and does not register the 5G registration base station data of China telecommunication; for the 5G shared base station of 3500 MHz-3600 MHz frequency band, the base station is constructed by China Unicom, the register station library only registers the 5G register base station data of China Unicom in the frequency band, the 5G register base station data of China telecom is not registered, in the formula (2), CU3.4 matching=0,CT3.5 matching=0。
In the actually measured base station data, the tested 5G base station data of China telecom and China Unicom in the frequency ranges of 3400 MHz-3500 MHz and 3500 MHz-3600 MHz appear in pairs, and in the formula (2), CU3.4 Total=CT3.4 Total,CT3.5 Total=CU3.5 Total
Thus, the cell registration rate formula is adjusted to:
Figure BDA0003310749750000091
the third step: reasonably optimizing a cell registration rate algorithm according to the characteristics of actually measured base station data and registration station data, and improving the cell registration rate
Since the 5G registration base station of China Unicom exists in the 3400 MHz-3500 MHz frequency band, but is not registered in the registration base station library; the 5G registration base station of Chinese telecommunication in the 3400 MHz-3500 MHz frequency band actually exists, but is not registered to the registration station library. In order to improve the cell registration rate, under the condition that the data of a registration station base cannot be changed, Chinese Unicom 5G actual measurement base station data in the actual measurement data can be deleted for a 5G actual measurement base station in a 3400 MHz-3500 MHz frequency band, and only the Chinese telecom 5G actual measurement base station data is reserved; for the 5G actual measurement base station with the frequency band of 3500 MHz-3600 MHz, the Chinese telecom 5G actual measurement base station data in the actual measurement data can be deleted, and only the Chinese Mobile 5G actual measurement base station data is reserved.
After deleting CU3.4 TotalAnd CT3.5 TotalAfter actually measuring the base station data in 5G, the formula of the cell registration rate is changed to:
Figure BDA0003310749750000101
as a result of this, it is possible to,
Figure BDA0003310749750000102
is smaller than the flow rate of the gas flow,
Figure BDA0003310749750000103
so that R ═ R1<R2
Therefore, after the formula (2) is reasonably optimized, the cell registration rate can be increased, and the effective management of a radio management department on a legal base station can be improved.
The fourth step: reasonably reduce the number of unregistered 5G base stations and reduce the checking work of illegal base stations
The algorithm of the number of unregistered base stations is as follows:
measured base station number … … (5) matching with CGI of registered base station
In the actually measured 5G base station data, the unregistered 5G base station algorithm formula (5) is refined as:
unR=(CM2.5 Total+CT3.4 Total+CU3.4 Total+CT3.5 Total+CU3.5 Total+CM4.8 Total)-(CM2.5 matching+CT3.4 matching+CU3.4 matching+CT3.5 matching+CU3.5 matching+CM4.8 matching)……(6)
Wherein unR represents the number of unregistered 5G base stations.
From the second step, CU3.4 matching=0,CT3.5 matching=0
Therefore, equation (6) is adjusted to:
unR1=(CM2.5 Total+CT3.4 Total+CU3.4 Total+CT3.5 Total+CU3.5 Total+CM4.8 Total)-(CM2.5 matching+CT3.4 matching+CU3.5 matching+CM4.8 matching)……(7)
In the same way as the third step, the CU is deleted3.4 TotalAnd CT3.5 TotalAfter actually measuring the base station data of 5G, the unregistered 5G base station number calculation formula is changed to:
unR2=(CM2.5 Total+CT3.4 Total+CU3.5 Total+CM4.8 Total)-(CM2.5 matching+CT3.4 matching+CU3.5 matching+CM4.8 matching)
……(8)
Therefore unR2<unR1
Therefore, after the formula (6) is reasonably optimized, the number of unregistered base stations can be reduced, the checking work of a wireless signal power management department on 5G illegal base stations is reduced, and the labor cost is saved.
The present invention will be described in further detail with reference to specific embodiments by way of examples.
The first step is as follows: acquiring the construction condition of the 5G base station, carrying out cell registration rate statistics, and analyzing the condition of a legal base station
According to the construction condition of the 5G base station, the data of the registration base station is obtained, and part of the data of the registration base station is shown in tables 1 to 4.
The following table 1 shows the 2515-2675MHz band china mobile 5G registered base station.
TABLE 1
Figure BDA0003310749750000111
The following table 2 shows a 5G registration base station for china telecommunication in 3400-3500MHz frequency band.
TABLE 2
Figure BDA0003310749750000121
The following table 3 shows a 3500-3600MHz frequency band china unicom 5G registration base station.
TABLE 3
Figure BDA0003310749750000131
The following table 4 shows the registration base station for 5G of China Mobile with 4800-4900MHz band.
TABLE 4
Figure BDA0003310749750000132
The following table 5 shows the measured base station of 5G in China Mobile in the 2515-2675MHz band.
TABLE 5
Figure BDA0003310749750000141
The following table 6 shows that 3400-3500MHz frequency band chinese telecom and china unicom share 5G actual measurement base stations.
TABLE 6
Figure BDA0003310749750000142
Figure BDA0003310749750000151
The following table 7 shows the measured base station of 5G in China Mobile 5G in the 4800-and 4900MHz frequency bands.
TABLE 7
Figure BDA0003310749750000152
295 total 5G base stations are acquired according to primary base station drive test data acquisition, wherein:
43 China Mobile base stations in the 2515-2675MHz frequency band are shown in Table 5. 3400-3500MHz frequency band Chinese telecom and Chinese Unicom share 125 (250 in total) base stations of 5G, as shown in Table 6. The 3500-3600MHz frequency band chinese telecom and china unicom share 1 (total 2) base stations of 5G each, as shown in table 7.
And 0 China mobile 5G base stations in the 4800-4900MHz frequency band.
According to the data of the 5G actual measurement base station, the following can be obtained:
CM2.5 Total=43,CT3.4 Total=CU3.4 Total=125,CT3.5 Total=CU3.5 Total=1,CM4.8 Total=0
The report data analyzed by the base station information checking function of the drive test software shows that 23 actually measured base stations of 2515-2675MHz in China are matched with the CGI of the registration station library, as shown in FIG. 3. The number of the actual measurement base stations of 3400-3500MHz in China telecom is 107 matched with the CGI in the registration station library, as shown in figure 4. The actual measurement base stations of 3500-3600MHz in China are matched with the CGI of the registration station library by 1, as shown in figure 5.
Thus, CM is available2.5 matching=23,CT3.4 matching=107,CU3.4 matching=0,CT3.5 matching=0,CU3.5 matching=1,CM4.8 matching=0。
And calculating the cell registration rate of the 5G base station according to an algorithm formula (2):
Figure BDA0003310749750000161
the second step is that: algorithm for acquiring drive test data and adjusting cell registration rate according to actually measured base station data
According to the first step, the adjusted cell registration rate R of the algorithm formula (3) can be obtained1=R=44.4%。
The third step: reasonably optimizing a cell registration rate algorithm according to the characteristics of actually measured base station data and registration station data, and improving the cell registration rate
And calculating the cell registration rate of the 5G base station according to the actual data acquired in the first step and an algorithm formula (4):
Figure BDA0003310749750000162
77.5% > 44.4%, the reasonably optimized cell registration rate formula (4) is proved to be capable of improving the cell registration rate to a greater extent and improving the effective management of the radio management department on the legal base station.
The fourth step: reasonably reduce the number of unregistered 5G base stations and reduce the checking work of illegal base stations
According to the actual data of the first step, the number of unregistered base stations can be obtained by the formula (7):
unR1=(CM2.5 Total+CT3.4 Total+CU3.4 Total+CT3.5 Total+CU3.5 Total+CM4.8 Total)-(CM2.5 matching+CT3.4 matching+CU3.5 matching+CM4.8 matching)
=(43+125+125+1+1+0)-(23+107+1+0)
=164
The number of unregistered base stations can be obtained by the optimized formula (8):
unR2=(CM2.5 Total+CT3.4 Total+CU3.5 Total+CM4.8 Total)-(CM2.5 matching+CT3.4 matching+CU3.5 matching+CM4.8 matching)
=(43+125+1+0)-(23+107+1+0)
=38
Because 38 is less than 164, the reasonable optimized unregistered base station number formula (8) is proved, the checking work of a wireless signal electricity management department on 5G illegal base stations can be reduced to a greater extent, and the labor cost is saved.
For a specific implementation of this embodiment, reference may be made to the relevant description in the above embodiments, which is not described herein again.
It is understood that the same or similar parts in the above embodiments may be mutually referred to, and the same or similar parts in other embodiments may be referred to for the content which is not described in detail in some embodiments.
It should be noted that the terms "first," "second," and the like in the description of the present invention are used for descriptive purposes only and are not to be construed as indicating or implying relative importance. Further, in the description of the present invention, the meaning of "a plurality" means at least two unless otherwise specified.
Any process or method descriptions in flow charts or otherwise described herein may be understood as representing modules, segments, or portions of code which include one or more executable instructions for implementing specific logical functions or steps of the process, and alternate implementations are included within the scope of the preferred embodiment of the present invention in which functions may be executed out of order from that shown or discussed, including substantially concurrently or in reverse order, depending on the functionality involved, as would be understood by those reasonably skilled in the art of the present invention.
It should be understood that portions of the present invention may be implemented in hardware, software, firmware, or a combination thereof. In the above embodiments, the various steps or methods may be implemented in software or firmware stored in memory and executed by suitable instruction execution devices. For example, if implemented in hardware, as in another embodiment, any one or combination of the following techniques, which are known in the art, may be used: a discrete logic circuit having a logic gate circuit for implementing a logic function on a data signal, an application specific integrated circuit having an appropriate combinational logic gate circuit, a Programmable Gate Array (PGA), a Field Programmable Gate Array (FPGA), or the like.
It will be understood by those skilled in the art that all or part of the steps carried by the method for implementing the above embodiments may be implemented by hardware related to instructions of a program, and the corresponding program may be stored in a computer readable storage medium, and when executed, the program includes one or a combination of the steps of the method embodiments.
In addition, functional units in the embodiments of the present invention may be integrated into one processing module, or each unit may exist alone physically, or two or more units are integrated into one module. The integrated module can be realized in a hardware mode, and can also be realized in a software functional module mode. The integrated module, if implemented in the form of a software functional module and sold or used as a separate product, may also be stored in a computer readable storage medium.
The storage medium mentioned above may be a read-only memory, a magnetic or optical disk, etc.
In the description herein, references to the description of the term "one embodiment," "some embodiments," "an example," "a specific example," or "some examples," etc., mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the invention. In this specification, the schematic representations of the terms used above do not necessarily refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.
By adopting the method, the device, the processor and the computer readable storage medium for realizing the verification processing aiming at the co-constructed 5G network base station, the problem of low cell registration rate is caused because the total number of legal 5G base stations which are actually put into operation by an operator is greater than the total number of 5G base stations registered by a station library on the basis that 5G base station data in a registration station database of the existing radio management department lack of 5G base station data of a shared operator. The technical scheme reduces the number of illegal base stations extracted by a radio management department in the base station information verification, thereby reducing the workload of manually verifying the illegal base stations.
In this specification, the invention has been described with reference to specific embodiments thereof. It will, however, be evident that various modifications and changes may be made thereto without departing from the broader spirit and scope of the invention. The specification and drawings are, accordingly, to be regarded in an illustrative rather than a restrictive sense.

Claims (11)

1. A method for implementing verification processing for a co-constructed 5G network base station is characterized by comprising the following steps:
(1) acquiring the construction condition of a 5G base station, calculating and counting the cell registration rate, and analyzing the condition of a legal base station;
(2) acquiring drive test data, and adjusting a cell registration rate calculation mode according to actually measured base station data;
(3) optimizing the calculation mode of the cell registration rate according to the characteristics of the actually measured base station data and the registration station data, and improving the cell registration rate;
(4) the number of unregistered 5G base stations is reduced, and the calculation mode of illegal base stations is optimized.
2. The method according to claim 1, wherein the step (1) of calculating the cell registration rate specifically comprises:
the cell registration rate is calculated according to the following formula:
the cell registration rate (measured base station number on the CGI match with the registered base station ÷ measured base station total number) × 100%.
3. The method according to claim 1, wherein the cell registration rate in step (1) further includes a cell registration rate of the 5G base station, specifically:
calculating the cell registration rate of the 5G base station according to the following formula:
Figure FDA0003310749740000011
wherein R is cell registration rate, CM2.5 matchingThe number of base stations and CT (computed tomography) matched with CGI (common gateway interface) of the 5G base station and the registered 5G base station are actually measured for the 2515 MHz-2675 MHz frequency band of the first base station construction party3.4 matchingThe number of base stations, CUs, on CGI (common gateway interface) matching between the actually measured 5G base station and the registered 5G base station for the 3400 MHz-3500 MHz frequency band of the second base station construction party3.4 matchingThe number of base stations on CGI (common gateway interface) matching between the actually measured 5G base station and the registered 5G base station for the 3400 MHz-3500 MHz frequency band of the third base station construction party, CT (computed tomography)3.5 matchingActually measuring the number of base stations, CUs (China Unicode common practice) matched with CGI (common gateway interface) of 5G base station and registered 5G base station for 3500 MHz-3600 MHz frequency band of second base station construction party3.5 matchingActually measuring the number of base stations on CGI (common gateway interface) matching between the 5G base station and the registered 5G base station for 3500 MHz-3600 MHz frequency band of a third base station construction party, and obtaining the number of the base stations by CM4.8 matchingActually measuring the number of base stations on CGI (common gateway interface) matching between the 5G base station and the registered 5G base station for the 4800 MHz-4900 MHz frequency band of the first base station constructor, and obtaining the number of the base stations and the CM2.5 TotalActually measuring the total number of 5G base stations and CT for the 2515 MHz-2675 MHz frequency band of the first base station construction party3.4 TotalActually measuring the total number of 5G base stations and CUs for 3400 MHz-3500 MHz frequency band of a second base station construction party3.4 TotalActually measuring the total number of 5G base stations and CT for 3400 MHz-3500 MHz frequency band of a third base station construction method3.5 TotalActually measuring the total number of 5G base stations and CUs for 3500 MHz-3600 MHz frequency band of a second base station construction party3.5 TotalActually measuring the total number of 5G base stations and CM for 3500 MHz-3600 MHz frequency band of a third base station construction party4.8 TotalAnd actually measuring the total number of the 5G base stations for the 4800 MHz-4900 MHz frequency band of the first base station construction party.
4. The method according to claim 1, wherein the step (2) of acquiring drive test data specifically includes the following steps:
and acquiring a base station cell identification code CGI of the 5G base station, and demodulating a mobile network code MNC, a mobile country code MCC and a network communication interface NCI.
5. The method according to claim 1, wherein the cell registration rate adjusted in step (2) specifically includes:
calculating the adjusted cell registration rate according to the following formula:
Figure FDA0003310749740000021
wherein R is1For adjusted cell registration rate, CM2.5 matchingThe number of base stations and CT (computed tomography) matched with CGI (common gateway interface) of the 5G base station and the registered 5G base station are actually measured for the 2515 MHz-2675 MHz frequency band of the first base station construction party3.4 matchingThe number of base stations, CUs, on CGI (common gateway interface) matching between the actually measured 5G base station and the registered 5G base station for the 3400 MHz-3500 MHz frequency band of the second base station construction party3.5 matchingActually measuring the number of base stations on CGI (common gateway interface) matching between the 5G base station and the registered 5G base station for 3500 MHz-3600 MHz frequency band of a third base station construction party, and obtaining the number of the base stations by CM4.8 matchingActually measuring the number of base stations on CGI (common gateway interface) matching between the 5G base station and the registered 5G base station for the 4800 MHz-4900 MHz frequency band of the first base station constructor, and obtaining the number of the base stations and the CM2.5 TotalActually measuring the total number of 5G base stations and CT for the 2515 MHz-2675 MHz frequency band of the first base station construction party3.4 TotalActually measuring the total number of 5G base stations and CUs for 3400 MHz-3500 MHz frequency band of a second base station construction party3.5 TotalActually measuring the total number of 5G base stations and CM for 3500 MHz-3600 MHz frequency band of a third base station construction party4.8 TotalAnd actually measuring the total number of the 5G base stations for the 4800 MHz-4900 MHz frequency band of the first base station construction party.
6. The method according to claim 1, wherein the step (3) specifically includes the following steps:
(3.1) deleting the total number of actually measured 5G base stations of the third base station construction party in the frequency band of 3400 MHz-3500 MHz, and deleting the total number of actually measured 5G base stations of the second base station construction party in the frequency band of 3500 MHz-3600 MHz;
and (3.2) updating the cell registration rate calculation mode.
7. The method according to claim 6, wherein the updated cell registration rate in step (3.2) is specifically:
calculating the updated cell registration rate according to the following formula:
Figure FDA0003310749740000022
wherein R is2For updated cell registration rate, CM2.5 matchingThe number of base stations and CT (computed tomography) matched with CGI (common gateway interface) of the 5G base station and the registered 5G base station are actually measured for the 2515 MHz-2675 MHz frequency band of the first base station construction party3.4 matchingThe number of base stations, CUs, on CGI (common gateway interface) matching between the actually measured 5G base station and the registered 5G base station for the 3400 MHz-3500 MHz frequency band of the second base station construction party3.5 matchingActually measuring the number of base stations on CGI (common gateway interface) matching between the 5G base station and the registered 5G base station for 3500 MHz-3600 MHz frequency band of a third base station construction party, and obtaining the number of the base stations by CM4.8 matchingActually measuring the number of base stations on CGI (common gateway interface) matching between the 5G base station and the registered 5G base station for the 4800 MHz-4900 MHz frequency band of the first base station constructor, and obtaining the number of the base stations and the CM2.5 TotalActually measuring the total number of 5G base stations and CT for the 2515 MHz-2675 MHz frequency band of the first base station construction party3.4 TotalActually measuring the total number of 5G base stations and CUs for 3400 MHz-3500 MHz frequency band of a second base station construction party3.5 TotalActually measuring the total number of 5G base stations and CM for 3500 MHz-3600 MHz frequency band of a third base station construction party4.8 TotalAnd actually measuring the total number of the 5G base stations for the 4800 MHz-4900 MHz frequency band of the first base station construction party.
8. The method for implementing the checking process for the co-established 5G network base station according to claim 1, wherein the number of unregistered 5G base stations in the step (4) specifically is as follows:
the number of unregistered 5G base stations is calculated according to the following formula:
unR2=(CM2.5 Total+CT3.4 Total+CU3.5 Total+CM4.8 Total)-(CM2.5 matching+CT3.4 matching+CU3.5 matching+CM4.8 matching);
Wherein, CM2.5 matchingThe number of base stations and CT (computed tomography) matched with CGI (common gateway interface) of the 5G base station and the registered 5G base station are actually measured for the 2515 MHz-2675 MHz frequency band of the first base station construction party3.4 matchingThe number of base stations, CUs, on CGI (common gateway interface) matching between the actually measured 5G base station and the registered 5G base station for the 3400 MHz-3500 MHz frequency band of the second base station construction party3.5 matchingActually measuring the number of base stations on CGI (common gateway interface) matching between the 5G base station and the registered 5G base station for 3500 MHz-3600 MHz frequency band of a third base station construction party, and obtaining the number of the base stations by CM4.8 matchingActually measuring the number of base stations on CGI (common gateway interface) matching between the 5G base station and the registered 5G base station for the 4800 MHz-4900 MHz frequency band of the first base station constructor, and obtaining the number of the base stations and the CM2.5 TotalActually measuring the total number of 5G base stations and CT for the 2515 MHz-2675 MHz frequency band of the first base station construction party3.4 TotalActually measuring the total number of 5G base stations and CUs for 3400 MHz-3500 MHz frequency band of a second base station construction party3.5 TotalActually measuring the total number of 5G base stations and CM for 3500 MHz-3600 MHz frequency band of a third base station construction party4.8 TotalAnd actually measuring the total number of the 5G base stations for the 4800 MHz-4900 MHz frequency band of the first base station construction party.
9. An apparatus for implementing a checking process for a co-established 5G network base station, the apparatus comprising:
a processor configured to execute computer-executable instructions;
a memory storing one or more computer-executable instructions that, when executed by the processor, perform the steps of any one of claims 1 to 8 of the method of performing a verification process for a co-established 5G network base station.
10. A processor for implementing a checking process for a co-established 5G network base station, wherein the processor is configured to execute computer-executable instructions, and when the computer-executable instructions are executed by the processor, the processor implements the steps of any one of claims 1 to 8 of the method for implementing the checking process for the co-established 5G network base station.
11. A computer-readable storage medium, having stored thereon a computer program executable by a processor to perform the steps of the method of any of claims 1 to 8 for performing a checking process for a co-established 5G network base station.
CN202111216258.1A 2021-10-19 2021-10-19 Method for implementing checking processing for co-established 5G network base station Active CN113747477B (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
CN202111216258.1A CN113747477B (en) 2021-10-19 2021-10-19 Method for implementing checking processing for co-established 5G network base station

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
CN202111216258.1A CN113747477B (en) 2021-10-19 2021-10-19 Method for implementing checking processing for co-established 5G network base station

Publications (2)

Publication Number Publication Date
CN113747477A true CN113747477A (en) 2021-12-03
CN113747477B CN113747477B (en) 2024-03-15

Family

ID=78726973

Family Applications (1)

Application Number Title Priority Date Filing Date
CN202111216258.1A Active CN113747477B (en) 2021-10-19 2021-10-19 Method for implementing checking processing for co-established 5G network base station

Country Status (1)

Country Link
CN (1) CN113747477B (en)

Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN114423015A (en) * 2021-12-28 2022-04-29 上海市无线电监测站 Vehicle-mounted system for rapid test and comparison of in-use station and implementation method

Citations (6)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US20040105429A1 (en) * 2001-03-09 2004-06-03 Lars Anckar Network and method for sharing radio access nodes between core networks
WO2008138769A1 (en) * 2007-05-11 2008-11-20 Nokia Siemens Networks Oy Method to attach a mobile station to a second generation packet network shared between different operators
EP2496050A1 (en) * 2011-03-01 2012-09-05 Alcatel Lucent Multi-operator radio cells
US20140247792A1 (en) * 2011-11-18 2014-09-04 Huawei Technologies Co., Ltd. Radio communication system, base station device and management method thereof
CN104918270A (en) * 2014-03-11 2015-09-16 中国移动通信集团广东有限公司 Wireless network parameter obtaining method, apparatus and terminal
CN112887039A (en) * 2020-09-03 2021-06-01 上海无委无线电检测实验室有限公司 5G base station radio frequency consistency test method

Patent Citations (6)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US20040105429A1 (en) * 2001-03-09 2004-06-03 Lars Anckar Network and method for sharing radio access nodes between core networks
WO2008138769A1 (en) * 2007-05-11 2008-11-20 Nokia Siemens Networks Oy Method to attach a mobile station to a second generation packet network shared between different operators
EP2496050A1 (en) * 2011-03-01 2012-09-05 Alcatel Lucent Multi-operator radio cells
US20140247792A1 (en) * 2011-11-18 2014-09-04 Huawei Technologies Co., Ltd. Radio communication system, base station device and management method thereof
CN104918270A (en) * 2014-03-11 2015-09-16 中国移动通信集团广东有限公司 Wireless network parameter obtaining method, apparatus and terminal
CN112887039A (en) * 2020-09-03 2021-06-01 上海无委无线电检测实验室有限公司 5G base station radio frequency consistency test method

Non-Patent Citations (4)

* Cited by examiner, † Cited by third party
Title
刘悦;钟期洪;沈建军;安劲伟;: "LTE基站共享关键参数配置与部署", 电信科学, no. 2 *
周泉;晏志强;杨振华;王伟;: "基于NSA单锚点共享模式下4G/5G协同策略探讨和应用", 邮电设计技术, no. 06 *
张轶戈;钟海;张军;: "5G接入网络共享共建", 中国新通信, no. 16 *
陈春海;: "多运营商LTE一体化基站的设计研究", 信息通信, no. 04 *

Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN114423015A (en) * 2021-12-28 2022-04-29 上海市无线电监测站 Vehicle-mounted system for rapid test and comparison of in-use station and implementation method

Also Published As

Publication number Publication date
CN113747477B (en) 2024-03-15

Similar Documents

Publication Publication Date Title
CN103347278B (en) The update method of fingerprint database and device in wireless location
EP2620024B1 (en) Generation and use of coverage area models
US20110227790A1 (en) Cuckoo hashing to store beacon reference data
CN111372183B (en) Method, device, equipment and storage medium for identifying poor terminal
US20190200318A1 (en) Supporting an update of stored information
WO2020207096A1 (en) Method for performing positioning in 5g scenarios, positioning platform and user terminal
CN107371158A (en) The investigation of mobile communication carrier user accounting and crowd measure estimating and measuring method in region
CN105163344A (en) Method for positioning TD-LTE intra-system interference
CN109996258A (en) Wireless network utilization appraisal procedure, calculates equipment and storage medium at device
CN105828393B (en) Method and device for configuring adjacent cells between systems
CN111328102B (en) Method and device for identifying common coverage relation
CN113747477A (en) Method, device and processor for realizing verification processing aiming at co-constructed 5G network base station and computer readable storage medium thereof
CN108770057A (en) The determination method and fingerprint positioning method in predetermined fingerprint library, device, storage medium
CN109246587B (en) High-speed rail network interference analysis method and device
CN109218963B (en) Position fingerprint data processing method, device, equipment and storage medium
Gambi et al. A WKNN-based approach for NB-IoT sensors localization
CN113115378B (en) Co-construction shared resource block configuration method and access network equipment
CN113645625A (en) Pseudo base station positioning method and device, electronic equipment and readable medium
CN111093207B (en) Signal coverage quality evaluation method and device of mobile communication network
CN107995650A (en) Obtain the method and device of adjacent area cell ID
CN110536356B (en) Public-private network interference investigation method and device
US10084673B1 (en) Network test system, a shakedown server, and a method of performing site acceptance testing for a communications network site
CN113115371B (en) Co-construction shared resource block configuration method and access network equipment
CN114040426B (en) Network optimization method, abnormal cell pushing method, device, terminal and server
TWI601434B (en) Wireless base station identification method and device

Legal Events

Date Code Title Description
PB01 Publication
PB01 Publication
SE01 Entry into force of request for substantive examination
SE01 Entry into force of request for substantive examination
GR01 Patent grant
GR01 Patent grant