JP5293559B2 - Communications system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To properly set operation information in a device of a base station in a communication system. <P>SOLUTION: The communication system 1 includes a first device 2 having identification information A5 of a first base station, a second device 3 having operation information B6 of a second base station corresponding to the first base station, and a third device 4 having information 8 unique to the second device. The second device 3 has a correspondence relation 7 between the identification information A of the first device and the operation information B of the second device. The third device 4 acquires the identification information A5 of the first base station from the first device 2. The third device 4 acquires the operation information B6 of the second base station corresponding to identification information A9 of the first base station from the second device 3 on the basis of information 8 inherent to the second device. The third device 4 performs setting as the second base station in the third device 4 on the basis of operation information B10 of the second base station. <P>COPYRIGHT: (C)2011,JPO&amp;INPIT

Description

  The present invention relates to a communication system.

  Conventionally, a communication device for setting communication parameters is known. Such a communication apparatus includes, for example, a memory in which a plurality of different types of communication parameters are grouped into one group and communication parameters of a plurality of groups having the same combination of communication parameter types are stored in units of groups. At least one communication of one or more groups stored in the memory by performing at least one of the above-mentioned crossover between groups of communication parameters of the same type and mutation of communication parameters according to a predetermined rule. A parameter changing unit that changes parameters, a parameter evaluating unit that evaluates whether or not a communication parameter can be adopted in a group unit according to a predetermined evaluation method, and a parameter evaluation unit that has been evaluated as adoptable by the parameter evaluating unit. Update communication parameters as regular communication parameters used for communication operations A parameter update unit is provided (for example, see Patent Document 1.).

JP 2004-153437 A

  However, in the conventional technology, when a base station is newly installed, the base station apparatus is shipped from the factory in a state in which operation information is set in advance. Alternatively, operation information is set in an apparatus by a worker during construction for installing the base station apparatus. Since the operation information is different for each base station, when a device in which operation information for a certain base station is set is mistakenly installed in another base station, the other base station may not operate normally. Further, there is a possibility that the service of the network to which the other base station belongs is interrupted. The same applies when another base station operation information is mistakenly set in the base station apparatus during construction for establishing a base station.

  It is an object of the present invention to provide a communication system capable of correctly setting operation information in a base station apparatus.

  The communication system includes a first device having identification information of a first base station, a second device having operation information of a second base station corresponding to the first base station, and a second device. A third device having unique information. The second device has a correspondence relationship between the operation information of the second base station and the identification information of the first base station. The third device acquires the identification information of the first base station from the first device. The third device acquires operation information of the second base station corresponding to the identification information of the first base station from the second device based on information unique to the second device. The third device performs setting as the second base station in the third device based on the operation information of the second base station.

  According to this communication system, there is an effect that operation information can be correctly set in the base station apparatus.

1 is a block diagram illustrating a communication system according to a first embodiment. 3 is a flowchart illustrating a communication procedure of the communication system according to the first embodiment. It is a block diagram which shows the communication system concerning Example 2. FIG. It is explanatory drawing which shows the table concerning Example 2. FIG. FIG. 10 is a sequence diagram illustrating a communication procedure of the communication system according to the second embodiment. It is explanatory drawing which shows the node ID request message concerning Example 2. FIG. It is explanatory drawing which shows the node ID response message concerning Example 2. FIG. It is explanatory drawing which shows the parameter request message concerning Example 2. FIG. It is explanatory drawing which shows the parameter response message concerning Example 2. FIG. FIG. 10 is an explanatory diagram of a node ID setting message according to the second embodiment. It is a block diagram which shows the communication system concerning Example 3. FIG. 10 is a flowchart illustrating an operation information acquisition procedure in the communication system according to the fourth embodiment.

  Exemplary embodiments of the communication system will be described below in detail with reference to the accompanying drawings. In the communication system according to the embodiment, the third device acquires the identification information of the first base station from the first device, and obtains the second base station operation information corresponding to the identification information as the second information. By obtaining from the device, the correct operation information is set as the second base station in the third device.

Example 1
FIG. 1 is a block diagram of a communication system according to the first embodiment. As shown in FIG. 1, the communication system 1 includes a first device 2, a second device 3, and a third device 4. The first device 2 has identification information A5 of the first base station. The second device 3 has operation information B6 of the second base station corresponding to the first base station. The second device 3 has a correspondence relationship 7 between the identification information A of the first base station and the operation information B of the second base station. The third device 4 has information 8 unique to the second device. In FIG. 1, the identification information A5 of the first base station, the operation information B6 of the second base station, and the information 8 unique to the second device indicated by the solid line are shown in FIG. It is already provided in the corresponding device 2, 3, 4 before connection. In FIG. 1, the identification information A9 of the first base station and the operation information B10 of the second base station, which are indicated by broken lines, are obtained by the third device 4 when the third device 4 is connected to the first device 2. It is obtained from the first device 2 and the second device 3.

FIG. 2 is a flowchart of a communication procedure of the communication system according to the first embodiment. As shown in FIG. 2, the third device 4 accesses the first device 2 when connected to the first device 2. Thereby, the identification information A5 of the first base station is transferred from the first device 2 to the third device 4. Thereby, the third device 4 acquires the identification information A9 of the first base station (step S1). Next, the third device 4 accesses the second device 3 based on the information 8 unique to the second device, and passes the identification information A9 of the first base station to the second device 3. The second device 3 is based on the correspondence 7 between the identification information A of the first base station and the operation information B of the second base station. The operation information B6 of the second base station corresponding to the identification information A is selected. The operation information B6 of the second base station selected by the second device 3 is transferred from the second device 3 to the third device 4. Thereby, the third device 4 acquires the operation information B10 of the second base station, and sets the operation information B10 of the second base station in the third device 4 (step S2). And the 3rd apparatus 4 starts the operation | movement as a 2nd base station with the 1st apparatus 2. FIG.

  According to the first embodiment, the third device 4 uses the second base station operation information B from the second device 3 based on the identification information A of the first base station acquired from the first device 2. Therefore, the correct operation information can be set as the second base station in the third device 4. In addition, in the stage before connecting the third device 4 to the first device 2, information unique to the second device may be set in the third device 4. 4 may be connected to any one of the plurality of first devices 2. That is, it is not necessary to manage the correspondence between the third device 4 and the first device 2 to which the third device 4 is connected. Therefore, the manufacturing cost of the third device 4 and the cost when connecting the third device 4 to the first device 2 can be reduced. Also, before connecting the third device 4 to the first device 2, the second base station operation information B is prepared according to the environment in which the third device 4 is installed. Therefore, the operation information B of the second base station that is sufficiently adjusted according to the actual environment can be prepared.

(Example 2)
As an application example of the communication system according to the first embodiment, for example, there is a case where operation parameters are set in a base station apparatus of a new system when shifting from an operating communication system to a new communication system to start operation from now. An example of a communication system in operation is a third generation (3G) mobile phone system. As an example of a new communication system, for example, there is a long term evolution (LTE) system that is being standardized in the 3rd Generation Partnership Project (3GPP). In the following embodiment, an example will be described in which an LTE system base station (eNB: evolved Node B) is added to a 3G system base station (Node B) in the transition period from the 3G system to the LTE system. The communication system according to the first embodiment is not limited to the case of shifting from the 3G system to the LTE system, but can be applied to the case of shifting from the current operation system to the new system.

FIG. 3 is a block diagram of a communication system according to the second embodiment. As shown in FIG. 3, the communication system 21 includes a shared RRH 22 as a first device, an OMC 23 as a second device, and an LTE-BBU 24 as a third device. RRH is an abbreviation for Remote Radio Head (remote radio head) and is a radio section of a base station. BBU is an abbreviation for Base Band Unit, and is a baseband signal processing unit of a base station. OMC is an abbreviation for Operation and Maintenance Center, and is an operation and maintenance center. The communication system 21 includes a 3G-BBU 31 and a DHCP server 32 as a fourth device. DHCP is an abbreviation for Dynamic Host Configuration Protocol. The DHCP server 32 automatically assigns an IP (Internet Protocol) address.

  First, the configuration of the communication system 21 before starting the transition work from the 3G system to the LTE system will be described. In the 3G system, the communication system 21 includes a shared RRH 22 and 3G-BBU 31. The base station of the 3G system corresponds to the first base station in the first embodiment, and includes the shared RRH 22 and 3G-BBU 31. The shared RRH 22 and the 3G-BBU 31 are not particularly limited, and are connected by, for example, a CPRI (Common Public Radio Interface) link 33.

  The shared RRH 22 has an RRH parameter 41 as operation information of the shared RRH 22. In the RRH parameter 41, the node ID (hereinafter referred to as ID-3G) 25 of the base station in the 3G system is set by the 3G-BBU 31. ID-3G25 corresponds to the identification information A of the first base station in the first embodiment. In the communication system 21 before starting the transition work from the 3G system to the LTE system, the LTE-BBU 24 is not connected to the shared RRH 22. The LTE-BBU 24 has an IP address (hereinafter referred to as OMC-IP) 28 of the OMC 23 that is accessed when connected to the shared RRH 22 before being connected to the shared RRH 22. The OMC-IP 28 corresponds to information unique to the second device in the first embodiment. The LTE-BBU 24 may have information other than the OMC-IP 28 at a stage before being connected to the shared RRH 22.

  Next, the configuration of the communication system 21 after the start of the transition work from the 3G system to the LTE system will be described. The LTE-BBU 24 is connected to the shared RRH 22. That is, the shared RRH 22 is shared as a radio unit in both the 3G system and the LTE system. The base station of the LTE system corresponds to the second base station in the first embodiment, and includes the shared RRH 22 and the LTE-BBU 24. The shared RRH 22 and the LTE-BBU 24 are not particularly limited, but are connected by, for example, the CPRI link 34.

  In the LTE system, the LTE-BBU 24, the OMC 23, and the DHCP server 32 are connected to an IP network 35, for example. The OMC 23 includes a database 42 that stores operation information of the LTE-BBU 24. The database 42 stores an LTE parameter 26 as operation information of the LTE-BBU 24. The LTE parameter 26 corresponds to the operation information B of the second base station in the first embodiment. A plurality of LTE-BBUs are connected to the OMC 23 via the IP network 35. The database 42 stores LTE parameters corresponding to each LTE-BBU. The OMC 23 has a table 27 that defines the correspondence between a plurality of ID-3Gs and a plurality of LTE parameters. The table 27 corresponds to the correspondence relationship between the identification information A of the first base station and the operation information B of the second base station in the first embodiment.

  In FIG. 3, ID-3G25, LTE parameter 26, and OMC-IP 28 indicated by solid lines are already provided in corresponding shared RRH 22, OMC 23, and LTE-BBU 24 before connecting LTE-BBU 24 to shared RRH 22. In FIG. 3, ID-3G51, OWN-IP52, LTE parameter file name 53, LTE parameter 54, and ID-LTE55 and 56 indicated by broken lines are connected to LTE-BBU24 and shared RRH22 when LTE-BBU24 is connected to shared RRH22. Each is acquired.

  FIG. 4 is an explanatory diagram of a table according to the second embodiment. As shown in FIG. 4, the table 27 defines the correspondence between ID-3G and LTE parameters. In addition, when the IP address of LTE-BBU 24 (hereinafter referred to as OWN-IP) is notified from LTE-BBU 24, table 27 holds the correspondence relationship between ID-3G and LTE parameters and OWN-IP.

FIG. 5 is a sequence diagram of the communication procedure of the communication system according to the second embodiment. As shown in FIG. 5, when connected to the shared RRH 22, the LTE-BBU 24 requests the ID-3G25 of the RRH parameter 41 from the shared RRH 22 by a node ID request message (NIDREQ) (step S11). The shared RRH 22 returns a node ID response message (NIDRESP) including ID-3G25 to the LTE-BBU 24 as a response to the request for ID-3G25 (step S12). Thereby, the LTE-BBU 24 acquires ID-3G51 (step S13). The node ID request message and the node ID response message are defined as unique messages in the C & M signal on the CPRI, for example (see FIGS. 6 and 7).

  Next, the LTE-BBU 24 exchanges, for example, DHCP Discovery (Step S14), DHCP Offer (Step S15), DHCP Request (Step S16), and DHCP Ack (Step S17) with the DHCP server 32, and the DHCP server. OWN-IP 52 is acquired from 32 (step S18). The OWN-IP 52 is an IP address of the LTE-BBU 24 on the IP network.

  Next, the LTE-BBU 24 requests the LTE parameter 26 from the OMC 23 by a parameter request message (SYSPREQ) including the OWN-IP 52 as a transmission source address, the OMC-IP 28 as a destination address, and ID-3G51 as a search key (step S19). ). When the OMC 23 receives the parameter request message, the OMC 23 searches the table 27 using ID-3G51 as a search key, and obtains the file name of the corresponding LTE parameter 26. The OMC 23 returns a parameter response message (SYSPRESP) including the file name of the LTE parameter 26 to the LTE-BBU 24 as a response to the request for the LTE parameter 26 (step S20). Thereby, the LTE-BBU 24 acquires the file name 53 of the LTE parameter 26 (step S21).

  The LTE-BBU 24 and the OMC 23 can communicate with each other using, for example, SNMP (Simple Network Management Protocol). When using SNMP, the parameter request message is transmitted from the LTE-BBU 24 to the OMC 23 as a snmp command using ID-3G and OWN-IP as parameters. Further, the LTE-BBU 24 receives the content of the parameter response message from the OMC 23 as a response to the snmp command.

  Next, the LTE-BBU 24 establishes, for example, an ftp (File Transfer Protocol) session with the OMC 23. The LTE-BBU 24 designates the file name 53 of the LTE parameter 26 acquired in step S21 in the ftp get command, and reads the corresponding LTE parameter 26 file from the database 42 of the OMC 23 (step S22). Thereby, the LTE-BBU 24 acquires a file of the LTE parameter 54 (step S23). The LTE-BBU 24 sends a node ID setting message (NIDSET) including its own node ID (ID-LTE) 55 included in the LTE parameter 54 to the shared RRH 22. As a result, the ID-LTE 56 is set in the RRH parameter 41 of the shared RRH 22 (step S24). And LTE-BBU24 restarts using the LTE parameter 54 acquired by step S23 (step S25), and starts a service (step S26). When, for example, SNMP is used for communication between the LTE-BBU 24 and the OMC 23, communication is performed by defining a parameter request message and a parameter response message as MIB (Management Information Base) parameters.

  FIG. 6 is an explanatory diagram of a node ID request message according to the second embodiment. As shown in FIG. 6, the node ID request message 61 has a field for storing a code indicating that it is a node ID request message.

  FIG. 7 is an explanatory diagram of a node ID response message according to the second embodiment. As shown in FIG. 7, the node ID response message 62 has a field for storing a code indicating that it is a node ID response message, and a field for storing ID-3G.

  FIG. 8 is an explanatory diagram of a parameter request message according to the second embodiment. As shown in FIG. 8, the parameter request message 63 has a field for storing a code indicating that it is a parameter request message, a field for storing ID-3G, and a field for storing OWN-IP.

  FIG. 9 is an explanatory diagram of a parameter response message according to the second embodiment. As shown in FIG. 9, the parameter response message 64 has a field for storing a code indicating that it is a parameter response message, and a field for storing a file name of the LTE parameter.

  FIG. 10 is an explanatory diagram of a node ID setting message according to the second embodiment. As shown in FIG. 10, the node ID setting message 65 has a field for storing a code indicating that it is a node ID setting message and a field for storing ID-LTE.

  According to the second embodiment, since the LTE-BBU 24 acquires the LTE parameter 26 from the OMC 23 based on the ID-3G51 acquired from the shared RRH 22, it is possible to set a correct parameter in the LTE-BBU 24. In addition, in the stage before connecting the LTE-BBU 24 to the shared RRH 22, it is only necessary that the OMC-IP 28 is set in the LTE-BBU 24. Therefore, the LTE-BBU 24 is connected to any of the plurality of shared RRHs 22. May be. That is, it is not necessary to manage the correspondence relationship between the LTE-BBU 24 and the shared RRH 22 to which the LTE-BBU 24 is connected. Therefore, the manufacturing cost of LTE-BBU24 and the cost at the time of connecting LTE-BBU24 to common RRH22 can be reduced. In addition, it is sufficient to prepare the LTE parameter 26 according to the environment in which the LTE-BBU 24 is installed and store it in the OMC 23 until the LTE-BBU 24 is connected to the shared RRH 22. The LTE parameter 26 adjusted to can be prepared.

  In step S22 described above, the OMC 23 may read the file of the corresponding LTE parameter 26 from the database 42 of the OMC 23 and transfer it to the LTE-BBU 24, for example, by an ftp put command. In this case, if there is a file name of the corresponding LTE parameter in the table 27 in step S20, the OMC 23 returns ACK (normal) to the LTE-BBU 24 as a parameter response message (SYSPRESP) for the LTE parameter request. Also good. When there is no file name of the corresponding LTE parameter in the table 27, the OMC 23 may return NACK (abnormal) to the LTE-BBU 24. In this way, the OMC 23 can schedule the timing for transferring the file of the LTE parameter 26 according to the convenience of the load of the OMC 23 and the like.

(Example 3)
The communication system according to the third embodiment is an example in a case where information corresponding to information unique to the second device in the first embodiment is the name of the OMC. In the third embodiment, the same components as those in the second embodiment are denoted by the same reference numerals as those in the second embodiment, and a duplicate description is omitted.

  FIG. 11 is a block diagram of a communication system according to the third embodiment. As illustrated in FIG. 11, the communication system 21 includes a DNS server 36 as a fifth device in addition to the configuration of the second embodiment. DNS is an abbreviation for Domain Name System. The DNS server 36 is connected to the IP network 35 and manages the correspondence between the host name and domain name and the IP address. The LTE-BBU 24 has the name of the OMC 23 (hereinafter referred to as OMC-name) 29 instead of OMC-IP as information corresponding to information unique to the second device in the first embodiment. The OMC-name 29 is represented in a host name + domain name format (FQDN: Full Qualified Domain Name format), for example, “omc.xxx.yyy.com”.

  In FIG. 11, ID-3G25, LTE parameter 26 and OMC-name 29 indicated by a solid line are already provided in the corresponding shared RRH 22, OMC 23 and LTE-BBU 24 before connecting LTE-BBU 24 to shared RRH 22. In FIG. 11, ID-3G51, OWN-IP52, OMC-IP57, LTE parameter file name 53, LTE parameter 54, and ID-LTE55 and 56 indicated by broken lines are LTE-BBU24 when LTE-BBU24 is connected to shared RRH22. And the common RRH 22 respectively.

  In the third embodiment, the LTE-BBU 24 acquires the OWN-IP 52 from the DHCP server 32, then accesses the DNS server 36 using the OWN-IP 52, and requests resolution of the name of the OMC-name 29. At this time, the DNS server 36 accessed by the LTE-BBU 24 is a DNS server that manages the network domain in which the LTE-BBU 24 is installed. The DNS server 36 returns the IP address of the OMC 23 to the LTE-BBU 24 as a response to the request from the LTE-BBU 24. Thereby, the LTE-BBU 24 acquires the IP address (OMC-IP) 57 of the OMC 23. The LTE-BBU 24 can obtain the LTE parameter 26 file from the OMC 23 in the same manner as in the second embodiment using the OMC-IP 57 acquired from the DNS server 36.

  According to the third embodiment, the same effect as in the second embodiment can be obtained. Further, according to the third embodiment, even when the network of the network operator is divided into a plurality of parts, and the OMC is arranged in each of the divided parts, the LTE-BBU 24 selects the local station from the plurality of OMCs. The OMC having the LTE parameters for can be correctly selected.

Example 4
The fourth embodiment is an example where a plurality of OMCs exist in the second embodiment. The LTE-BBU has a plurality of OMC IP addresses as information corresponding to information unique to the second device in the first embodiment. The communication system according to the fourth embodiment is the same as that of the second embodiment. However, there are a plurality of OMCs.

  FIG. 12 is a flowchart of an operation information (LTE parameter) acquisition procedure in the communication system according to the fourth embodiment. As shown in FIG. 12, when the process for acquiring LTE parameters is started, first, the LTE-BBU sets the value of n to 0 (step S31). n is an integer of 0 or more. The maximum value of n is smaller by 1 than the number of OMCs present in plurality. Next, the LTE-BBU issues a parameter request message (SYSSPREQ) including OWN-IP as a source address, OMC-IPn as a destination address, and ID-3G as a search key. OMC-IPn is the IP address of the nth OMC among the plurality of OMC IP addresses. That is, the LTE-BBU requests an LTE parameter from the OMC whose IP address is OMC-IPn among the plurality of OMCs (step S32).

  If the file name of the LTE parameter corresponding to ID-3G notified from the LTE-BBU is in the table, the OMC returns ACK (normal) to the LTE-BBU. When the file name of the LTE parameter corresponding to ID-3G notified from the LTE-BBU is not in the table, the OMC returns NACK (abnormal) to the LTE-BBU. The LTE-BBU receives a parameter response message (SYSPRESP) including ACK or NACK as a response to the LTE parameter request from the OMC (step S33). The parameter response message (SYSPRESP) may or may not include the LTE parameter file name along with ACK.

  When the LTE-BBU receives a parameter response message (SYSPRESP) including ACK from the OMC (step S34: Yes), the LTE-BBU ends the series of LTE parameter acquisition processing on the assumption that the LTE parameter has been successfully acquired. Thereafter, for example, an ftp session is established, and the corresponding LTE parameter file is transferred from the OMC to the LTE-BBU (see FIG. 5, step S22 in the figure). On the other hand, when LTE-BBU receives NACK as a parameter response message (SYSPRESP) from OMC (step S34: No), it increments the value of n by 1 (step S35). If the incremented value of n is less than or equal to the maximum value of n (step S36: Yes), the process returns to step S32.

  And LTE-BBU requests | requires a LTE parameter with respect to OMC of the following IP address (OMC-IPn) (step S32). Until the LTE-BBU receives ACK in step S34 (step S34: Yes) or until the value of n becomes larger than the maximum value of n in step S36 (step S36: No), the LTE-BBU The processing from S32 to step S36 is repeated. When the value of n becomes larger than the maximum value of n (step S36: No), the LTE-BBU ends the series of LTE parameter acquisition processing, assuming that acquisition of the LTE parameter has failed.

  According to the fourth embodiment, the same effect as the second embodiment can be obtained. Further, according to the fourth embodiment, even when a plurality of OMCs are arranged, the LTE-BBU can acquire and set the correct LTE parameters for the own station.

DESCRIPTION OF SYMBOLS 1,21 Communication system 2,22 1st apparatus 3,23 2nd apparatus 4,24 3rd apparatus 5,25 Identification information of 1st base station 6,26 Operation information of 2nd base station 7, 27 Correspondence between identification information of first base station and operation information of second base station 8, 28, 29 Information unique to second device 32 Fourth device 36 Fifth device

Claims (5)

A first device having identification information of a first base station;
A second apparatus having a correspondence relationship between the operation information of the second base station corresponding to the first base station, and the operation information of the second base station and the identification information of the first base station;
A third device having information unique to the second device,
The third device obtains identification information of the first base station from the first device, and from the second device based on information unique to the second device, the first base station Obtaining operation information of the second base station corresponding to the identification information of the station, and setting the third device as the second base station based on the operation information of the second base station A communication system characterized by the above. A fourth device for assigning an address to the device;
The third device receives an address assignment from the fourth device, uses the address as a source address, and uses the address of the second device included in information unique to the second device as a destination address. The communication system according to claim 1, wherein the second device is accessed. A fourth device assigning an address to the device;
A fifth device having a correspondence relationship between the name of the device and the address of the device,
The third device receives an address assignment from the fourth device, uses the address as a source address, and from the fifth device, includes the second device included in information unique to the second device. The communication system according to claim 1, wherein an address of the second device corresponding to the name of the device is acquired, and the second device is accessed using the address of the second device as a destination address.   The third device acquires a file name of operation information of the second base station corresponding to the identification information of the first base station from the second device, and based on the file name, acquires the file name of the second base station operation information. The communication system according to claim 1, wherein operation information of the second base station is acquired from the second device.   The second device transmits operation information of the second base station to the third device based on the identification information of the first base station sent from the third device. The communication system according to any one of claims 1 to 3.

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