JP5105942B2 - ONU automatic registration method - Google Patents

Description

  The present invention relates to an ONU automatic for performing connection registration of an ONU (Optical Network Unit) in a transmission system using a PON system such as GE-PON (Gigabit Ethernet (registered trademark) -Passive Optical Network). It relates to the registration method.

  As is well known, the PON system does not perform optical-electrical conversion in a transmission system from a station to a user, and uses an optical splitter that is a low-cost passive element to branch an optical signal into a plurality of users. Since an economical network that can share a core optical fiber can be configured, FTTH (Fiber To The Home) has been realized that uses an optical connection to the Internet. In addition, GE-PON can realize transmission speed of 1Gbps on public line network and can apply Ethernet Ethernet (registered trademark) that has been used in LAN to send and receive Ethernet (registered trademark) frames as they are from telephone stations to homes. Has been standardized, the access service by the GE-PON system, which is faster and more economical, has started in 2004 and is rapidly spreading. As a result, commercial services utilizing high speed such as high-quality IP video transmission, IP telephones, and videophones have become possible.

FIG. 1 is a configuration diagram showing a PON system and an ONU automatic registration function.
The GE-PON system includes an OLT (Optical Line Terminal) 2 serving as an intra-station device, an ONU (Optical Network Unit) 1 installed in a user's home, and an OLT-ONU. The optical fiber 6 of the transmission line to be connected, the optical splitter 4 installed between the OLT 2 and the plurality of ONUs 1 are configured. The ONU 1 is connected directly to a user terminal 8 such as a personal computer via a UNI (User Network Interface) 7 or via a VDSL (Very High Bit Rate Digital Subscriber Line). Further, the ONU 1 includes a child ID input means 13 such as a rotary switch for inputting a child ID number used for automatic registration by the installer. The OLT 2 is connected to a higher level network (such as the Internet) 10 and is connected to a control terminal 5 that performs ON / OFF setting of an automatic registration function.
The outline of the general operation will be described. The ONU 1 converts the optical signal from the OLT 2 into an electric signal and gives it to the user terminal 8, and also converts the electric signal from the user terminal 8 into an optical signal and transfers it to the OLT 2. On the other hand, the OLT 2 transfers the optical signal from the ONU 1 to the upper network, transfers the signal from the upper network to the ONU 1, and monitors the PON section and the ONU 1.

Next, authentication / registration when an ONU is connected to a PON and used will be described.
The OLT 2 automatically registers the MAC address of the ONU in the ONU authentication database 24 when the ONU 1 starts communication. Further, the operator uses the control terminal 5 to change or delete the ONU authentication database 24 and set the automatic registration function ON / OFF. The conventional ONU authentication database 24 has a data configuration that stores child ID numbers in association with MAC addresses. Note that the automatic registration function is set to “invalid” in the case of increasing security, but here, it is assumed that automatic registration is performed, and therefore, it will be described as being set to “valid”.

The sequence of the conventional ONU automatic registration method shown in FIG. 5 will be described.
When the ONU 1 is linked up to the OLT 2, the OLT 2 requests the ONU 1 to acquire the child ID number and the MAC address, and determines whether or not the MAC address acquired from the ONU 1 already exists in the ONU authentication database 24 (step ST11). ). When the ONU 1 does not have the MAC address in the ONU authentication database 24, for example, when the ONU 1 is linked up for the first time, the OLT 2 determines the normality of the child ID number acquired this time (having a value within a predetermined range) and other It is checked whether there is no duplication with the ONU child ID number (step ST12). When the child ID number is normal and there is no duplication, the child ID number and MAC address of the ONU are written in the ONU authentication database 24 to complete network connection registration (step ST13), and the UNI port of the ONU 1 is connected. To start. If the child ID number is invalid in step ST12, the UNI port of the ONU 1 is closed to make it non-conductive.
When the ONU 1 is linked up after the second time, the ONU authentication database 24 already has the information of the ONU 1 in the determination of step ST11. Therefore, the OLT 2 uses the MAC address of the ONU 1 as a key. The child ID number registered in 24 is read out, and collation processing with the child ID number acquired from the ONU 1 is performed (step ST14). If both child ID numbers match, the UNI port is opened. If they do not match, the UNI port is closed.

JP 2002-223227 A

In the PON system, the conventional ONU automatic registration method generates an ONU authentication database by using default parameter values and performs registration as described above. In such a system, when implementing an application that requires the location of the equipment, such as a fixed-line telephone service in an IP telephone service, VLAN settings for connecting individual ONUs to separate VLANs (Virtual LANs) It may be necessary to set specific parameters such as Since the ONU authentication database is managed using the MAC address unique to the ONU as a key, unless automatic registration is completed and the MAC address of the terminal to be used is determined, bandwidth allocation and VLAN setting are performed for each ONU. Certain parameter settings such as could not be made. In addition, the setting work for that purpose has to be performed by the operator on the OLT side every time the ONU is installed.
In addition, although there exists a process using a temporary MAC address in this invention demonstrated below, the technique about temporarily registering a MAC address in automatic registration is described in patent document 1. FIG. However, the technology, when the MAC address of the newly connected terminal is not registered, operates a DHCP (Dynamic Host Configuration Protocol) server, completes the connection after completing the connection by temporarily registering the MAC address. It is not a suggestion that the specific parameter setting can be automatically set for each ONU other than the normal network connection registration process when the ONU is connected.

  The present invention has been made to solve the above-described problems, and at the time of automatic registration of a normal network connection of an ONU, it is possible to simultaneously set a specific parameter such as a VLAN setting for each ONU. An object of the present invention is to obtain an ONU automatic registration method for a PON system.

The ONU automatic registration method according to the present invention is an ONU automatic registration method in which, when an ONU is linked up to an OLT of a transmission system using the PON method, the OLT performs an ONU authentication / registration process based on an ONU authentication database. The ONU authentication database has a data structure for storing a child ID number, a MAC address of the ONU, and specific parameters corresponding to each ONU, and the temporary MAC address corresponding to an arbitrary child ID number is stored in the ONU authentication database. The specific parameters are written in advance, the new ONU is linked up by inputting the child ID number in the ONU authentication database, and the OLT uses the new ONU in the ONU authentication database during the ONU authentication / registration process. There is a temporary MAC address for the entered child ID number Determine to have, but was Unishi by you override the MAC address of the new ONU of regular in the appropriate temporary MAC address in the case that existed.

According to the present invention, a temporary MAC address and a specific parameter corresponding to each ONU are written in advance in the ONU authentication database, and the temporary MAC address is overwritten with the regular MAC address of the new ONU, so that the network during ONU automatic registration of the connection, bandwidth allocation against an individual ONU, it becomes possible to perform simultaneously the specific parameter settings for individual ONU, such as VLAN configuration. Therefore, it is not necessary to manually perform a specific parameter setting process after the ONU automatic registration, and the installation work can be made efficient.

Embodiment 1 FIG.
FIG. 3 is an example of the ONU authentication database 240 held by the OLT 2 according to the first embodiment of the present invention. The ONU authentication database 240 stores specific parameters such as bandwidth allocation (maximum value, minimum value), VLAN settings, and the like, corresponding to the child ID number and corresponding to the ONU MAC address and each ONU. It has a data structure. For example, the MAC address for the child ID number “2” is all “f” (hereinafter referred to as “temporary MAC address”), but this is manually written in advance in the ONU authentication database 240 on the OLT 2 side and temporarily registered. . As will be described below, a specific parameter setting is assigned to the ONU by overwriting the temporary MAC address with the regular MAC address of the ONU specified by the child ID number. Other specific parameters set for each ONU include a delay class, a MAC address learning limit number, auto-negotiation, and the like.

FIG. 2 is a sequence diagram showing the operation of ONU authentication / registration processing in the GE-PON system according to Embodiment 1 of the present invention. Hereinafter, the ONU automatic registration method according to the first embodiment will be described.
When ONU 1 is linked up to OLT 2, OLT 2 requests ONU 1 to obtain the MAC address along with the child ID number, and determines whether the child ID number and MAC address obtained from ONU 1 already exist in ONU authentication database 240. (Step ST21). In this case, the acquired child ID number and MAC address are compared with the child ID number and MAC address managed on the ONU authentication database 24. Regardless of the value of the address, only the child ID number and the MAC address are registered. If the ONU authentication database 24 has neither the MAC address nor the child ID number, for example, when the ONU 1 is linked up for the first time, there is no duplication with the normality of the child ID number acquired this time and the child ID numbers of other ONUs. (Step ST22). If the child ID number is normal and there is no duplication, the child ID number and MAC address of the ONU are written in the ONU authentication database 240 to complete normal network connection registration (step ST23), and the UNI port of the ONU 1 The continuity of is started. In step ST22, if the child ID number is invalid, the UNI port of the ONU 1 is closed to make it non-conductive. The above operation is almost the same as the conventional method.

  On the other hand, if it is determined in step ST21 that the MAC address already exists in the ONU authentication database 240 corresponding to the child ID number acquired from the ONU 1, the MAC address is applied to the service of the current GE-PON system. Or a temporary MAC address (for example, all “f” in FIG. 3) registered in advance in the ONU authentication database 240 in order to preset a specific parameter (step ST24). In the case of the MAC address applied to the current service, the OLT 2 collates the acquirer ID number corresponding to the MAC address with the ONU authentication database 240 (step ST25). When there is a child ID number that matches the acquired child ID number in the ONU authentication database 240, the UNI port is opened and signal conduction is permitted. If the matching child ID number is not found in the ONU authentication database 240, the UNI port is closed and signal conduction is not permitted.

  On the other hand, if it is determined in step ST24 that the MAC address existing in the ONU authentication database 240 is a temporary MAC address registered for presetting a specific parameter (for example, All “f”), the OLT 2 The child ID number corresponding to the MAC address is checked against the ONU authentication database 240 (step ST26). Note that when a specific parameter is set for the ONU 1, the ONU connection contractor inputs a child ID number corresponding to the temporary MAC address temporarily registered in the ONU authentication database 240 when connecting the ONU 1. Will do. Therefore, when the ONU authentication database 240 has a child ID number that matches the acquired child ID number, the MAC address (current service) acquired from the ONU 1 as the temporary MAC address of the ONU authentication database 240 using the child ID number as a key. By overwriting the regular MAC address applied to), specific parameter setting and normal network connection registration are completed (step ST27), and the UNI port is opened to start conduction. If the matching child ID number is not found in the ONU authentication database 240 in step ST26, the UNI port is closed to disable the conduction.

  As described above, according to the first embodiment, the ONU authentication database is configured as a data structure that stores child ID numbers, ONU MAC addresses, and specific parameters corresponding to individual ONUs. A temporary MAC address (for example, all “f”) and a specific parameter are written in advance in correspondence with an arbitrary child ID number, and a new ONU is linked up by inputting the child ID number in the ONU authentication database. In the ONU authentication / registration process, the OLT checks whether there is a temporary MAC address for the child ID number input by the new ONU in the ONU authentication database. Correspond to the new ONU by overwriting the normal MAC address of the new ONU in the address And to perform a constant parameter settings. Therefore, it is possible to simultaneously set specific parameters for individual ONUs at the time of network connection ONU automatic registration. Conventionally, since the ONU authentication database is managed using the MAC address assigned to each ONU as a key, specific parameters are set for the MAC address. Therefore, it was not possible to set for ONUs having different MAC addresses instead. In other words, in the present invention, the ONU authentication database is managed using the child ID number as a key. ONU registration and specific parameter setting) can be performed, and it is not necessary for the operator to change the settings one by one on the OLT side after installing the ONU, making installation work more efficient and shortening the time to start the service. Is possible. Even in the case of an ONU failure, etc., if the MAC address of the ONU authentication database is set to the temporary registration state (all “f”), it can be exchanged with any ONU, so that maintainability can be improved. It becomes.

Embodiment 2. FIG.
In the case of the first embodiment, a temporary MAC address is registered in advance in a specific parameter stored in the ONU authentication database 240, and a specific parameter is set by overwriting the formal MAC address during the ONU authentication / registration process. In the case of the second embodiment, the OLT 2 has a storage area (this is referred to as a “parameter storage area”) different from the ONU authentication database, and has a child ID in advance. A specific parameter is stored corresponding to the number, and the specific parameter is set by extracting the specific parameter and registering it together in the ONU authentication database at the time of ONU automatic registration. Note that the ONU authentication database in the second embodiment also has a data structure that manages using the child ID number as a key in the same manner as the ONU authentication database 240 in the first embodiment. Since the parameter storage area is used together, a temporary MAC address is not temporarily registered in advance.
FIG. 4 is a sequence diagram showing an operation of authentication / registration processing according to Embodiment 2 of the present invention. In the second embodiment, new steps ST15 and ST16 are provided for the conventional sequence in FIG.

Next, the operation will be described.
When ONU1 is linked up to OLT2, OLT2 requests ONU1 to obtain the child ID number and MAC address, and determines whether the child ID number and MAC address obtained from ONU1 already exist in the ONU authentication database. (Step ST11). If there is no MAC address in the ONU authentication database, the OLT 2 checks whether the child ID number acquired this time is normal and does not overlap with the child ID numbers of other ONUs (step ST12). If the child ID number is normal and there is no duplication, the parameter storage area is searched and a specific parameter corresponding to the child ID number is selected (step ST15). When there is no corresponding parameter, the child ID number and MAC address of the ONU 1 are written in the ONU authentication database to complete normal network connection registration (step ST13). If there is a corresponding parameter in the parameter storage area, the parameter is extracted and written in the ONU authentication database in association with the child ID number and MAC address of the ONU 1, and the specific parameter setting and normal network connection registration are performed. Completion (step ST16). When the registration of either step ST13 or ST16 is completed, the conduction of the UNI port of the registered ONU 1 is started. If the child ID number is invalid in step ST12, the UNI port of the ONU 1 is closed to make it non-conductive.

  When the ONU 1 is linked up after the second time, it is the same as described with reference to FIG. 5. In the determination of step ST11, the ONU authentication database already contains information about the ONU 1, so the OLT 2 Using the MAC address as a key, the child ID number registered in the ONU authentication database 24 is read out, and collation processing with the child ID number acquired from the ONU 1 is performed (step ST14). If both child ID numbers match, the UNI port is opened. If they do not match, the UNI port is closed.

  As described above, according to the second embodiment, the ONU authentication database is configured as a data structure storing a child ID number, a MAC address of the ONU, and specific parameters corresponding to each ONU, and the OLT In addition to the ONU authentication database, it has a parameter storage area for storing a specific parameter corresponding to an arbitrary child ID number in advance. The new ONU is linked up by inputting the child ID number in the parameter storage area. During the ONU authentication / registration process, the OLT extracts a specific parameter corresponding to the child ID number input by the new ONU from the parameter storage area and writes it in the ONU authentication database together with the MAC address of the new ONU. The specific parameter setting corresponding to the new ONU is performed. Therefore, it is possible to simultaneously set specific parameters for individual ONUs at the time of network connection ONU automatic registration. In addition, since the ONU authentication database can manage specific parameters using the child ID number as a key, for example, when an ONU is replaced due to a failure, if the same child ID number is designated by the ONU, the specific parameter is set. Therefore, it is possible to improve maintenance operability.

It is a block diagram which shows schematic structure of a GE-PON system. It is a sequence diagram which shows the operation | movement of the authentication and registration process which concerns on Embodiment 1 of this invention. It is explanatory drawing which illustrates the data structure of the authentication database which concerns on Embodiment 1 of this invention. It is a sequence diagram which shows the operation | movement of the authentication and registration process which concerns on Embodiment 2 of this invention. It is a sequence diagram which shows the operation | movement of the conventional authentication and registration process.

Explanation of symbols

  1 ONU, 2 OLT, 13 child ID input means, 5 control terminal, 6 optical fiber, 7 UNI, 8 user terminal, 10 upper network, 240 ONU authentication database.

Claims (1)

In the ONU automatic registration method in which the OLT performs the ONU authentication / registration process based on the ONU authentication database when the ONU is linked up to the OLT of the transmission system using the PON method
The ONU authentication database is configured as a data structure for storing child ID numbers, ONU MAC addresses, and specific parameters corresponding to individual ONUs;
In the ONU authentication database, a temporary MAC address and a specific parameter are written in advance in correspondence with an arbitrary child ID number,
Link the new ONU by entering the child ID number in the ONU authentication database,
During the ONU authentication / registration process, the OLT checks whether a temporary MAC address corresponding to the child ID number input by the new ONU exists in the ONU authentication database. ONU automatic registration wherein the override child the MAC address of the new ONU regular in the address.

Images