JP7101651B2 - Slave equipment and communication system - Google Patents

Description

The present invention relates to a slave station device and a communication system.

The Ethernet® network is a communication network compliant with the IEEE (Institute of Electrical and Electronics Engineers) 802 standard. A 48-bit MAC (Media Access Control) address is assigned as a unique address to the communication device constituting the Ethernet network at the time of shipment from the factory.

The MAC address includes a product vendor code (OUI: Organizationally Unique Identifier) that indicates the vendor of the communication device, a code that the vendor assigns to each communication device individually, and a code that uniquely indicates each communication device, and I / G (Individual / Group). It is composed of a bit and a U / L (Universal / Local) bit.

The I / G bit indicates whether the MAC address is a unicast address or a multicast address. Specifically, when the I / G bit is 0, a unicast address is indicated, and when the I / G bit is 1, a multicast address is indicated.

Further, the U / L bit indicates whether the MAC address is a universal address or a local address. Specifically, when the U / L bit is 0, a universal address is indicated, and when the U / L bit is 1, a local address is indicated. The universal address is also called a global address, but in this specification, the expression "universal address" will be used for explanation. Further, in the following description, a MAC address having a U / L bit of 0 is referred to as a universal MAC address, and a MAC address having a U / L bit of 1 is referred to as a local MAC address. The universal MAC address is used when it is necessary to assign a MAC address that is guaranteed to be unique in the world to a communication device. The local MAC address can be freely generated and used by a vendor or the like when it is not necessary to ensure uniqueness in the world, for example, when a communication device is used in a limited network. However, the local MAC address needs to be unique within the limited network.

Patent Document 1 describes an invention of a gateway device that generates and uses a local MAC address. The invention described in Patent Document 1 integrates a plurality of functions previously realized individually by a plurality of gateway devices and realizes them with one gateway device. The gateway device described in Patent Document 1 generates a plurality of local MAC addresses used in each of the above-mentioned plurality of functions based on one universal MAC address assigned in advance.

Japanese Patent No. 5279996

The gateway device described in Patent Document 1 changes the bit of the third octet of the OUI to generate a local MAC address. Therefore, it may not be possible to ensure uniqueness within a limited network. That is, if the bits of the area other than the third octet of OUI are the same and there are multiple gateway devices of different vendors in the network, the same local MAC address may be generated by two or more gateway devices. There is.

The present invention has been made in view of the above, and an object of the present invention is to obtain a slave station device capable of generating a MAC address in which uniqueness is ensured to the extent that realization of uniqueness is required. ..

In order to solve the above-mentioned problems and achieve the object, the present invention makes it possible to communicate with the master station device by individually registering each of a plurality of channels in the master station device constituting the communication system. A slave station device that uses a unique address within a limited network when transitioning and registering each of a plurality of channels with the master station device, and is a first self-assigned device. It includes a unique address holding unit that holds an address, and an address generating unit that generates a second address that is unique within a limited network based on the first address. The first address contains a bit string indicating the vendor of the slave station device. The address generator changes some bits of the bit string determined based on the address assigned in advance to each slave station device that allows connection to the master station device forming a limited network. Generate a second address using a program.

The slave station device according to the present invention has an effect that it can generate a MAC address in which uniqueness is ensured within a range in which realization of uniqueness is required.

Diagram showing the configuration of MAC address The figure which shows the structural example of the communication system which concerns on Embodiment 1 of this invention. The figure which shows an example of the functional block composition of OLT which concerns on Embodiment 1. The figure which shows an example of the functional block composition of ONU which concerns on Embodiment 1. The figure which shows an example of the functional block composition of the management apparatus which concerns on Embodiment 1. A sequence diagram showing an example of an operation of registering the ONU according to the first embodiment in the OLT. The figure which shows the structural example of the communication system which concerns on Embodiment 2 of this invention. A sequence diagram showing an example of an operation of registering the ONU according to the second embodiment in the OLT. The figure which shows an example of the range which can guarantee the uniqueness of a local MAC address in the communication system which concerns on Embodiments 1 and 2. The figure which shows an example of the hardware which realizes OLT

Hereinafter, the slave station apparatus and the communication system according to the embodiment of the present invention will be described in detail with reference to the drawings. The present invention is not limited to this embodiment.

Embodiment 1.
First, the configuration of the MAC address handled in this embodiment and each of the embodiments described later will be briefly described. FIG. 1 is a diagram showing a configuration of a MAC address.

As shown in FIG. 1, the MAC address is composed of octet 1 to octet 6. Further, the least significant bit of the octet 6 is bit0, and the most significant bit is bit7. The least significant bit of octet 1 is bit40, and the most significant bit is bit47. The bit 41 included in the octet 1 corresponds to the above-mentioned U / L bit, and the bit 40 corresponds to the above-mentioned I / G bit. The 22 bits of bit24 to bit39 and bit42 to bit47 correspond to the above-mentioned OUI. The 24 bits from bit0 to bit23 are used by the vendor to create a code uniquely indicating the communication device. In this specification and FIG. 1, the MAC addresses bit0 to bit23 are expressed as vendor-created codes.

FIG. 2 is a diagram showing a configuration example of a passive optical network (PON) system, which is a communication system according to the first embodiment of the present invention.

The PON system 100 shown in FIG. 2 is a SIEPON (Service Interoperability in Ethernet PON) system defined by IEEE 1904.1.

As shown in FIG. 2, the PON system 100 includes an OLT (Optical Line Terminal) 1 ₁ to 1 _n , which is a master station device. Each of OLT _{1 1} to 1 _n is provided with a plurality of PON ports that are interfaces with an ONU (Optical Network Unit) that is a slave station device. In FIG. 2, a plurality of PON ports included in the OLT _{1 1} are PON ports 10 ₁ to 10 _m , and a plurality of PON ports included in the OLT 1 _n are PON ports 10 _n1 to 10 _nm . One or more ONUs are connected to each PON port via the optical coupler 51 and the optical fiber 52. In FIG. 2, the ONU connected to the PON port 10 ₁ provided in the OLT _{1 1} is referred to as the ONU 2 ₁₁ , and the ONU connected to the PON port 10 _m is referred to as the ONU 2 _{1 m} . The ONU connected to the PON port 10 _nm provided in the OLT1 _1n is defined as the ONU 2 _nm .

In the following description, when it is not necessary to distinguish OLT _{1 1 to} 1 _n , such as explaining the matters common to OLT 1 ₁ to 1 _n , each of OLT 1 1 to 1 _n is described as OLT 1. Similarly, when it is not necessary to distinguish between ONU2 ₁₁ , 21 _m and 2 _nm , ONU2 ₁₁ , 21 _m and 2 _nm are referred to as ONU2, respectively.

As shown in FIG. 2, the PON system 100 further includes a management device 3. The management device 3 includes a database holding unit 31 that holds the MAC address database 311 and a program holding unit 32 that holds the MAC address generation program 321. The MAC address database 311 and the MAC address generation program 321 are created by an operator (not shown). The MAC address database 311 held by the database holding unit 31 and the MAC address generating program 321 held by the program holding unit 32 can be updated by the operator at any timing.

In the MAC address database 311, the MAC address generation program 321 is based on the MAC address pre-assigned to ONU2 that is permitted to be registered in OLT1 and the MAC address that is pre-assigned to ONU2 that is permitted to be registered in OLT1. The generated local MAC address is registered. The MAC address database 311 is passed from the management device 3 to the OLT1 in response to a request from the OLT1.

The MAC address generation program 321 is a program for ONU2 to generate a local MAC address. The MAC address generation program 321 is passed from the management device 3 to the OLT1 in response to a request from the OLT1, and further is passed from the OLT1 to the ONU2.

OLT1 and ONU2 communicate using a plurality of channels. The ONU2 is in a state where it can communicate with the OLT1 by performing the registration process on the OLT1, but the registration process needs to be performed for each channel. That is, the ONU2 communicates with the OLT1 using the channel for which the registration process has been normally completed. In the example shown in FIG. 2, CH # 1 to CH # 4 are used to enable communication between OLT 1 _n and ONU 2 _nm , but the number of channels used is not limited to this. On the other hand, ONU2 _nm is in a state where only one factory-shipped MAC address, which is a universal MAC address, is assigned at the time of shipment from the factory. Therefore, ONU2 _nm generates a local MAC address based on the factory-shipped MAC address in order to communicate with OLT1 _n using a plurality of channels, and performs registration processing in each channel. The MAC address used in the registration process in each channel is the factory default MAC address assigned to ONU 2 _nm and the local MAC address generated by the MAC address generator 321 based on the factory default MAC address. be. FIG. 2 shows an example in which the factory-shipped MAC address is used in the registration process for using CH # 1 and the local MAC address is used in the registration process for using CH # 2 to CH # 4. .. Although ONU2 _nm has been described, the same applies to other ONU2 such as ONU2 ₁₁ and ONU2 _{1 m} . Although one or more communication terminals are connected to each ONU2, the description of the communication terminal is omitted in FIG.

Here, the MAC address generation program 321 will be described. The MAC address generation program 321 is created by an operator (not shown). The operator verifies the OUI and programs the MAC address generation program 321 so that the uniqueness of the locus MAC address assigned to each channel of ONU2 is guaranteed. When the maximum number of channels that can be used for communication between one ONU2 and OLT1 (hereinafter referred to as the maximum number of channels of ONU2) is 2 to the Xth power or less, the operator uses Xbit out of 22 bits indicating OUI. Create a program to generate a local MAC address by rewriting. The operator determines which bit the Xbit to be rewritten should be based on the OUI constituting the factory-shipped MAC address of each ONU2 that is permitted to connect to the OLT1. The operator compares the OUIs of the factory-shipped MAC addresses of each ONU2 that are allowed to connect to the OLT1, and selects and determines the bit at the position where the OUIs of different vendors do not become the same even if the rewriting is performed. For example, if there are three vendors of ONU2 that allow connection to OLT1, the operator determines the Xbit so that the UI indicating each of the three vendors is maintained in a different state even after rewriting. The operator, for example, programs the MAC address generation program 321 as follows.

An example of a MAC address generation program 321 capable of distinguishing between OUI = 00-06-F5 and OUI = 00-06-F7 when the maximum number of channels of ONU2 = 4, that is, X = 2 is shown. OUI = 00-06-F5 and OUI = 00-06-F7 correspond to the OUI of the factory-shipped MAC address of ONU2 which is permitted to be registered in OLT1.

In this case, the operator overwrites the bit45 and bit44 of the OUI of the factory-shipped MAC address, which is the source of the local MAC address, with 00/01/10/11 indicating the channel number, and further, the factory-shipped MAC address. Program the MAC address generation program 321 that overwrites the U / L bit and the I / G bit of the above with U / L bit = 1 and I / G bit = 0. According to this MAC address generation program 321, the following unique local MAC address can be obtained from the factory-shipped MAC address. The factory-shipped MAC addresses here are (1) 00-06-F5- [vendor-created code] and (2) 00-06-F7- [vendor-created code].

Local MAC address obtained from the factory-shipped MAC address in (1) 02-06-F5- [Vendor-created code]
12-06-F5- [Vendor creation code]
22-06-F5-[Vendor creation code]
32-06-F5-[Vendor creation code]
Local MAC address obtained from the factory-shipped MAC address in (2) 02-06-F7- [Vendor-created code]
12-06-F7- [Vendor creation code]
22-06-F7- [Vendor creation code]
32-06-F7- [Vendor creation code]

Here, an example of changing (overwriting) the bit 45 and bit 44 of the OUI is shown, but if the bits (bit 27 to bit 39, bit 42 to bit 47) other than the lower 3 bits (bit 24 to bit 26) of the OUI are used, any 2 bits should be changed. You may. Further, if it is possible to maintain a state in which OUIs of different vendors are not duplicated, more bits than X bits (here, 2 bits) may be changed.

Although the operator decides the Xbit to be changed, the management device 3 may decide it. For example, the management device 3 acquires the information of the maximum number of channels of ONU2 and the information of OUI constituting the factory-shipped MAC address of each ONU2 permitting connection to OLT1 from the operator, and is based on the maximum number of channels. The number X of the bits to be changed is determined, and the bits of each OUI constituting the factory MAC address of each ONU2 that is allowed to connect to OLT1 are compared, and all the ONU2s have the same value. Select the Xbit to be changed from. As a result, the workload of the operator can be reduced.

FIG. 3 is a diagram showing an example of the functional block configuration of the OLT 1 according to the first embodiment. As shown in FIG. 3, the OLT 1 includes a storage unit 11, a registration processing unit 13, a program collation unit 14, and a communication unit 15.

The storage unit 11 includes a database holding unit 12 that receives and holds the MAC address database 311 when it is transmitted from the management device 3. When the registration request is received from the ONU2, the registration processing unit 13 determines whether or not to allow the connection of the requesting ONU2. The program collation unit 14 confirms whether the MAC address generation program 321 held by the ONU 2 is the same as the MAC address generation program 321 held by the program holding unit 32 of the management device 3. The communication unit 15 communicates with the management device 3 and the ONU 2.

FIG. 4 is a diagram showing an example of the functional block configuration of ONU2 according to the first embodiment. As shown in FIG. 4, the ONU 2 includes an address generation unit 21, a program management unit 22, a registration processing unit 23, a storage unit 24, and a communication unit 27.

The storage unit 24 includes a unique address holding unit 25 that holds the universal MAC address assigned to the ONU 2, and a program holding unit 26 that receives and holds the MAC address generation program 321 when it is transmitted from the management device 3. including. The universal MAC address held by the unique address holding unit 25 corresponds to the above-mentioned factory-shipped MAC address. The universal MAC address held by the unique address holding unit 25 is a first address assigned in advance to ONU2.

The address generation unit 21 uses the MAC address generation program 321 held by the program holding unit 26, and uses the local MAC address based on the factory-shipped MAC address which is the universal MAC address held by the unique address holding unit 25. To generate. The local MAC address generated by the address generator 21 is a second address whose uniqueness is ensured within the limited network. Further, the MAC address generation program 321 is an address generation program that changes a part of the bits in the bit string indicating the UI of the first address. The program management unit 22 manages various information related to the MAC address generation program 321 held by the program holding unit 26, for example, information such as a version and a creation date / time. The registration processing unit 23 executes a registration process for enabling communication with the OLT 1. The communication unit 27 communicates with the OLT 1 and the communication terminal (not described in FIG. 2).

FIG. 5 is a diagram showing an example of a functional block configuration of the management device 3 according to the first embodiment. As shown in FIG. 5, the management device 3 includes a storage unit 30, a database creation unit 33, a program creation unit 34, an operation reception unit 35, and a communication unit 36.

The storage unit 30 includes a database holding unit 31 and a program holding unit 32. The database holding unit 31 and the program holding unit 32 are the same as the database holding unit 31 and the program holding unit 32 shown in FIG.

The database creation unit 33 creates the MAC address database 311 held by the database holding unit 31. The program creation unit 34 creates the MAC address generation program 321 held by the program holding unit 32. The operation reception unit 35 receives various operations by the operator. The operations accepted by the operation reception unit 35 include a creation operation and an editing operation of the MAC address database 311 and a creation operation and an editing operation of the MAC address generation program 321. The communication unit 36 communicates with the OLT1.

Next, the operations of the OLT 1, ONU 2 and the management device 3 constituting the PON system 100, specifically, the operation in which the ONU 2 registers with the OLT 1 and transitions to a state in which communication with the OLT 1 is possible will be described.

FIG. 6 is a sequence diagram showing an example of an operation of registering ONU2 according to the first embodiment in OLT1. It is assumed that ONU2 communicates with OLT1 using a total of 4 channels, and registration has not been completed for any of the channels. Each of the four channels has a first channel that performs registration processing using the factory-shipped MAC address and a second channel that performs registration processing using the local MAC address generated based on the factory-shipped MAC address. Channels # 1 to # 3. It is assumed that ONU2 has not completed the generation of the local MAC address.

First, the operator creates a MAC address generation program 321 and saves it in the management device 3 (steps S11 and S12), and further, the factory-shipped MAC address of ONU2 that permits registration and the MAC address of ONU2. The work (steps S13, S14) of writing the local MAC address created by using the generation program 321 to the MAC address database 311 of the management device 3 is performed.

In step S11 above, specifically, the operator finds the minimum number of bits X that can indicate the maximum number of channels of ONU2 (the sum of the number of first channel and the number of second channels), and the vendor of ONU2. The degeneracy method of the OUI showing the above is determined, and the MAC address generation program 321 as described above is created. In the determination of the OUI degeneration method, it is determined which bit (total X bits) of the 22 bits (see FIG. 1) indicating the OUI of the factory-shipped MAC address of ONU2 is rewritten to generate the local MAC address. The operator determines the X bit at the position where OUI duplication does not occur even if the rewriting is performed, as the bit to be rewritten when the local MAC address is generated.

Next, the OLT 1 acquires and stores the MAC address database 311 from the management device 3 (steps S15 and S16).

The ONU2 in the unregistered state first transmits a registration request for the first channel to the OLT1 using the retained factory MAC address (step S17). The registration request for the first channel includes the factory MAC address. Upon receiving the registration request for the first channel, the OLT 1 performs a registration process for the first channel of the ONU2 (step S18). Specifically, the OLT1 collates the MAC address (factory default MAC address) included in the registration request with the held MAC address database 311, and the factory default MAC address is registered in the MAC address database 311. If so, the registration process of the first channel is performed. If the factory-shipped MAC address is not registered in the MAC address database 311, the operation ends without performing the registration process.

When the registration process of the first channel is completed, the OLT 1 transmits the registration permission of the first channel to the ONU2 (step S19). Upon receiving the registration permission of the first channel, the ONU2 performs a registration process (step S20) and shifts the first channel to the registration state. Since the registration process performed by each of OLT1 and ONU2 is the same as the registration process performed in a general SIEPON system, the description thereof will be omitted.

Next, the OLT1 confirms the MAC address generation program 321 held by the ONU2 that has registered the first channel (steps S21 and S22). Specifically, the OLT1 sends a MAC address generation program confirmation to the ONU2 to make an inquiry, and the ONU2 notifies the OLT1 of the information of the retained MAC address generation program 321 in the MAC address generation program response. If the ONU2 does not hold the MAC address generation program 321, the ONU2 notifies the OLT1 to that effect.

Next, the OLT 1 acquires the MAC address generation program 321 held by the management device 3 from the management device 3 (step S23). Then, when the ONU2 does not have the same MAC address generation program 321 as the MAC address generation program 321 acquired from the management device 3, the OLT1 downloads the MAC address generation program 321 acquired from the management device 3 to the ONU2 (step). S24). The OLT 1 determines whether or not to download the MAC address generation program 321 to the ONU2 based on the information acquired from the ONU2 in step S22 and the MAC address generation program 321 acquired from the management device 3. The OLT 1 does not execute step S24 when the ONU2 holds the same MAC address generation program 321 as the MAC address generation program 321 acquired from the management device 3. In order to reduce the number of accesses to the management device 3, the OLT 1 may cache the MAC address generation program 321 acquired from the management device 3.

The ONU2 saves the MAC address generation program 321 when it is sent from the OLT1, and uses the local MACs on the second channels # 1 to # 3 based on the MAC address generation program 321 and the factory default MAC address. Generate addresses # 1 to # 3 (step S25). The ONU2 then assigns the generated local MAC addresses # 1 to # 3 to the second channels # 1 to # 3 (step S26), and further uses the local MAC address # 1 to use the local MAC address # 1 for the second channel # 1. The registration request of is transmitted to OLT1 (step S27). The OLT 1 performs a registration process for the second channel # 1 of the ONU2 (step S28), and if registration is permitted, transmits the registration permission for the second channel # 1 to the ONU2 (step S29). The ONU2 that has received the registration permission of the second channel # 1 performs a registration process (step S30), and transitions the second channel # 1 to the registration state.

The operation of registering the second channel # 1 shown in steps S27 to S30 is the same as the operation of registering the first channel shown in steps S17 to S20.

After transitioning the second channel # 1 to the registered state, ONU2 and OLT1 execute the same processing for the second channels # 2 and # 3 to transition to the registered state (steps S31 to S38). .. This completes the registration of all channels of ONU2.

As described above, in the PON system 100 according to the present embodiment, the ONU2 is one of a plurality of channels used in the communication when performing the registration process for enabling the communication with the OLT1. Use the universal MAC address (factory default MAC address) that holds the channel registration in advance, and then use the MAC address generation program 321 received from OLT1 to part of the universal MAC address OUI. Rewrite the bit of to generate the required number of local MAC addresses. Then, ONU2 registers the second channel different from the first channel among the plurality of channels used for communication by using the generated local MAC address. The bit to be rewritten using the MAC address generation program 321 is based on the OUI of the universal MAC address assigned in advance to each ONU2 that allows connection to OLT1, so that the OUIs of different vendors will be in different states even after rewriting. Will be decided.

According to this embodiment, ONU2 can generate a local MAC address that can guarantee uniqueness within a limited network. The limited network here is a network formed by each OLT1 and each ONU2.

Embodiment 2.
FIG. 7 is a diagram showing a configuration example of a PON system 100a, which is a communication system according to the second embodiment of the present invention. In FIG. 7, the same components as those of the PON system 100 according to the first embodiment are designated by the same reference numerals as those of the PON system 100. In this embodiment, components different from those in the first embodiment will be described.

The PON system 100a includes the OLT _{1 1} to 1 _n , ONU _{2 11} , 2 _{1 m} , 2 _nm and the management device 3 of the PON system 100 according to the first embodiment, _respectively . This is a configuration in which _nm and the management device 3a are replaced, and a registration server 4 is added. When it is not necessary to distinguish _OLT 1a ₁ to 1 an, each of _OLT 1a ₁ to 1 an is described as OLT 1a. Similarly, when it is not necessary to distinguish between ONU2a ₁₁ , 2a _1m and 2a _nm , ONU2a ₁₁ , 2a _1m and 2a _nm are referred to as ONU2a, respectively.

The functional block configuration of OLT1a is the same as that of OLT1 (see FIG. 3). That is, the OLT 1a includes a storage unit 11, a registration processing unit 13, a program collation unit 14, and a communication unit 15. However, the storage unit 11 does not include the database holding unit 12. Further, the operation of the registration processing unit 13 of the OLT 1a is partially different from the operation of the registration processing unit 13 of the OLT 1.

The functional block configuration of ONU2a is the same as that of ONU2 (see FIG. 4). That is, the ONU2a includes an address generation unit 21, a program management unit 22, a registration processing unit 23, a storage unit 24, and a communication unit 27. However, the operations of the address generation unit 21 and the registration processing unit 23 of the ONU2a are partially different from the operations of the address generation unit 21 and the registration processing unit 23 of the ONU2. The ONU2 according to the first embodiment is registered in the OLT1 by using the factory-shipped MAC address and the local MAC address generated by the address generation unit 21, but the ONU2a does not use the factory-shipped MAC address. The local MAC address generated by the address generation unit 21 is used for registration in OLT1a.

The functional block configuration of the management device 3a is the same as that of the management device 3 (see FIG. 5). That is, the management device 3a includes a storage unit 30, a database creation unit 33, a program creation unit 34, an operation reception unit 35, and a communication unit 36. However, the programs held by the program holding unit 32 included in the storage unit 30 are different. In the management device 3 according to the first embodiment, the program holding unit 32 included in the storage unit 30 holds the MAC address generation program 321. On the other hand, in the management device 3a according to the present embodiment, the program holding unit 32 included in the storage unit 30 holds the operation program of the ONU2a (corresponding to the old ONU program 331A or the new ONU program 331B shown in FIG. 7). do. The operation program of ONU2a held by the program holding unit 32 includes a MAC address generation program similar to the MAC address generation program 321 described in the first embodiment. The operation program of ONU2a is passed from the management device 3a to OLT1a, and further from OLT1a to ONU2a.

The registration server 4 includes a MAC address database 41. The MAC address database 41 is a database similar to the MAC address database 311 passed from the management device 3 to the OLT 1 in the first embodiment.

Next, the operations of the OLT1a, ONU2a, the management device 3a, and the registration server 4 constituting the PON system 100a, specifically, the operation of the ONU2a registering with the OLT1a and transitioning to a state in which communication with the OLT1a is possible will be described. do.

FIG. 8 is a sequence diagram showing an example of an operation of registering ONU2a according to the second embodiment in OLT1a. Similar to the first embodiment described above, the ONU2a communicates with the OLT1a using a total of four channels. When registering each of the 4 channels to OLT1a for the first time, the registration process is performed using the factory-shipped MAC address, and for the second and subsequent registrations, the local MAC address generated based on the factory-shipped MAC address is used. The first channel for registration processing and the second channels # 1 to # 3 for which registration processing is always performed using the local MAC address generated based on the factory-shipped MAC address.

In the example shown in FIG. 8, when the ONU2a has completed the registration of the first channel, the ONU2a operation program (old ONU program 331A) is replaced with a new operation program (new ONU program 331B), and the ONU2a is replaced with the OLT1a. The operation of registering is described. It is assumed that only the first channel operates in the ONU2a that executes the old ONU program 331A, and four channels in total of the first channel and the second channel operate in the ONU2a that executes the new ONU program 331B.

At the time of starting the operation, the old ONU program 331A is stored in the management device 3a (step S51), and the old database (old MAC address database 41) is stored in the registration server 4 (step S52).

First, the operator creates a new ONU program 331B and replaces the old ONU program 331A held by the management device 3a with the new ONU program 331B (steps S53 and S54). The method of creating the MAC address generation program included in the new ONU program 331B is the same as that of the first embodiment.

In step S53 above, the operator creates an ONU program including, for example, a MAC address generation program that distinguishes between OUI = 00-06-F5, OUI = 00-06-F7, and OUI = 10-06-F5. , This is the new ONU program 331B. As an example, the operator overwrites bit37 and bit36 of the OUI of the factory MAC address, which is the source of the local MAC address, with 00/01/10/11 indicating the channel number, and further, the factory MAC address. Create a new ONU program 331B that overwrites the U / L bit and the I / G bit of the above with U / L bit = 1 and I / G bit = 0. In step S54 above, the program holding unit 32 in the storage unit 30 of the management device 3a holds the new ONU program 331B in place of the old ONU program 331A.

The operator further updates the MAC address database 41 by writing the local MAC address generated by the ONU2a to the MAC address database 41 of the registration server 4 using the MAC address generation program included in the new ONU program 331B (step). S55, S56). In the following description, the updated MAC address database 41 of the registration server 4 may be referred to as a new database.

When the update work of the ONU program and the update work of the MAC address database 41 in steps S53 to S56 are completed, the operator gives an instruction to update the ONU program to the OLT1a via the management device 3a (steps S57 and S58).

Upon receiving the ONU program update instruction, the OLT 1a acquires the ONU program (new ONU program 331B) from the management device 3a and stores it in the storage unit 11 (steps S59 and S60).

Next, the OLT1a confirms the ONU program held by the ONU2a (steps S61 and S62). Specifically, the OLT1a sends an ONU program confirmation to the ONU2a to make an inquiry, and the ONU2a notifies the OLT1a of the information of the held ONU program in the ONU program response.

Next, if the ONU2a does not hold the same ONU program as the new ONU program 331B held by the storage unit 11, the OLT1a downloads the new ONU program 331B to the ONU2a (step S63). The OLT1a determines whether or not to download the new ONU program 331B to the ONU2a based on the information acquired from the ONU2a in step S62 and the new ONU program 331B held in the storage unit 11. The OLT1a does not execute step S63 when the ONU2a holds the same ONU program as the new ONU program 331B.

When the new ONU program 331B is sent from the OLT1a, the ONU2a saves the new ONU program 331B (step S64) and restarts the program (step S65). After restarting, the ONU2a operates according to the new ONU program 331B.

The ONU2a then uses the local MAC addresses # 1 to be used in the first channel and the second channels # 1 to # 3, based on the MAC address generation program included in the new ONU program 331B and the factory default MAC address. Generate # 4 (step S66).

The ONU2a then uses the generated local MAC address # 1 to send a registration request for the first channel to the registration server 4 via the OLT1a (step S67).

When the registration server 4 receives the registration request, the registration server 4 performs a collation process of the local MAC address # 1 included in the received registration request, that is, a confirmation process of confirming whether the local MAC address # 1 is registered in the new database (step S68). ). When the local MAC address # 1 is registered in the new database, the registration server 4 transmits the registration permission of the first channel to ONU2a via OLT1a (step S69), and further registers the first channel of ONU2a. Notifies OLT1a that the above has been executed (step S71).

The ONU2a that has received the registration permission of the first channel performs a registration process (step S70), and transitions the first channel to the registration state.

Upon receiving the notification that the registration of the first channel of the ONU2a has been executed, the OLT1a performs the registration process of the first channel of the ONU2a (step S72).

After that, the ONU2a, the OLT1a, and the registration server 4 perform the same processing as in steps S67 to S72 performed for registering the first channel for the second channels # 1 to # 3, and the second channels # 1 to # 3 are performed. Transition # 3 to the registered state (steps S73 to S90). In the process for registering each of the second channels # 1 to # 3, the local MAC addresses # 2 to # 4 are used respectively.

As described above, in the PON system 100a according to the present embodiment, when the OLT1a receives the update instruction of the operation program of the ONU2a from the management device 3a, the OLT1a acquires the new ONU program 331B which is the updated operation program from the management device 3a. And download it to ONU2a. The ONU2a generates a local MAC address by using the updated MAC address generation program included in the downloaded new ONU program 331B, and registers the generated local MAC address in the OLT1a.

According to this embodiment, even if the network configuration changes due to the addition of a vendor of ONU2a that allows connection to OLT1a, ONU2a can guarantee uniqueness within a limited network. A MAC address can be generated.

In the PON system 100a, the entire ONU program is updated, and the updated ONU program is downloaded to ONU2a as a new ONU program 331B. That is, the information indicating which bit of the bit string indicating the UI is changed to generate the local MAC address may be downloaded to the ONU2a. In this case, the address generation unit 21 of ONU2a changes the internal setting so as to change the bit to be changed, which is indicated by the downloaded information, to generate the local MAC address in the bit column indicating the factory-shipped MAC address. ..

Next, the range in which the uniqueness of the local MAC address can be guaranteed when the first embodiment and the second embodiment are applied will be described. FIG. 9 is a diagram showing an example of a range in which the uniqueness of the local MAC address can be guaranteed in the communication system according to the first and second embodiments. In FIG. 9 and the following description, the description of the reference numerals of the OLT, the ONU, and the management device will be omitted.

Here, consider a case where the OLT has m PON ports (m is an integer of 2 or more) and the management device manages n units (n is an integer of 2 or more). For example, an authentication process for determining whether or not the registration server (not shown) described in the second embodiment permits registration for the ONUs under each of the n units OLT # 1 to # n in the figure. In the case of this (the case of the uniqueness guarantee range # 1 shown), it is necessary to use a MAC address generation program that makes the local MAC address unique in all ONUs of the uniqueness guarantee range # 1. In this case, the network formed by the OLT and the ONU included in the uniqueness guarantee range # 1 is a limited network. As another example, in the case where the OLT # 1 targets the ONU under its own control for the above authentication process (the case of the uniqueness guarantee range # 2 shown), the ONU # 1 ₁ to 1 _i , ..., ONU. A MAC address generation program that makes the local MAC addresses of # m ₁ to # m _j unique may be used. In this case, the network formed by the OLT and the ONU included in the uniqueness guarantee range # 2 is a limited network. As yet another example, in the case where the MAC address is used only for the discovery processing of the ONU (the case of the uniqueness guarantee range # 3 shown), the ONUs # ₁ to # 1 _i under the PON port # 1 of the OLT # 1 A MAC address generator that makes the local MAC address unique may be used. In this case, the network formed by the OLT and the ONU included in the uniqueness guarantee range # 3 is a limited network.

As described above, in the first and second embodiments, the operator can freely change the uniqueness guarantee range by adjusting the local MAC address generation algorithm in the MAC address generation program.

Next, the hardware configurations of the OLT1 and ONU2 according to the first embodiment and the OLT1a and ONU2a according to the second embodiment will be described. As an example, the hardware configuration of OLT1 will be described.

The OLT 1 can be realized by, for example, the processor 91, the memory 92, the interface circuit 93, and the optical interface circuit 94 shown in FIG. FIG. 10 is a diagram showing an example of hardware that realizes OLT1.

The processor 91 is a CPU (also referred to as a Central Processing Unit, a processing unit, a computing device, a microprocessor, a microcomputer, or a DSP (Digital Signal Processor)). The memory 92 is non-volatile, for example, RAM (Random Access Memory), ROM (Read Only Memory), flash memory, EPROM (Erasable Programmable Read Only Memory), EPROM (registered trademark) (Electrically Erasable Programmable Read Only Memory), and the like. Or a volatile semiconductor memory. The interface circuit 93 is a circuit for transmitting and receiving electrical signals via a network, and the optical interface circuit 94 is a circuit for transmitting and receiving optical signals via an optical network.

The registration processing unit 13 and the program collation unit 14 of the OLT 1 are realized by the processor 91 and the memory 92. That is, a program for operating as the registration processing unit 13 and the program collation unit 14 is stored in the memory 92 in advance, and the processor 91 reads the program from the memory 92 and executes the program, whereby the registration processing unit 13 and the program collation are collated. Part 14 is realized.

Further, the storage unit 11 of the OLT 1 is realized by the memory 92. The communication unit 15 is realized by the interface circuit 93 and the optical interface circuit 94. When the communication unit 15 communicates with the management device 3, the interface circuit 93 is used, and when the communication unit 15 communicates with the ONU 2, the optical interface circuit 94 is used.

Although the hardware that realizes OLT1 has been described, the same applies to the hardware that realizes OLT1a. Further, ONU2 and 2a can be realized by the same hardware.

The configuration shown in the above embodiments shows an example of the contents of the present invention, can be combined with another known technique, and is one of the configurations as long as it does not deviate from the gist of the present invention. It is also possible to omit or change the part.

1,1 1,1 _n , 1a, 1a ₁ , _1an OLT, 2,2 ₁₁ , 2 _1m , 2 _nm , 2a ₁₁ , 2a _1m , 2a _nm ONU, _3,3a management device, 4 registration server, 10 ₁ , 10 _m , 10 _n1 , 10 _nm PON port, 11,24,30 Storage unit, 12,31 Database holding unit, 13,23 Registration processing unit, 14 Program collation unit, 15,27,36 Communication unit, 21 Address generation Unit, 22 Program Management Department, 25 Unique Address Holding Department, 26, 32 Program Holding Department, 33 Database Creation Department, 34 Program Creation Department, 35 Operation Reception Department, 41,311 MAC Address Database, 51 Optical Coupler, 52 Optical Fiber, 100,100a PON system, 321 MAC address generation program, 331A old ONU program, 331B new ONU program.

Claims (5)

By individually registering each of the plurality of channels in the master station apparatus constituting the communication system, the state transitions to a state in which communication with the master station apparatus is possible, and each of the plurality of channels is registered in the master station apparatus. A slave station device that uses a unique address within a limited network.
A unique address holder that holds the first address assigned to itself,
An address generator that generates a second address that is unique within the limited network based on the first address.
Equipped with
The first address includes a bit string indicating the vendor of the slave station device.
The address generator modifies a part of the bit string determined based on an address pre-assigned to each slave station device that allows connection to the master station device forming the limited network. Generate the second address using an address generator,
A slave station device characterized by that. The target bit to be changed when the address generator generates the second address is an address assigned in advance to each slave station device that is permitted to connect to the master station device forming the limited network. Determined based on the bit string indicating the vendor of the slave station device.
The slave station apparatus according to claim 1. The first address or the second address is assigned to each of the plurality of channels, and each of the plurality of channels is assigned to the master station apparatus by using the assigned first address or the second address. Registration processing department to register,
Equipped with
The address generation unit uses the address generation program acquired from the master station device via the channel registered by the registration processing unit using the first address to generate the second address. Generate,
The slave station apparatus according to claim 1 or 2. The first address or the second address is assigned to each of the plurality of channels, and each of the plurality of channels is assigned to the master station apparatus by using the assigned first address or the second address. Registration processing department to register,
Equipped with
When a new address generation program is acquired from the master station device, the address generation unit newly generates the second address by using the acquired new address generation program.
The registration processing unit newly assigns a second address newly generated by the address generation unit to each of the plurality of channels, and uses the newly assigned second address to each of the plurality of channels. Is registered in the master station device,
The slave station apparatus according to claim 1 or 2. The slave station device according to any one of claims 1 to 4,
The master station device to which the slave station device is connected and
A management device that holds the address generation program executed by the slave station device, and
Equipped with
The management device holds the address generation program used in the slave station device, and the management device holds the address generation program.
The master station device confirms whether the address generation program held by the slave station device connected to itself and the address generation program held by the management device are the same, and is not the same. In this case, the address generation program held by the management device is acquired and downloaded to the slave station device connected to the self.
A communication system characterized by that.

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