JP2012231247A - Transmission apparatus and transmission system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To continuously normally conduct a main signal, regardless of a frame length, even during re-activation of a CPU.SOLUTION: In a transmission apparatus, transmission permission band determination means which uses a plurality of transmission terms of transmission control information to allocate a transmission permission band to each of counter transmission apparatuses allocates the transmission permission band to any one of the plurality of transmission terms and determines a transmission start time and a transmission permission amount in the transmission term for each of the plurality of counter transmission apparatuses. The transmission term, and the transmission start time and the transmission permission amount in the transmission term determined by the transmission permission band determination means are stored for each of the plurality of counter transmission apparatuses. In the case of re-activation, transmission control information generated on the basis of the transmission term, the transmission start time, and the transmission permission amount of the corresponding counter transmission apparatus is then transmitted to each counter transmission apparatus within the transmission term.

Description

  The present invention relates to a transmission apparatus and a transmission system. For example, the present invention can be applied to a transmission apparatus and a transmission system in which a main signal is continuously conducted normally even in a transmission system even when a CPU is restarted due to software update or the like.

  In recent years, an access network called FTTH (Fiber To The Home) using an optical fiber as a transmission path has been widespread for the purpose of providing high-speed and broadband broadband services to private homes. For the provision of broadband services by FTTH, an optical access system called a PON (Passive Optical Network) is often used.

  As shown in FIG. 3, the PON system includes one station side optical line terminal (OLT) 2 and a plurality of subscriber side optical line terminal units (ONU) 1 (1-1). ˜1-n: For example, the optical cable 4 is branched using an optical passive element called an optical splitter (optical coupler) 3, for example, indicated as ONU 1-1 or the like. In this configuration, one-to-many connection is made. By sharing the optical fiber 4 and the transmission apparatus among a plurality of subscribers, it is possible to provide an FTTH service economically.

  In the PON system, generally, a WDM (Wavelength Division Multiplexing) method using different wavelengths is used for communication from the OLT 2 to the ONU 1 and communication from the ONU 1 to the OLT 2. In addition, since a single fiber is shared by a plurality of ONUs 1-1 to 1-n, communication from ONU1 to OLT2 uses a TDMA (Time Division Multiple Access) method to collide signals from each ONU1. Is avoiding.

  As an access network using the PON system, there is a network called GE-PON (Gigabit Ethernet PON) which uses Gigabit Ethernet (registered trademark) as a protocol and is standardized as IEEE Std 802.3ah. GE-PON defines a control function called Multi-Point Control Protocol (MPCP) for access control by TDMA, and transmits and receives a control frame called MAC Control frame between OLT 2 and ONU 1. MPCP control is realized with this.

  In MPCP, prior to communication between OLT 2 and ONU 1, a communication path between OLT 2 and ONU 1 is established by a procedure called a discovery process. In the discovery process, a MAC path for discovery processing is transmitted and received between the OLT 2 and the ONU 1 to establish a communication path between the OLT 2 and the ONU 1. For the TDMA control from the ONU 1 to the OLT 2, the time synchronization of the OLT 2 and all the ONUs 1 is performed in the discovery process.

  After the communication path is established, the ONU 1 notifies the OLT 2 of the amount of data to be transmitted (transmission request amount) using a REPORT frame that is one of the MAC control frames.

  The OLT 2 uses the GATE frame, which is one of the MAC Control frames, from the transmission request amount of each ONU 1 notified by the REPORT frame, the data amount (transmission permission amount) that permits transmission of each ONU 1 and the transmission start time. To ONU1.

  The ONU 1 transmits a data frame to the OLT 2 based on the transmission permission amount notified by the GATE frame and the transmission start time.

  IEEE Std 802.3ah prescribes functions (OAM: Operation, Administration and Maintenance) between OLT and ONU, and uses OLT-ONU using a control frame called a slow protocol frame. OAM information is communicated between them.

  Regarding communication of OAM information between OLT and ONU, after a communication path by MPCP is established, a communication path for OAM information is established by an OAM discovery mechanism. After the communication path for OAM information is established, the normality of the communication path for OAM information is confirmed by monitoring periodic exchange of OAM information.

  As described above, the MPCP discovery process, the exchange of control information using the GATE frame after establishing the communication path, the REPORT frame, and the operation / management / maintenance function are performed by software processing by the CPU in the transmission apparatus constituting the PON system. Generally realized.

  However, software installed in the OLT2 and ONU1 devices is often expected to be updated for reasons such as function expansion, and in that case, it is common to restart the CPU. .

  Therefore, while the CPU is restarted due to software update, the function of exchanging control information by the GATE frame and REPORT frame after the establishment of the communication path is stopped, and transmission and reception of the GATE frame and REPORT frame between the OLT and the ONU are stopped. There is a problem that the main signal frame cannot be conducted.

  Further, during the CPU restart due to software update, the operation / management / maintenance function stops, and it becomes impossible to maintain the OAM information communication path. In the transmission apparatus, the operation / management / maintenance function is disabled. When the communication path is cut off, the operation of cutting off the conduction of the main signal is common, so that there is a problem that the conduction of the main signal frame becomes impossible.

  As a method for solving the above problems, the technique described in Japanese Patent Application No. 2009-902211 has been proposed. In this method, GATE information (frame transmission start time and transmission permission amount) calculated in advance is set in the transmission permission band setting memory unit, and the preset setting information is periodically updated while the CPU is restarted. The ONU is notified individually.

  In the case of this method, as shown in FIG. 4, the transmission start time of all the connected ONUs 1 during one GATE information transmission cycle (STi; i indicates the ONU number, 1 ≦ i ≦ n) And a transmission permission amount (LENi) are allocated, and the information is periodically notified to the ONU 1.

JP 2009-066555 A

  However, the above-described method may cause a problem depending on the number of ONUs connected and the transmission cycle of GATE information.

  The maximum transmission permission amount given in one cycle is determined by the cycle and the transmission rate at that time. For example, it is assumed that the maximum transmission permission amount given in one cycle is 10,000 bytes, and that there are 10 ONUs 1 connected at that time. At this time, if an attempt is made to evenly allocate the transmission permission amount per unit of each ONU 1, the transmission permission amount per unit of ONU 1 is 1000 bytes.

  In this case, for example, the allocation state of each ONU 1 is as shown in FIG. 5A, and the setting contents of the transmission permission bandwidth setting memory unit of the OLT 2 are shown in FIG. (B) and FIG. 5 (C). That is, the transmission permission band setting memory unit for the ONU 1-1 stores “transmission start time = 0” and “transmission permission amount = 1000” as illustrated in FIG. 5B, and for the ONU 1-10. The transmission permission bandwidth setting memory unit stores “transmission start time = 9000” and “transmission permission amount = 1000” as illustrated in FIG.

  There are various types of frames conducted on the transmission device depending on the protocol. For example, when attention is focused on Ethernet (registered trademark), the maximum frame length of an Ethernet frame is generally 1518 bytes. Therefore, when ONU 1 tries to transmit a frame having a length of 1500 bytes, for example, if the transmission permission amount periodically given is 1000 bytes as described above, the transmission band is insufficient and the frame cannot be conducted. The problem of end up occurs.

  Therefore, the present invention is to restart the computer by software update or the like by installing a function to limit the ONU that gives transmission permission in each slot by making the GATE information transmission cycle (= 1 slot) multiple times into a multi-slot. In particular, an object of the present invention is to provide a transmission apparatus and a transmission system capable of continuing a communication service without interrupting the conduction of the main signal regardless of the frame length.

  In order to solve such a problem, the first aspect of the present invention is (1) using a plurality of transmission cycles for periodically transmitting transmission control information to a plurality of opposite transmission apparatuses, and a maximum transmission permission band of the plurality of transmission cycles. The transmission permission band is allocated to a plurality of opposite transmission apparatuses, and transmission of transmission control information is allocated to any one of a plurality of transmission cycles, and the transmission start time and transmission in the transmission cycle are assigned. A transmission permission band determining unit that determines a permission amount for each of a plurality of opposed transmission apparatuses; and (2) a transmission cycle determined by the transmission permission band determination unit, a transmission start time and a transmission permission amount in the transmission cycle. A transmission control information setting unit that is set for each of a plurality of opposite transmission apparatuses, and (3) a transmission cycle, a transmission start time, and a transmission time of the corresponding opposite transmission apparatus that are acquired from the transmission control information setting means when restarting. The transmission cycle transmission control information generated on the basis of the authorization amount, compatible transmission system, characterized in that it comprises a plurality of transmission control information transmitting means for transmitting to the opposite transmission devices.

  According to a second aspect of the present invention, in the transmission system for performing data transmission between the first transmission device and the plurality of second transmission devices, the first transmission device corresponds to the transmission device of the first aspect of the present invention. A transmission system characterized by:

  According to the present invention, the transmission cycle of the transmission control information is made into a multi-slot in a plurality of times, and a transmission permission band in each slot is given, so that, for example, even when the computer is restarted by software update or the like, regardless of the frame length The communication service can be continued without interrupting the conduction of the main signal.

It is an internal block diagram which shows the internal structure of the OLT apparatus of 1st Embodiment. It is an internal block diagram which shows the internal structure of the OLT apparatus of 2nd Embodiment. It is a figure which shows the structure of a PON system. It is a figure which shows the allocation method of the uplink transmission permission amount during CPU restart in a prior art. It is a figure which shows the example of allocation of the uplink transmission permission amount during CPU restart in a prior art. It is a sequence diagram which shows the information transmission process between the OLT apparatus and ONU apparatus of 1st and 2nd embodiment. It is a sequence diagram which shows the transmission / reception process of the OAM frame between the OLT apparatus and ONU apparatus of 1st and 2nd embodiment. It is a flowchart which shows the process in the case of performing CPU restart in the OLT apparatus of 1st and 2nd embodiment. It is a figure which shows the allocation method of the uplink transmission permission amount during CPU restart of 1st Embodiment. It is a figure which shows the example of allocation of the uplink transmission permission amount during CPU restart in 1st Embodiment. It is a flowchart which shows the operation | movement of the judgment processing whether to use the multislot of 1st Embodiment. It is a figure which shows the example of uplink transmission permission amount allocation during CPU restart in 2nd Embodiment. It is a figure which shows the example of allocation of the uplink transmission permission amount during CPU restart in 2nd Embodiment.

(A) 1st Embodiment Below, the 1st Embodiment of the transmission apparatus and transmission system of this invention is described, referring drawings.

  1st Embodiment illustrates the case where this invention is applied to the station side transmission apparatus (OLT apparatus) which comprises the GE-PON system which uses the Gigabit Ethernet for the protocol of a PON system.

(A-1) Configuration of the First Embodiment Since the overall configuration of the GE-PON system of the first embodiment is the same as the conventional one, the first embodiment will be described with reference to FIG.

  FIG. 1 is an internal configuration diagram illustrating an internal configuration of the OLT device 2 according to the first embodiment. 1, the OLT device 2 includes an E / O conversion unit 11, a MAC unit 12, a multipoint MAC control frame processing unit 13 (13-1 to 13-n; n is an integer. A multipoint MAC control frame processing unit 13), a MAC control client unit 14, a multipoint transmission control unit 15, a multislot control unit 16, an OAM frame processing unit 17, an OAM client unit 18, and a MAC client unit 19.

  In FIG. 1, the MAC Control client unit 14 and the OAM client unit 18 are executed by software processing by the CPU included in the OLT device 2 by executing a program stored in the ROM. Other components are executed by hardware processing.

  The E / O conversion unit 11 converts the received optical signal into an electrical signal, or converts the electrical signal from the MAC unit 12 into an optical signal.

  The MAC unit (media access control unit) 12 corresponds to a lower sublayer of the data link layer (second layer) of the OSI reference model, and performs frame transmission / reception, error detection, and the like.

  The multipoint MAC control frame processing unit 13 individually performs frame processing for each ONU device 1 connected to the OLT device 2.

  As shown in FIG. 1, the multipoint MAC control frame processing unit 13 includes a MAC control frame identifying unit 131, a MAC control frame multiplexing unit 132, a discovery processing unit 133, a GATE processing unit 134, a REPORT processing unit 135, and a GATE information setting unit. 136.

  The MAC Control frame identification unit 131 identifies a frame called a MAC Control frame among the frames received by the MAC unit 12. The MAC Control frame identifying unit 131 outputs the identified MAC Control frame to the Discovery processing unit 133 or the REPORT processing unit 136, and transfers other frames to the OAM frame processing unit 17.

  The MAC Control frame multiplexing unit 132 multiplexes the frame from the OAM frame processing unit 17 and the MAC Control frame from the Discovery processing unit 133 and the GATE processing unit 134 and outputs the multiplexed result to the MAC unit 12.

  The Discovery processing unit 133 receives the MAC frame for Discovery processing extracted from the MAC Control frame identifying unit 131 and notifies the MAC Control client unit 14 of the contents. Also, the Discovery processing unit 133 generates a MAC frame for Discovery processing based on the Discovery processing information notified from the MAC Control client unit 14 and outputs the MAC frame to the MAC Control frame multiplexing unit 132.

  The REPORT processing unit 135 receives the REPORT frame extracted from the MAC Control frame identification unit 131 and notifies the MAC Control client unit 14 of the contents.

  Based on the GATE information notified from the MAC Control client unit 14, the GATE processing unit 134 generates a GATE frame and outputs the GATE frame to the MAC Control frame multiplexing unit 132. Alternatively, the GATE processing unit 134 generates a GATE frame based on the GATE information set in the GATE information setting unit 136 and outputs the GATE frame to the MAC Control frame multiplexing unit 132. As the operation of the GATE processing unit 134, one of the above operations is selected depending on the setting.

  The GATE information setting unit 136 includes the slot number of the GATE information transmission cycle determined by the MAC Control client unit 14 (information specifying the transmission cycle), the transmission start time determined for each ONU device 1 in the slot, and This sets the amount of transmission permission.

  In addition, the GATE information setting unit 136 sets the transmission start time corresponding to the slot number in a cycle in which the slot number notified from the multi-slot control unit 16 matches the slot number stored in the slot number setting memory unit 1362. The GATE processing unit 134 is notified of the transmission permission amount.

  The GATE information setting unit 136 includes a transmission permission band setting memory unit 1361 and a slot number setting memory unit 1362.

  The transmission permission band setting memory unit 1361 stores the transmission start time and the transmission permission amount notified from the transmission permission band calculation processing unit 142 of the MAC Control client unit 14.

  The slot number setting memory unit 1362 stores the slot number notified from the transmission permitted bandwidth calculation processing unit 142 of the MAC Control client unit 14.

  The multi-slot control unit 16 manages the slot number corresponding to the GATE information transmission period based on the number of slots constituting the multi-slot set from the MAC control client unit 14, and the multi-point MAC control frame This is to notify the GATE information setting unit 136 of the processing unit 13.

  The MAC Control client unit 14 includes a discovery protocol processing unit 141 and a transmission permitted bandwidth calculation processing unit 142.

  The discovery protocol processing unit 141 performs the discovery process processing based on the MAC control frame information notified from the discovery processing unit 133 of each multipoint MAC control frame processing unit 13, and sets the corresponding MAC control frame information to be responded to. This is notified to the Discovery processing unit 133 of the point MAC Control frame processing unit 13.

  The transmission permission bandwidth calculation processing unit 142 calculates a transmission start time and a transmission permission amount to be assigned to each ONU device 1 based on the REPORT information notified from the REPORT processing unit 135 of each multipoint MAC control frame processing unit 13. To do.

  Further, the transmission permission band calculation processing unit 142 notifies the calculated transmission start time and transmission permission amount of each ONU device 1 to the GATE processing unit 135 of the multipoint MAC control frame processing unit 13 corresponding to each ONU device 1. . Also, the transmission permission band calculation processing unit 142 notifies the GATE information setting unit 134 of the calculated transmission start time and transmission permission amount of each ONU device 1 and the slot number as GATE information.

  The multipoint transmission control unit 15 arbitrates the transmission request from each multipoint MAC control frame processing unit 13 and gives a transmission permission to the MAC control frame multiplexing unit 132 of each multipoint MAC control frame processing unit 13. .

  The OAM frame processing unit 17 includes an OAM frame identification unit 171, an OAM frame multiplexing unit 172, an OAM processing unit 173, and an OAM transmission setting memory unit 174.

  The OAM frame identification unit 171 identifies the slow protocol frame among the frames output from the multipoint MAC control frame processing unit 13, outputs the identified frame to the OAM processing unit 173, and the other frames are the MAC client unit. Forward to 19.

  The OAM frame multiplexing unit 172 multiplexes the frame from the MAC client unit 19 and the slow protocol frame from the OAM processing unit 173 and outputs the multiplexed frame to the multiprotocol MAC control frame processing unit 13.

  The OAM processing unit 173 receives the slow protocol frame extracted from the OAM frame identification unit 171 and notifies the OAM client unit 18 of the content. The OAM processing unit 173 is configured to generate a slow protocol frame based on the OAM information notified from the OAM client unit 18 and output it to the OAM frame multiplexing unit 172, or set in the OAM transmission setting memory unit 174. Based on the OAM information, it has a function of generating a slow protocol frame and outputting it to the OAM frame multiplexing unit 172, and one of these operations is selected by setting.

  The OAM transmission setting memory unit 174 stores the OAM information notified from the OAM client unit 18. The OAM transmission setting memory unit 174 periodically notifies the OAM processing unit 173 of the stored OAM information.

  The OAM client 18 includes an OAM protocol processing unit 181. The OAM protocol processing unit 181 performs OAM protocol processing based on the content of the slow protocol frame received from the OAM processing unit 173, and gives OAM information to the OAM processing unit 173.

  The MAC client unit 19 implements a bridge function and the like.

(A-2) Operation of First Embodiment Next, an operation of transmission processing in the GE-PON system of the first embodiment will be described.

(A-2-1) Communication Processing Between ONU Device 1 and OLT Device 2 FIG. 6 is a sequence diagram illustrating communication processing between the ONU device 1 and the OLT device 2.

  In the PON system in which a plurality of ONU devices 1 are connected to the OLT device 2 illustrated in FIG. 1, first, between the discovery protocol processing unit 141 of the MAC Control client unit 14 of the OLT device 2 and the equivalent functions of the ONU device 1. Thus, the discovery information is exchanged using the Discovery MAC Control frame (S101), thereby completing the discovery process and establishing a communication path between the OLT device 2 and the ONU device 1 (S102). At this time, the time synchronization between the OLT measure 2 and the ONU device 1 is also performed.

  After the communication path between the OLT device 2 and the ONU device 1 is established, communication from the ONU device 1 to the OLT device 2 is performed according to the following procedure.

(1) Based on the REPORT information notified from the ONU device 1, the OLT device 2 transmits the transmission start time at which the ONU device 1 may start transmission, and the amount of data that can be transmitted (transmission permission amount). Is notified to the ONU device 1 by the GATE frame (S103).

  At first, since the REPORT information from the ONU device 1 is not received, a transmission permission amount that can transmit the REPORT frame is given to the ONU device 1.

(2) The ONU device 1 transmits the REPORT information calculated based on the accumulated data amount to the OLT device 2 using the REPORT frame (S104).

(3) The REPORT information of the REPORT frame received by the OLT device 2 passes through the MAC unit 12, the MAC Control frame identification unit 131, and the REPORT processing unit 135, and the transmission permitted bandwidth calculation processing unit 142 of the MAC Control client unit 14. To be notified.

(4) The transmission permission band calculation processing unit 142 calculates the transmission start time and the transmission permission amount of each ONU device 1 based on the notified REPORT information from each ONU device 1 (S105).

  The transmission start time and transmission permission amount of each ONU device 1 calculated by the transmission permission band calculation processing unit 14 are given to the GATE processing unit 134 as GATE information. Then, the GATE processing unit 134 uses the transmission start time and the transmission permission amount of each ONU device 1 as GATE information, and transmits the information to each ONU device 1 via the MAC Control frame multiplexing unit 132 and the MAC unit 12 by the GATE frame. (S106).

(5) The ONU device 1 extracts the transmission start time and the transmission permission amount from the GATE information of the received GATE frame, and outputs a frame for the transmission permission amount when the transmission start time comes.

  Thereafter, communication from the ONU device 1 to the OLT device 1 is realized by repeating (2) to (5).

  For communication from the OLT device 2 to the ONU device 1, the multipoint transmission control unit 15 arbitrates transmission requests from the multipoint MAC control frame processing units 13 in the OLT device 2. Thereby, the frame output from the multipoint MAC control frame processing unit 13 is controlled.

  FIG. 7 is a sequence diagram showing an OAM frame communication process between the OLT device 2 and the ONU device 1.

  As shown in FIG. 7, after establishing the communication path between the OLT device 2 and the ONU device 1, between the OAM protocol processing unit 181 of the OAM client unit 18 of the OLT device 2 and the equivalent function of the ONU device 1, By exchanging OAM information using a slow protocol frame (S201), the OAM discovery process is completed, and an operation / management / maintenance communication path (OAM information communication path) between the OLT device 2 and the ONU device 1 Is established (S202).

  After the communication path for OAM information is established, periodic exchange of OAM information is performed between the OLT device 2 and the ONU device 1, and the normality of the communication path for OAM information is confirmed by monitoring. It performs (S203, S204).

(A-2-2) Process when Software Update Process of OLT Device 2 is Performed A procedure when the software update process of the OLT apparatus 2 is performed in the above state will be described.

  FIG. 8 is a flowchart for explaining the operation of the software update process of the OLT device 2.

  For example, when updating software in the OLT device 2, the OLT device 2 performs the following operations using an update command, a restart command, or the like as a trigger.

  In the OLT device 2, when updating software, the transmission permitted bandwidth calculation processing unit 142 of the MAC Control client unit 14 uses, for example, a method described later, the transmission permission amount and transmission start to each ONU device 1 using multislots. Determine the time and slot number.

(1) In the OLT device 2, the transmission permission amount, the transmission start time, and the slot number determined for each ONU device 1 are processed from the MAC Control client unit 14 by the multipoint MAC control frame processing corresponding to each ONU device 1. The GATE information setting unit 136 of the unit 13 is notified.

  The GATE information setting unit 136 of each multipoint MAC control frame processing unit 13 sets the received transmission start time and transmission permission amount in the transmission permission band setting memory unit 1361 and sets the slot number in the slot number setting memory unit 1362. (S301).

  Here, FIG. 9 is an explanatory diagram for explaining the relationship between the transmission start time and transmission permission amount allocated to each ONU device 1 in the multi-slot and the slot number.

  One slot refers to one period of the GATE information transmission period in which GATE information is periodically transmitted to one or a plurality of ONU apparatuses 1 connected to the OLT apparatus 2. In this embodiment, as shown in FIG. 9, a multi-slot period obtained by combining a plurality of slots is used as an entire period for assigning GATE information to each ONU device 1.

  Here, the transmission permitted bandwidth calculation processing unit 142 determines the GATE information of each ONU device 1 within a period composed of multislots.

  For example, in FIG. 9, in the case of the ONU device 1-1 of “ONU # 1,” the slot number is “slot 1”, the transmission start time in “slot 1” is “ST1”, and the permitted transmission amount is “LEN1”. Then, the slot number assigned in this way is set in the slot number setting memory unit 1362, and the transmission start time and the transmission permission amount in the slot are set in the transmission permission band setting memory unit 1361.

(2) The operation of the GATE processing unit 134 of the OLT device 2 is changed from the operation of “generating and outputting a GATE frame based on the GATE information notified from the transmission permitted bandwidth calculation processing unit 142 of the MAC Control client unit 14”. The setting is switched to the operation of “generate and output a GATE frame based on the GATE information set in the GATE information setting unit 136” (S302).

  At the same time, the multi-slot control unit 16 sets the number of slots constituting the multi-slot received from the MAC control client unit 14 and starts the slot number management operation. This slot number management operation is realized by, for example, an operation in which the slot number is counted up to a set number such as 1, 2, 3,... Every GATE information transmission cycle, and the count is repeated in order from 1 when the set number is reached. (S303).

(3) OAM information addressed to each ONU device 1 is set in the OAM transmission setting memory unit 174 of the OLT device 2 (S304).

(4) The operation of the OAM processing unit 173 of the OLT device 2 is changed from an operation of “generating and outputting a slow protocol frame based on OAM information notified from the OAM client unit 18” to “OAM transmission setting memory unit” Based on the OAM information set in 174, the setting is switched to the operation of “generate and output a slow protocol frame” (S305).

(5) The software of the OLT device 2 is updated and the CPU is restarted (S306).

(6) After the completion of the CPU restart, the operation of the GATE processing unit of the OLT device 2 is generated by generating a GATE frame based on the GATE information notified from the transmission permitted bandwidth calculation processing unit 142 of the MAC Control client unit 14 The operation is switched back to the “output” operation (S307).

  Further, the operation of the OAM processing unit 173 is switched back to the operation of “generate and output a slow protocol frame based on the OAM information notified from the OAM client unit 18” (S308).

  According to the above procedure, during the restart of the CPU of the OLT device 2, the OAM information set in the OAM transmission setting memory unit 174 is periodically notified to each ONU device 1, so that the OLT device 2 and each ONU The normality of the communication path for OAM information with the device 1 is maintained, and the ONU device 1 does not interrupt communication with the OLT device 2 during that time. Therefore, the communication between the OLT device 2 and the ONU device 1 is not affected during that time.

  Further, during the restart of the CPU of the OLT device 2, the GATE information set in the transmission permission band setting memory unit 1361 is periodically notified to each ONU device 1. During this period, the REPORT information from each ONU device 1. The function of notifying the dynamic GATE information reflecting the above will not work, but will not affect the communication between the OLT device 2 and the ONU device 1.

  If the communication is interrupted for some reason during the CPU restart of the OLT device 2 or each ONU device 1, the communication can be recovered by starting from the MPCP discovery process after the CPU restarts.

(A-2-3) Determination Method of GATE Information Next, a method for determining the GATE information (transmission start time, transmission permission amount, and slot number) of each ONU device 1 in the OLT device 2 will be described.

  In the OLT device 2, the transmission permission band calculation processing unit 142 obtains the transmission start time, transmission permission amount, and slot number of each ONU device 1.

  Various methods can be applied as a method for determining a transmission permission amount or the like by the transmission permission band calculation processing unit 142 as long as the transmission permission amount is obtained from each ONU device 1 using multislots.

  For example, the maximum transmission permission amount given in one cycle is 10,000 bytes, and there are 10 ONU devices connected at that time, and the transmission permission amount is equally allocated to each ONU device 1 Is illustrated.

  At this time, in the case of the conventional method, since the maximum transmission permission amount per slot is 10,000 bytes, the transmission permission amount of the ONU device 1 per unit is 1000 bytes. For example, the maximum frame length (1518 bytes) of the Ethernet frame In some cases, the frame becomes smaller and frame conduction is not possible.

  Therefore, for example, the transmission permission bandwidth calculation processing unit 142 sets the transmission permission amount of each ONU device 1 to “2000 bytes”, and determines the number of ONU devices 1 connected at that time and the transmission permission amount “2000 bytes”. Multiply. Then, the transmission permission band calculation processing unit 142 determines the number of slots of the GATE information transmission period based on the comparison result between the multiplication result and the maximum permitted amount of one period at that time.

  For example, in this case, the transmission permitted bandwidth calculation processing unit 142 sets the number of slots constituting the multi-slot to “2”. Note that various methods can be widely applied as a method for determining the number of slots, and the method is not limited to the above example.

  The transmission permission band calculation processing unit 142 allocates the transmission permission amount and the transmission start time of the five ONU apparatuses 1-1 to 1-5 in the first slot “slot 1”, and another “5” in “slot 2”. The transmission permission amount and transmission start time of each of the ONU apparatuses 1-6 to 1-10 are determined.

  FIG. 10 is an explanatory diagram illustrating a state of GATE information allocation according to the first embodiment.

  In FIG. 10A, for example, for the ONU device 1-1 of “ONU # 1,” the transmission permitted bandwidth calculation processing unit 142 sets the slot number to “slot 1” and the transmission start time to “ST1 = 0”. , “LEN1 = 2000 (bytes)” is assigned as the transmission permission amount.

  Next, the transmission permitted bandwidth calculation processing unit 142 sets the slot number to “slot 1” for the ONU device 1-2 of “ONU # 2” after “ONU # 1”, and sets the transmission permission amount to “LEN2 = “2000 (bytes)” and the transmission start time is assigned as “ST2 = 2000”.

  Here, the transmission start time indicates a relative time within the same slot. For example, “ST2 = 2000” intends a time after 2000 bytes of data transmission time with respect to “ST1 = 0”. In this embodiment, the transmission start time is a relative time in the same slot, but may be an absolute time.

  As described above, the transmission start time, the transmission permission amount, and the slot number are similarly determined for the ONU devices 1-3 to 1-5 of “ONU # 3” to “ONU # 5”.

  Next, the transmission permitted bandwidth calculation processing unit 142 assigns the slot number “slot 2” to the ONU device 1-6 of “ONU # 6” in the next cycle of the GATE information transmission cycle of “slot 1”. Then, the transmission start time in the slot is set to “ST6 = 0”, and the transmission permission amount is assigned “LEN6 = 2000 (bytes)”.

  Similarly, the ONU devices 1-7 to 1-10 “ONU # 7” to “ONU # 10” also determine the transmission start time, the transmission permission amount, and the slot number.

  As described above, the transmission start time, the transmission permission amount, and the slot number determined by the transmission permission band calculation processing unit 142 are as shown in FIGS. 10 (B) and 10 (C). Are stored in the transmission permitted bandwidth setting memory unit 1361 and the slot number setting memory unit 1362 of the GATE information setting unit 136 of each of the multipoint MAC control frame processing units 13-1 to 13-10.

  According to this method, the transmission permission band of each ONU device 1 can be set to 2000 bytes, and for example, conduction is possible even with the maximum frame length of Ethernet.

  In the above description, the case where the transmission permission bandwidth calculation processing unit 142 determines the transmission permission amount and the like of each ONU device 1 using multislots has been described. However, the MAC Control client unit 14 is It may be determined whether the allocation is performed in the slot or the allocation is performed in the multi-slot.

  FIG. 11 is a flowchart illustrating an example of processing of the allocation method determination method. In FIG. 11, the MAC Control client unit 14 first acquires the maximum transmission permission amount of the GATE information transmission cycle at that time (S401) and the number of ONU devices 1 to which the OLT device 2 is connected (S402). The MAC Control client unit 14 obtains a transmission permission amount that can be allocated to one ONU device 1 based on the maximum transmission permission amount of one GATE information transmission cycle and the number of ONU devices 1. . When the transmission permission amount per unit is less than a threshold value (for example, the maximum frame length value of Ethernet) (S403), the MAC Control client unit 14 performs allocation in multi-slots (S404), and otherwise. The MAC Control client unit 14 performs allocation within one slot (S405).

(A-3) Effect of First Embodiment As described above, according to the first embodiment, the GATE information transmission cycle (= 1 slot) is multi-slotted into a plurality of slots, and the designated slot number is By installing a function to notify GATE information set in advance only in the transmission cycle, even if the maximum frame length is not affected by the GATE information transmission cycle and the number of connected ONUs, the CPU of the OLT device can be restored by software update etc. Communication services can be continued during startup.

(B) Second Embodiment Next, a second embodiment of the transmission apparatus and transmission system of the present invention will be described with reference to the drawings.

(B-1) Configuration of Second Embodiment FIG. 2 is an internal configuration diagram showing an internal configuration of an OLT device of the second embodiment.

  In FIG. 2, the OLT device 20 of the second embodiment includes an E / O conversion unit 11, a MAC unit 12, a multipoint MAC control frame processing unit 23 (23-1 to 23-n, hereinafter referred to as the whole A multipoint MAC control frame processing unit 23), a MAC control client unit 24, a multipoint transmission control unit 15, a multislot control unit 16, an OAM frame processing unit 17, an OAM client unit 18, and a MAC client unit 19.

  The OLT device 20 of the second embodiment is different from the first embodiment in the determination method of the GATE information of the MAC Control client unit 24 and the configuration of the multipoint MAC Control frame processing unit 23. Are the same as those in the first embodiment, and are denoted by the same reference numerals.

  Therefore, in the following, the configuration of the multipoint MAC control frame processing unit 23 and the MAC control client unit 24 different from those of the first embodiment will be described in detail.

  The MAC Control client unit 24 includes a discovery protocol processing unit 141 and a transmission permitted bandwidth calculation processing unit 242. In the second embodiment, the determination method of GATE information determined for each ONU device 1 by the transmission permitted bandwidth calculation processing unit 242 is different from that in the first embodiment.

  In addition to the function of the first embodiment, the transmission permission band calculation processing unit 242 determines a transmission permission amount and a transmission start time over a plurality of slots for one ONU device 1. Thereby, the transmission start time and the transmission permission amount can be determined for a certain ONU device 1 in a plurality of slots.

  The multipoint MAC control frame processing unit 23 is provided for each ONU device 1 as in the first embodiment.

  In addition, the multipoint MAC control frame processing unit 23 replaces the GATE information setting unit 136 of the first embodiment with a plurality of GATE information setting units 236 (236-1 to 236-3; A setting unit 236).

  The GATE information setting unit 236 sets the transmission permission amount and the transmission start time for each slot for each slot number when the transmission permission band calculation processing unit 242 determines the transmission permission amount and the transmission start time over a plurality of slots. To do.

  The number of GATE information setting units 236 provided in one multipoint MAC control frame processing unit 23 is only required to set GATE information for each slot when GATE information is determined over a plurality of slots. It is not particularly limited.

  The GATE information setting unit 236 includes a transmission permission band setting memory unit 2361 and a slot number setting memory unit 2362.

  The transmission permission band setting memory unit 2361 stores the frame transmission start time and the transmission permission amount notified from the transmission permission band calculation processing unit 242 of the MAC Control client unit 24.

  The slot number setting memory unit 2362 stores the slot number notified from the transmission permitted bandwidth calculation processing unit 242 of the MAC Control client unit 24.

  Further, the GATE information setting unit 236 is stored in the transmission permission band setting memory unit 2361 in a cycle in which the slot number notified from the multi-slot control unit 16 matches the slot number stored in the slot number setting memory unit 2362. The GATE processing unit 134 is notified of the frame transmission start time and the permitted transmission amount.

(B-2) Operation | movement of 2nd Embodiment Next, operation | movement of the process in the OLT apparatus 20 of 2nd Embodiment is demonstrated, referring drawings.

  In the following, a description will be given focusing on the GATE information determination method in the OLT device 20 and the operation of setting the determined GATE information in the GATE information setting unit 236.

  Note that the operation of communication processing between the OLT device 2 and the ONU device 1 and the operation of software update processing in the OLT device 2 are the same as those in the first embodiment, and thus detailed description thereof is omitted here. To do.

  In 1st Embodiment, the case where the transmission permission amount was equally allocated with respect to the some ONU apparatus 1 was illustrated. However, there is a case where the transmission permission amount of a certain ONU device 1 is determined to be different from that of another ONU device 1.

  For example, when the number of connected ONU devices 1 is 5, the ratio between the transmission permission amount of the ONU device 1-1 and the transmission permission amounts of the other ONU devices 1-1 to 1-4 is expressed as "ONU device 1- 1: Other ONU devices 1-2 to 1-5 = 6: 1 ”are exemplified.

  In this case, according to the procedure according to the first embodiment, in the multi-slot, only one slot can be allocated to the ONU device 1. Therefore, an example of how to assign is as shown in FIG.

  In the example of FIG. 12, it is assumed that the number of slots is “2”, and the maximum transmission permission amount in one cycle is “10000 bytes”. In this case, since the number of slots that can be assigned to the ONU device 1-1 of “ONU # 1” is one, all of “slot1” are assigned to “ONU # 1” and the next “slot2” is assigned. Are assigned to the ONU devices 1-2 to 1-5 of "ONU # 2" to "ONU # 5".

  Then, the transmission permission amount of “ONU # 1” is “LEN1 = 10000”, the transmission permission amounts of “ONU # 2” to “ONU # 5” are “LEN2 to LEN5 = 2000”, and the allocation ratio is “ONU #”. 1: Other ONUs # 2 to # 5 = 5: 1 ”. Furthermore, in “slot 2”, the bandwidth is left unnecessarily.

  Further, if there is no surplus bandwidth in “slot 2”, the transmission permission amount of “ONU # 2” to “ONU # 5” becomes “LEN = 2500”, and therefore the allocation ratio is also “ONU # 1”. : Other ONUs # 2 to # 5 = 4: 1 ”.

  In other words, in the case of the above example, the maximum transmission permission amount given to one ONU device 1 is limited to one-slot number with respect to the entire band.

  Therefore, in the second embodiment, during the software update process in the OLT device 2, the transmission permission bandwidth calculation processing unit 242 performs the transmission start time and the transmission permission amount of each ONU device 1 as follows: Determine the slot number.

  FIG. 13 is an explanatory diagram illustrating a state of GATE information allocation according to the second embodiment.

  For example, the maximum transmission permission amount given in one cycle is “10000 bytes”, the number of connected ONU devices 1 is “5”, and the allocation ratio is “ONU # 1: other ONU # 2”. -ONU # 5 = 6: 1 "is exemplified.

  In this case, when the transmission permission bandwidth calculation processing unit 242 determines the GATE information in one slot, the transmission permission amount per ONU device 1 becomes “6000 bytes” and “1000 bytes”. The transmission-permitted bandwidth calculation processing unit 242 assigns “ONU # 1”, “ONU # 2”, “ONU # 3” to the slot 1, and sets the number of slots constituting the multislot to “2”. “ONU # 1”, “ONU # 4”, and “ONU # 5” are assigned. Note that which ONU device 1 is assigned to each slot is not particularly limited.

  That is, in slot 1, for “ONU # 1,” the transmission permission band calculation processing unit 242 sets the slot number to “slot 1”, the transmission start time to “ST1 = 0”, and the transmission permission amount to “LEN1 = 6000”. ".

  Further, the transmission permitted bandwidth calculation processing unit 242 sets the transmission start time for “ONU # 2” to “ST2 = 6000”, the transmission permission amount to “LEN2 = 2000”, and the transmission start time for “ONU # 3”. Is “ST3 = 8000”, and the transmission permission amount is “LEN3 = 2000”.

  In addition, in slot 2, the transmission permission bandwidth calculation processing unit 242 assigns “ST1 = 0” as the transmission start time and “LEN1 = 6000” as the transmission permission amount for “ONU # 1” separately from slot 1. .

  Further, the transmission permission bandwidth calculation processing unit 242 sets “ST4 = 6000” as the transmission start time for “ONU # 4”, sets “LEN4 = 2000” as the transmission permission amount, and sets the transmission start time for “ONU # 5”. Is “ST5 = 8000”, and the transmission permission amount is “LEN5 = 2000”.

  The transmission permission band calculation processing unit 242 sets the GATE information for each ONU device 1 determined as described above in the GATE information setting unit 236 of the multipoint MAC control frame processing unit 23 corresponding to each ONU device 1.

  For example, as shown in FIG. 13B, in the case of “ONU # 1,” GATE information of each slot is set in the two GATE information setting units 236-1 and 236-2.

  That is, as shown in FIG. 13B, “slot number: 1” is set in the slot number setting memory unit 2362 in the GATE information setting unit 236-1, and “transmission start time = 0” and “transmission permission” “Amount = 6000” is set in the transmission-permitted bandwidth setting memory unit 2361. In the GATE information setting unit 236-2, “slot number: 2” is set in the slot number setting memory unit 2362, and “transmission start time = 0” and “transmission permission amount = 6000” are transmission permission band setting memory. Part 2361.

  Further, as shown in FIG. 13C, in the case of “ONU # 5”, “slot number: 2” is set in the slot number setting memory unit 2362 in the GATE information setting unit 236-1, and “transmission start” “Time = 8000” and “transmission permission amount = 2000” are set in the transmission permission band setting memory unit 2361. However, since “ONU # 5” is set for only one slot, “slot number: none” is set in the slot number setting memory unit 2362 in the GATE information setting unit 236-2, and “transmission start time = none”. ”And“ transmission permission amount = none ”are stored in the transmission permission band setting memory unit 2361.

  As described above, in the multi-slot, the transmission permission band of the ONU device 1-1 is set to “12000 bytes”, and the transmission permission bands of the other ONU devices 1-2 to 1-5 are set to “2000 bytes”. The allocation ratio of “ONU # 1: Other ONU # 2 to # 5 = 6: 1” can be realized. Further, each ONU device 1 can be connected with the maximum frame length.

(B-3) Effects of Second Embodiment As described above, according to the second embodiment, in addition to the effects of the first embodiment, per ONU (for example, per multipoint MAC Control frame processing unit). ), A plurality of GATE information setting units can be assigned to a plurality of slots for the same ONU device.

  As a result, even when the CPU of the OLT device is restarted due to software update, etc., the allocation ratio between ONUs can be increased, such as increasing the allocation to one ONU device without being affected by the GATE information transmission cycle and the number of connected ONUs. It is possible to freely set and continue the communication service.

(C) Other Embodiments In the above-described first embodiment, the number of ONUs connected is exemplified as ten, but the number is not limited to this. Further, although the number of slots constituting the multi-slot is 2, the value may be larger than this. In addition, although an example is given in which the assignment to each ONU is equal, the assignment is not limited to equality, and may be assigned with a certain weight.

  In the second embodiment described above, the number of ONU connections is exemplified as five, but the number is not limited to this. Further, although the number of slots constituting the multi-slot is 2, the value may be larger than this. In addition, an example is shown in which ONUs 1, 2, and 3 are assigned to slot 1, and ONUs 1, 4, and 5 are assigned to slot 2. However, the present invention is not limited to this, and only ONU 1 is assigned to slot 1 and ONUs 1 to 5 are assigned to slot 2. It may be assigned.

  In the first and second embodiments described above, an embodiment of a GE-PON system using Gigabit Ethernet as a protocol of the PON system is shown. However, the embodiment is not limited to the GE-PON system, but other PONs. The same effect can be obtained even if the present invention is applied to a station-side transmission apparatus used in the system. Further, the same effect can be obtained when the present invention is applied not only to the PON system but also to a station-side transmission apparatus that performs similar communication control between two apparatuses. Furthermore, the present invention is not limited to optical communication and can be applied to telecommunication.

1 (1-1 to 1-n): ONU device,
2 and 20 ... OLT device,
11 ... E / O conversion unit, 12 ... MAC unit,
13 (13-1 to 13-n) and 23 (23-1 to 23-n) ... Multipoint MAC Control frame processing unit,
131... MAC control frame identification unit, 132... MAC control frame multiplexing unit, 133... Discovery processing unit, 134... GATE processing unit, 135.
136 and 236 (236-1 to 236-n) ... GATE information setting unit,
1361 and 2361 ... transmission permission band setting memory unit,
1362 and 2362... Slot number setting memory unit,
14 ... MAC Control client part,
15 ... Multipoint transmission control unit, 16 ... Multislot control unit,
17 ... OAM frame processing unit, 18 ... OAM client unit,
19 ... MAC client part,
3 ... optical splitter, 4 ... optical fiber.

Claims (3)

Using multiple transmission cycles for periodically transmitting transmission control information to multiple opposing transmission devices, and assigning a transmission-permitted bandwidth to the multiple opposing transmission devices within the maximum transmission permitted bandwidth of the multiple transmission cycles The transmission of the transmission control information is assigned to any one of the plurality of transmission cycles, and the transmission start time and the transmission permission amount in the transmission cycle are determined for each of the plurality of opposing transmission devices. Allowed bandwidth determination means;
Transmission control information setting means for setting the transmission period, the transmission start time and the transmission permission amount in the transmission period determined by the transmission permission band determining means for each of the plurality of opposed transmission apparatuses;
At the time of restart, the transmission control information generated based on the transmission cycle, the transmission start time, and the transmission permission amount of the corresponding opposite transmission apparatus acquired from the transmission control information setting unit is used as the transmission cycle. And a plurality of transmission control information transmitting means for transmitting to the corresponding opposite transmission apparatus. The transmission permission band determining means allocates a plurality of the transmission cycles to one counter transmission device, and determines the transmission start time and the transmission permission amount for each transmission cycle,
The transmission apparatus, wherein the transmission control information setting means sets the plurality of transmission cycles in association with the transmission disclosure time and the transmission permission amount determined for each transmission cycle. In a transmission system that performs data transmission between a first transmission device and a plurality of second transmission devices,
The transmission system according to claim 1, wherein the first transmission device corresponds to the transmission device according to claim 1.

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