JP4692236B2 - OLT switching method, optical termination system, and OLT unit - Google Patents

Description

  The present invention relates to a method of switching an optical terminal device OLT (Optical Line Terminal) of a center station in a PON (Passive Optical Network) system, an optical terminal system, and an OLT unit.

  An optical access method using GE-PON (Gigabit Ethernet Passive Optical Network) is becoming widespread. Ethernet and Ethernet are registered trademarks. In the PON, a plurality of user optical terminators ONU (Optical Network Unit) are connected to an optical terminator OLT (Optical Line Terminal) arranged in a center station via an optical transmission line composed of an optical fiber and an optical coupler. In GE-PON, it is common to accommodate 16 or 32 ONUs with one optical fiber, but there is no upper limit on the number of ONUs that can be accommodated with one optical fiber, and there are 64 or 128 ONUs. It is also possible to accommodate ONUs. In this case, if the OLT fails, service to 64 or 128 users is interrupted.

  In recent years, not only data communication services but also telephone services and broadcasting services are provided simultaneously. If the OLT fails, these services are also unavailable. In the future, IP transmission of terrestrial television broadcasting is also being studied, and more and more service interruptions, especially service interruptions due to OLT failures must be avoided.

It is well known to employ a redundant configuration in preparation for a failure of a communication device. For example, in PON, ITU-TG 983 defines a redundant configuration. Patent Document 1 describes a non-instantaneous redundant configuration of PON. Patent Document 2 describes an uninterruptible switching device in a wavelength division multiplexing apparatus for IP signals (packet signals).
Japanese Patent Laid-Open No. 09-130834 JP 2004-96514 A

  In the PON, the OLT stores management information such as an identification ID (LLID) and an allocated bandwidth of each ONU, and manages each ONU and its service based on this management information. When the OLT is rebooted or exchanged, the OLT usually starts from a discovery procedure for searching for an ONU to be connected, and it takes a very long time before the original service can be started.

  If the active system and the standby system share this management information during and before and after switching, at least the discovery procedure or part of it can be omitted. However, along with the switching, link breaks and clock loss occur in each ONU, and a loss of downlink data frames also occurs. Link disconnection requires a procedure by a spare OLT that newly assigns an LLID to each ONU. In addition, the clock loss requires a procedure for each ONU to synchronize with the clock from the spare OLT. In either case, it takes time, and the active system cannot be switched to the standby system as early as no interruption. Of course, the data lost due to the frame loss cannot be recovered unless the transmission source can be requested to retransmit, and even if the retransmission can be requested, the time loss for that must be accepted.

  Patent Documents 1 and 2 do not disclose a method for sharing management information and a method for preventing link disconnection, clock loss, and frame loss.

  An object of the present invention is to provide an OLT switching method, an optical termination system, and an OLT unit that can solve these disadvantages and can quickly switch to a standby system.

OLT switching method according to the present invention, the working OLT unit through an optical transmission line connected to a plurality of user devices, in the PON system for managing the user equipment, in a method of switching the working OLT unit to the spare OLT unit Then, the downstream signal from the higher level network is supplied to both the current OLT unit and the backup OLT unit, and the signal for the higher level network output from the current OLT unit and the backup OLT unit is supplied to the higher level network. A step of preparing a first connection and an upstream signal from the optical transmission line of the PON system are supplied to both the working OLT unit and the backup OLT unit, and output from the working OLT unit and the backup OLT unit. The signal for the user device of the PON system Comprising the steps of: providing a second connection for supplying to the optical transmission line, the pre-OLT unit intercepts a downlink signal and an uplink signal, a predetermined amount of the downlink signal, the pre-OLT unit in switching the standby mode is stored in the memory a waiting step of Ru is operated, and stopping the output of the upstream and downstream signals from the working OLT unit, a step of a predetermined period after the preliminary OLT unit, the idle pattern Ru is output to the optical transmission line, a step of Ru downlink signal is output to the optical transmission line to be stored from the pre-OLT unit to the memory, the pre-OLT unit, and a step of managing the user equipment, the waiting step is the working Calculating a first hash value from a predetermined signal of the downlink signals output from the OLT unit; In the switching standby mode, a step of calculating a second hash value from the downlink signal input from the upper network to the spare OLT unit, a second hash value of the same downlink signal, and a write address to the memory Are stored in the hash table in association with each other, a step of reading a write address corresponding to the hash value that matches the first hash value on the hash table, and the write address read from the hash table And a step of updating the read address of the memory to the next write address of the predetermined signal .

The optical termination system according to the present invention controls a first OLT unit that is a working machine, a second OLT unit that is a spare machine, and switching from the first OLT unit to the second OLT unit. An optical termination system comprising: a control unit including a control unit that calculates a first hash value of a frame excluding a control frame of a downlink signal output from the first OLT unit. The second OLT unit temporarily stores a downstream signal from the upper network, a hash calculation circuit that calculates a second hash value from a predetermined downstream signal from the upper network, and the same downstream signal of the hash table for storing in association with the write address to the second hash value and the memory, the emitted Reading means for reading the write address corresponding to the hash value on the table matches the first hash value, a memory control circuit for controlling writing and reading the memory, the switching standby mode, from the memory In a state in which reading is prohibited , the read address of the memory is updated to the write address of the predetermined downstream signal next to the write address read by the reading means from the hash table. A memory control circuit that reads a stored signal, an electric / optical converter that converts an electric signal into an optical signal, and the electric power for a predetermined period in accordance with an instruction from the control unit to switch from the switching standby mode to the normal mode. / Idle pattern signal is applied to the optical converter, and then the memory The Ri signals characterized by comprising a circuit switch for supplying to the electrical / optical converter.

The OLT unit according to the present invention includes a memory that temporarily stores a downstream signal from the upper network, a hash calculation circuit that calculates a hash value from the downstream signal from the upstream network, and the hash value and the memory of the same downstream signal. A hash table for storing a write address to the memory, a reading means for reading a write address corresponding to a hash value supplied from the control unit on the hash table, and controlling writing and reading of the memory In the switching standby mode, in the switching standby mode, the memory is set to the write address of the predetermined downlink signal next to the write address read from the hash table by the read means in a state in which reading from the memory is prohibited. Update the read address of In this mode, the memory control circuit that reads the stored signals from the memory in the order of storage, the electric / optical converter that converts the electric signals into optical signals, and the switching unit from the control standby mode to the normal mode. A switching circuit that applies an idle pattern signal to the electric / optical converter for a predetermined period in accordance with a transition instruction, and then supplies a downstream signal from the memory to the electric / optical converter. .

  According to the present invention, the active OLT unit can be switched to the spare OLT unit without disconnecting communication. Since an idle pattern is transmitted at the time of switching, the user apparatus can be prepared for reception of a signal from the spare machine, and can receive a downlink signal without any trouble.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

  FIG. 1 shows a schematic block diagram of an embodiment of the present invention. The optical termination system of the present embodiment arranged in the center station includes an active optical termination (OLT) unit 10a, a spare OLT unit 10b, and a control unit 10c. The upstream side of the working OLT unit 10a and the spare OLT unit 10b is connected to a switch 12, for example, a layer 2 or layer 3 switch. The switch 12 is further connected to an upper network. Downlink signals output from the transmission (TX) port of the switch 12 are supplied to the active OLT unit 10a and the spare OLT unit 10b in predetermined frame units, for example, Ethernet (registered trademark) frame units. The interface between the switch 12 and the OLT units 10a and 10b is 1000Base-T or 1000Base-SX.

  The active OLT unit 10a and the spare OLT unit 10b have the same configuration and function. This is because one type of OLT unit to be stocked can be used, and any of the OLTs 10a and 10b can be used as a working machine or a spare machine. A component is added to the component of the active OLT unit 10a, and b is added to the component of the spare OLT unit 10b.

  Each OLT unit 10a, 10b has a normal mode when operating as an active machine, a switching standby mode when waiting for switching as a spare machine, and a passive mode from the normal mode to stopping. In the switching standby mode, only the upstream signal and downstream signal are received, and the received signal is not output. In this embodiment, the working OLT unit 10a operates in the normal mode, and the spare OLT unit 10b operates in the switching standby mode.

  The downstream sides of the OLT units 10 a and 10 b are connected to the optical fiber 16 via the 2: 1 optical coupler 14. The optical coupler 14 outputs the downstream signal light from the OLT units 10a and 10b to the optical fiber 16, divides the upstream signal light input from the optical fiber 16, and divides one upstream signal light into the OLT unit 10a. Is an optical element that supplies the divided upstream signal light to the OLT unit 10b.

  The optical fiber 16 and below are composed of the optical transmission line of the PON system and the ONUs 22-1 to 22-n of the respective users. That is, the other end of the optical fiber 16 is connected to a 1: n optical coupler 18. The optical coupler 18 divides the downstream signal light from the optical fiber 16 into n and outputs the divided signal light to the optical fibers 20-1 to 20-n. The other ends of the optical fibers 20-1 to 20-n are connected to optical termination units (ONUs) 22-1 to 22-n of the respective users.

  The portion composed of the optical coupler 12, the optical fiber 16, and the optical coupler 18 constitutes a 2: N optical coupler in a broad sense. Therefore, it goes without saying that this part may be changed to a single optical coupler of 2: N. Alternatively, each user may be accommodated by arranging a plurality of 1: 2 optical couplers along the optical axis of one optical fiber.

  Each ONU 22-1 to 22-n outputs upstream signal light to the optical fibers 20-1 to 20-n. The upstream optical signal carries a management signal addressed to the working OLT unit (for example, 10a) and a data signal addressed to a device connected to the upper network. The signal addressed to the OLT unit 10a includes a control signal and a response signal for establishing a logical link. The optical coupler 18 outputs upstream optical signals from the optical fibers 20-1 to 20-n to the optical fiber 16. The optical coupler 14 divides the upstream optical signal from the optical fiber 16 into two parts, supplies one to the WDM (wavelength division multiplexing) optical coupler 56a of the OLT unit 10a, and supplies the other to the WDM optical coupler 56b of the OLT unit 10b.

  The basic operation and configuration of the OLT 10a will be described. The downstream signal frame from the switch 12 is input to the memory 30a as a buffer and the hash calculation circuit 32a. The memory 30a sequentially stores the downstream signal frames from the switch 12 under the control of the memory control circuit 34a.

  In the normal mode, the memory control circuit 34a operates the memory 30a as a ring buffer that circularly uses the storage area of the memory 30a, and sequentially outputs stored data to the CPU 36a. The hash calculation circuit 32a and the hash table 36a are not used in the normal mode.

  On the other hand, in the switching standby mode, the memory control circuit 34a cyclically writes the downstream signal frame from the switch 12 in the storage area of the memory 30a, and does not read the stored data. However, the read address of the memory 30a is sequentially updated in accordance with an instruction from the CPU 38a. A new downlink signal is overwritten on the downlink signal that has not been read from the memory 30a. In accordance with the read permission from the CPU 38a, the memory control circuit 34a reads the memory signal after the read address at that time from the memory 30a to the CPU 38a.

  The hash calculation circuit 32a calculates the hash value of the downstream signal frame from the switch 12 in units of frames. The hash table 36a stores the hash value calculated by the hash calculation circuit 32a in association with the write address of the memory 30a of the frame. Of course, the hash table 36a need only store the correspondence between the hash value and the write address for only the downstream signal stored at that time in the memory 30a.

  The downstream signal read from the memory 30a is input to the CPU 38a. This downstream signal is used for negotiation between the OLT unit 10a and the upper network, such as a signal addressed to the subordinate ONUs 22-1 to 22-n, and a control signal, a response signal, and an approval signal addressed from the upper network to the OLT unit 10a. Related signals. The CPU 38a takes in signals (including control signals, response signals, and acknowledgment signals) addressed to the OLT unit 10a among the downstream signals from the memory 30a, and addresses them to the other ONUs 22-1 to 22-n. The received signal is output to the down buffer 40a. The CPU 38a also outputs a control signal (such as a Gate frame used for logical link registration and band allocation) to the ONUs 22-1 to 22-n to the downlink buffer 40a. Within the downlink buffer 40a, the rate of the downlink signal is adjusted, and the output order is controlled in order of priority. The CPU 38a also snoops (snoops) the types of downstream signals addressed to the ONUs 22-1 to 22-n from the upper network.

  The clock generator 48a has a built-in oscillator having a frequency corresponding to the transmission rate of the downstream signal, for example, 1.25 GHz, and generates a clock having the frequency. The idle pattern generation device 50a repeatedly generates an idle pattern (“00111111010 0110110101”) defined in IEEE 802.3 and called / I2 / in accordance with the clock from the clock generation circuit 48a. The down buffer 40a reads the stored data to the switch 42a in accordance with the output clock of the clock generator 48a. The switch 42a is normally connected to the output of the buffer 40, but is connected to the output of the idle pattern generator 50a only for a predetermined period when shifting from the switching standby mode to the normal mode.

  The output signal of the down buffer 40a selected by the switch 42a or the clock from the clock generator 50a is applied to the drive circuit 44a. The drive circuit 44a drives a laser diode 46a as an electric / optical converter in accordance with a signal from the switch 42a.

  The output light of the laser diode 46a is input to the optical demultiplexer 54a through the optical switch 52a. In the normal mode, the CPU 38a controls the switch 52a to be closed. In the switching standby mode, the CPU 38a stops the drive circuit 44a and / or controls the switch 52a to be in an open state in order to prevent erroneous output of the downstream signal light.

  The optical demultiplexer 54a is provided to monitor the downstream signal light output to the PON optical transmission line, and supplies 99% of the downstream signal from the optical switch 52a to the WDM optical coupler 56, and the rest. Supply to the control unit 10c. The WDM optical coupler 56 a supplies the downstream signal light from the optical demultiplexer 54 a to the optical coupler 14. The downstream signal light is incident on each ONU 22-1 to 22-n via a PON optical transmission line including the optical coupler 14, the optical fiber 16, the optical coupler 18, and the optical fibers 20-1 to 20-n.

  Each ONU 22-1 to 22-n outputs upstream signal light to the optical fibers 20-1 to 20-n. The upstream optical signal carries a signal addressed to the working OLT unit (for example, 10a) and a signal addressed to a device connected to the upper network. The signal addressed to the OLT unit 10a includes a control signal and a response signal for establishing a logical link. The optical coupler 18 outputs upstream optical signals from the optical fibers 20-1 to 20-n to the optical fiber 16. The optical coupler 14 divides the upstream optical signal from the optical fiber 16 into two parts, supplies one to the WDM optical coupler 56a of the OLT unit 10a, and supplies the other to the WDM optical coupler 56b of the OLT unit 10b.

  The WDM optical coupler 56a supplies the upstream signal light from the optical coupler 14 to an optical / electrical converter 58a such as a photodiode. The optical / electrical converter 58a converts the upstream signal light from the WDM optical coupler 56a into an upstream signal that is an electrical signal. This upstream signal is supplied to the CPU 38a via the buffer 60a. The CPU 38a takes in signals (LLID registration request, bandwidth request, etc.) addressed to the OLT unit 10a from among the upstream signals, and snoops (snoops) the upstream signals addressed to the upper network. In the normal mode, the CPU 38a supplies the upstream signal addressed to the upper network to the switch 12 among the signals from the buffer 60a. In the switching standby mode, the CPU 38a discards the signal after storing it in the FIFO buffer without supplying it to the switch 12. .

  The CPU 38a includes a storage device that stores an IGMP snooping table and a MAC address table for each of the ONUs 22-1 to 22-n. In the switching standby mode, the CPU 38a sequentially prepares the IGMP snooping table and the MAC address table according to the interception result of the upstream signal from the ONU 22-1 to 22-n to the active OLT unit in preparation for becoming the active machine. Update. In GE-PON, a spare OLT unit that operates with the same algorithm as the working OLT unit does not intercept messages from the working OLT unit to the ONUs 22-1 to 22-n, but from the ONUs 22-1 to 22-n to the working OLT. The management contents of the ONUs 22-1 to 22-n by the active OLT unit can be grasped only by intercepting the upstream signal to the unit, particularly the management signal such as the REPORT frame.

  The configuration and basic operation of the control unit 10c will be described. The demultiplexed light of the optical demultiplexer 54a is divided into two by the optical demultiplexer 72, one of the divided lights is input to the power monitor 70a, and the other divided light is transmitted from the OLT unit 10a to the ONUs 22-1 to 22-n. The signal is input to the optical / electrical converter 74 in order to monitor the downstream signal output. The optical / electrical converter 74 converts the incoming downstream signal light into an electrical signal. The framing circuit 76 collects downstream signals output from the optical / electrical converter 74 into a predetermined frame, for example, an Ethernet (registered trademark) frame. Since the frame of the downlink signal output from the framing circuit 76 includes a Gate frame, the Gate frame deletion circuit 78 deletes the Gate frame from the frame generated by the framing circuit 76. The hash calculation circuit 80 calculates a hash value of each frame output from the Gate frame deletion circuit 78.

  Further, the demultiplexed light from the optical demultiplexer 54b of the spare OLT unit 10b is input to the power monitor 70b. The power monitors 70a and 70b supply the power value of the monitoring result to the control circuit 82. The control circuit 82 monitors the downstream signal light output states of the OLT units 10 and a10b based on the monitoring results of the power monitors 70a and 70b.

  The control circuit 82 also supplies the hash value calculated by the hash calculation circuit 80 to the CPU 38b of the spare OLT unit (here, the OLT unit 10b).

  The operation of the active OLT unit 10a in the normal mode will be described. The switch 42a is always connected to the output of the downstream buffer 40a, and the switch 52a is always closed. Downstream signal frames from the switch 12 are buffered in the memory 30a and input to the CPU 38a. The CPU 38a captures signals (including control signals, response signals, and approval signals) addressed to the active OLT unit 10a among the downstream signals from the memory 30a, and inputs them to the other ONUs 22-1 to 22-n. The addressed signal is output to the downlink buffer 40a. The CPU 38a also outputs a control signal for the ONUs 22-1 to 22-n to the downlink buffer 40a.

  The clock generator 48a generates a clock having a frequency corresponding to the transmission rate of the downstream signal. The down buffer 40a reads the stored data to the switch 42a in accordance with the output clock of the clock generator 48a. The down signal from the down buffer 40a is applied to the drive circuit 44a, and the drive circuit 44a drives the laser diode 46a according to the down signal.

  The output light of the laser diode 46a is input to the optical demultiplexer 54a through the optical switch 52a. The optical demultiplexer 54a supplies 99% of the downstream signal power from the optical switch 52a to the WDM optical coupler 56, and supplies the rest to the optical demultiplexer 72 of the control unit 10c. The WDM optical coupler 56 a supplies the downstream signal light from the optical demultiplexer 54 a to the optical coupler 14. The downstream signal light is incident on each ONU 22-1 to 22-n via a PON optical transmission line including the optical coupler 14, the optical fiber 16, the optical coupler 18, and the optical fibers 20-1 to 20-n.

  The WDM optical coupler 56a supplies the upstream signal light from the optical coupler 14 to an optical / electrical converter 58a such as a photodiode. The optical / electrical converter 58a converts the upstream signal light from the WDM optical coupler 56a into an upstream signal that is an electrical signal. This upstream signal is supplied to the CPU 38a via the buffer 60a. The CPU 38a captures a signal addressed to the active OLT unit 10a from among the upstream signals, and snoops (snoops) the upstream signal addressed to the upper network. The CPU 38a supplies the switch 12 with an upstream signal addressed to the upper network among the signals from the buffer 60a.

  At this time, in the control unit 10c, the split light from the optical demultiplexer 54a is divided into two by the optical demultiplexer 72, one split light is input to the power monitor 70a, and the other split light is optical / electrically converted. Input to the device 74. The optical / electrical converter 74 converts the downstream signal light from the optical demultiplexer 72 into an electrical signal. The framing circuit 76 collects downstream signals output from the optical / electrical converter 74 into a predetermined frame. The gate frame deletion circuit 78 deletes the gate frame from the frame generated by the framing circuit 76. The hash calculation circuit 80 calculates a hash value of each frame output from the Gate frame deletion circuit 78. The control circuit 82 supplies the hash value calculated by the hash calculation circuit 80 to the CPU 38b of the spare OLT unit 10b.

  The operation of the spare OLT unit 10b in the switching standby mode will be described. In the switching standby mode, the CPU 38b opens the switch 52b and connects the switch 42b to the output side of the buffer 40b. However, the buffer 40b is substantially in an output stopped state.

  The memory 30b cyclically stores the downlink signal frames from the switch 12 sequentially under the control of the memory control circuit 34b. The memory control circuit 34b stops reading stored data from the memory 30b. The hash calculation circuit 32b calculates a hash value of the downstream signal frame in units of frames. The hash table 36b stores the hash value of the downstream signal frame and the write address in association with each other.

  The CPU 38b searches the hash table 36b for a hash value having the same value as the hash value from the control circuit 82, and reads an address for storing a frame having the same hash value from the hash table 36b. The CPU 38b instructs the memory control circuit 34b to indicate the read address of the memory 30b as the address of the frame next to the frame having the same hash value on the memory 30b. As a result, the downlink signal frame output from the OLT unit 10a is deleted from the memory 30b of the spare OLT unit 10b.

  The WDM optical coupler 56b supplies the upstream signal light from the optical coupler 14 to an optical / electrical converter 58b such as a photodiode. The optical / electrical converter 58b converts the upstream signal light from the WDM optical coupler 56b into an upstream signal that is an electrical signal. This upstream signal is supplied to the CPU 38b via the buffer 60b. The CPU 38b takes in the signal addressed to the OLT unit 10a from among the upstream signals, and discards it while sniffing the upstream signal addressed to the upper network. That is, the CPU 38b does not supply the upstream signal to the upper network to the switch 12. The CPU 38b updates the IGMP snooping table and the MAC address table for each of the ONUs 22-1 to 22-n based on the result of the snooping.

In the standby OLT unit 10b in the switching standby mode, the downlink signal not output from the active OLT unit 10a is stored in the memory 30b.

Thus, the OLT units 10a to the working machine, when the OLT unit 10b and spare machine, working OLT unit 10a operates in the normal mode, specifically, as described above, from the upper network ONU22-1 Relays downstream signals to ~ 22-n and upstream signals from ONUs 22-1 to 22-n to the upper network, and manages registration of logical links and assignment of transmission bands of ONUs 22-1 to 22-n . Further, the spare OLT unit 10b intercepts the downstream signal and the upstream signal in the switching standby mode. The control device 82 of the control unit 10c monitors the downstream signal output from the OLT unit 10a to the optical coupler 14 by the circuits 74-80.

  A switching procedure and operation from the active OLT unit 10a to the spare OLT unit 10b will be described. In accordance with an instruction from a remote user, an instruction from an operating device (not shown), or detection of a failure of the active OLT 10a unit that cannot output a downstream signal light, the control device 82 of the control unit 10c performs the following procedure from the active OLT 10a. Switch to the spare OLT unit 10b.

  The standby OLT unit 10b operates as described above in the switching standby mode, and always stores the latest fixed amount of data in the downstream signal from the switch 12 to the ONUs 22-1 to 22-n in the memory 30b. In addition, an upstream signal from the ONUs 22-1 to 22-n to the working OLT unit 10 a and the upper network is intercepted, and the operation contents of the ONUs 22-1 to 22-n and the ONUs 22-1 to 22-by the working OLT unit 10 a are monitored. Intercept the management contents of n. Switch 42b is connected to the output of buffer 40b and switch 52b is open. Of course, the clock generator 48b and the idle pattern generator 50b are operating, and the clock generator 48b generates a clock having a predetermined frequency.

  As described above, the circuits 74 to 80 calculate hash values for frames other than the Gate frame in the downstream signal light output from the laser diode 46a of the active OLT unit 10a. The control device 82 supplies the calculated hash value to the CPU 38b of the spare OLT unit 10b. The CPU 38b of the spare OLT unit 10b compares the hash value from the control device 82 with a plurality of hash values stored in the hash table 36b, and indicates the next address of the address corresponding to the matching hash value as the read address. The memory control circuit 34b is controlled. Of course, at this time, only the read address is changed, and reading from the memory 30b is disabled. In this way, every time a downstream signal is output from the active OLT unit 10a, the read address of the memory 30b is updated to indicate the downstream signal that has not been output.

  The control unit 10c confirms that the downlink signal buffering in the memory 30b of the backup OLT unit 10b is operating normally and that the backup OLT unit 10b is able to intercept the uplink signal, and then the working OLT unit 10a is instructed to shift to the passive mode, and the backup OLT unit 10b is instructed to shift to the normal mode.

  In the passive mode, the OLT unit 10a stops outputting the downlink signal light and opens the switch 52a when the output of the downlink signal light is completed in units of frames. In addition, the working OLT unit 10a stops assigning a new band to the ONUs 22-1 to 22-n. Due to the stop of bandwidth allocation, each ONU 22-1 to 22-n cannot output an upstream signal. The passive mode is a mode in which the function is substantially stopped only by storing the management information, and waiting for completion of switching to the spare machine. Of course, when the downstream signal light output system of the working OLT unit 10a is broken or when the working OLT unit 10a is broken down, the OLT unit 10a actually sends a control signal to the ONUs 22-1 to 22-n. Cannot transmit, and cannot output downstream signal light.

  In accordance with the instruction to shift to the normal mode, the CPU 38b of the backup OLT unit 10b opens the output port to the switch 12 in preparation for relaying the upstream signal to the upper network.

  In preparation for the optical signal output from the laser diode 46b, the CPU 38b closes the switch 52b and connects the switch 42b to the idle pattern generator 50b side for a predetermined period, for example, about 2 μs. Thereby, idle pattern signal light is supplied to each ONU 22-1 to 22-n for a predetermined period. By transmitting the idle pattern signal light to each of the ONMUs 22-1 to 22-n before the data signal light, each of the ONUs 22-1 to 22-n can be prepared for synchronization detection of downstream signals received thereafter.

  After returning the switch 42b to the output side of the down buffer 40b, the CPU 38b reads out the down signal stored in the memory 30b after the storage position indicated by the read address and supplies it to the down buffer 40b. That is, the memory 30b is operated as a buffer. Thereby, the backup OLT unit 10b plays a role of relaying the downstream signals of the respective ONUs 22-1 to 22-n from the upper network.

  For example, when the downstream frames a, b, c, d, e, f,... Continue and the OLT unit 10a outputs the downstream signal light of the downstream frames a, b, c to the optical coupler 14. In addition, the OLT unit 10 b outputs downstream signal light of downstream frames d, e, f,... Following the downstream frame c to the optical coupler 14.

  Each ONU 22-1 to 22-n receives the downstream frames a, b, and c from the OLT unit 10a, receives the clock from the OLT unit 10b for 2 μs, and then receives the downstream frame from the OLT unit 10b. d, e, f,... are received. During the switching from the active OLT unit 10a to the spare OLT unit 10b, a clock synchronized with the downstream signal from the spare OLT unit 10b is transmitted in advance to the ONUs 22-1 to 22-n. Can receive the downstream signal light from the spare OLT unit 10b without any trouble.

  Of course, when the ONUs 22-1 to 22-n may receive the downlink frame in duplicate, the downlink signal output from the active OLT unit 10 a is managed by the read address management of the memory 30 b in the switching standby mode. You may make it memorize | store in duplicate. In this case, the timing for stopping the output of the downstream signal light from the active OLT unit 10a may not be strict. For example, when the frame d is duplicated and stored in the memory 30b, the active OLT unit 10a may stop the output in the middle of outputting the signal light of the downstream frame d.

  The spare OLT unit 10b uses the information acquired by intercepting the upstream signal in the switching standby mode to register the ONU 22-1 such as registration of logical links and transmission bands of the ONUs 22-1 to 22-n. Take over the management of ~ 22-n.

  When the spare OLT unit 10b confirms that the management has been correctly taken over, the spare OLT unit 10b thereafter operates in the normal mode, and notifies the control device 80 of the control unit 10c of the completion of the transition to the normal mode. The control device 80 instructs the OLT unit 10a to shift from the passive mode to the complete stop or to shut down in accordance with the notification of the completion of the shift from the OLT unit 10b to the normal mode.

  In this way, in this embodiment, the OLT can be exchanged without substantially hindering communication between the upper network and the ONUs 22-1 to 22-n. Since the spare OLT unit 10b takes over the management of the ONUs 22-1 to 22-n, the line disconnection normally associated with the OLT exchange does not occur.

  Similarly to switching from the OLT unit 10a to the OLT unit 10b, when switching from the OLT unit 10b to the OLT unit 10a is desired, elements having the same functions as those of the elements 72 to 80 are applied to the demultiplexed light of the demultiplexer 54b. Even so.

  The OLT units 10a and 10b may share the clock generators 48a and 48b, or may share the clock generators 48a and 48b and the idle pattern generators 50a and 50b. For example, the control unit 10c is provided with a clock generator corresponding to the clock generators 48a and 48b and an idle pattern generator corresponding to the idle pattern generators 50a and 50b, and the clocks generated by the clock generator are buffered 40a and 40b. The idle pattern generated by the idle pattern generator is supplied to the switches 42a and 42b.

  It is obvious that the above embodiment can be extended to a configuration in which a plurality of working machines and one spare machine are arranged in parallel and any working machine is switched to the spare machine. For example, between the L2 switch or the L3 switch and the working machine and the spare machine, a selector capable of paralleling the spare machine to the working machine to be switched is arranged, and the optical coupler corresponding to the working machine, the spare machine, and the optical coupler 14 is arranged. Between the two, a selector optical selector that can parallelize a spare machine to the current machine to be switched may be arranged.

  Although the invention has been described with reference to specific illustrative embodiments, various modifications and alterations may be made to the above-described embodiments without departing from the scope of the invention as defined in the claims. This is obvious to an engineer in the field to which the present invention belongs, and such changes and modifications are also included in the technical scope of the present invention.

It is a schematic block diagram of one Example of this invention.

Explanation of symbols

10a, 10b: Optical termination unit (OLT unit)
10c: Control unit 12: L2 switch 14: Optical coupler 16: Optical fiber 18: Optical couplers 20-1 to 20-n: Optical fibers 22-1 to 22-n: Optical terminator (ONU)
30a, 30b: Memory 32a, 32b: Hash calculation circuit 34a, 34b: Memory control circuit 36a, 36b: Hash table 38a, 38b: CPU
40a, 40b: Downstream buffers 42a, 42b: Switches 44a, 44b: Drive circuits 46a, 46b: Laser diodes (electric / optical converters)
48a, 48b: clock generators 50a, 50b: idle pattern generators 52a, 52b: optical switches 54a, 54b: optical demultiplexers 56a, 56b: WDM optical couplers 58a, 58b: optical / electrical converters 60a, 60b: upstream Buffers 70a and 70b: Power monitor 72: Optical demultiplexer 74: Optical / electrical converter 76: Frame forming circuit 78: Gate frame deletion circuit 80: Hash calculation circuit 82: Control circuit

Claims (6)

Working OLT unit (10a), via an optical transmission line connected to a plurality of user devices, in the PON system for managing the user equipment, in a method of switching the working OLT units (10a) to the pre-OLT unit (10b) There,
For the higher-level network that supplies downstream signals from the higher-level network to both the current OLT unit (10a) and the backup OLT unit (10b), and is output from the current OLT unit (10a) and the backup OLT unit (10b) the method comprising the signal providing a first connection for supplying to the upper network,
The upstream signal from the optical transmission line of the PON system is supplied to both the working OLT unit and the backup OLT unit, and the signal for the user device of the PON system output from the working OLT unit and the backup OLT unit is sent. comprising the steps of: providing a second connection for supplying to the optical transmission line (14),
The preliminary OLT unit, a waiting step of intercepting a downlink signal and an uplink signal, a predetermined amount of the downlink signal or by supplying the pre-OLT unit in switching the standby mode is stored in the memory,
A step of stopping the output of the upstream and downstream signals from the working OLT unit,
A step of predetermined duration, the idle pattern Ru is output to the optical transmission line from the pre-OLT unit,
Comprising the steps of a downlink signal stored from the pre-OLT unit in the memory Ru is output to the optical transmission line,
Step The pre-OLT unit, which manages the user equipment
And
The waiting step is
Calculating a first hash value from a predetermined signal among the downlink signals output from the working OLT unit;
Calculating a second hash value from the downstream signal input from the higher-level network to the spare OLT unit in the switching standby mode;
Storing the second hash value of the same downstream signal and the write address to the memory in association with each other in a hash table;
Reading a write address corresponding to a hash value matching the first hash value on the hash table;
Updating the read address of the memory to a write address of the predetermined signal next to the write address read from the hash table . A first OLT unit (10a) which is a working machine;
A second OLT unit (10b) which is a spare machine;
A control unit (10c) that controls switching from the first OLT unit to the second OLT unit, and is a first frame of a downlink signal that is output from the first OLT unit, excluding the control frame. A control unit comprising a hash calculation circuit (80) for calculating the hash value of
The second OLT unit (10b)
A memory (30b) for temporarily storing downstream signals from the upper network;
A hash calculation circuit (32b) for calculating a second hash value from a predetermined downstream signal from the upper network;
A hash table (36b) for storing the second hash value of the same downlink signal and the write address to the memory in association with each other ;
Reading means for reading a write address corresponding to the hash value matching the first hash value on the hash table;
A memory control circuit for controlling writing and reading of the memory, and in the switching standby mode, in a state in which reading from the memory is prohibited, the predetermined predetermined next to the writing address read by the reading unit from the hash table A memory control circuit (34b) that updates the read address of the memory to the write address of the downstream signal, and reads the memory signal from the memory in the order of storage in the normal mode;
An electrical / optical converter (46b) for converting electrical signals into optical signals;
An idle pattern signal is applied to the electric / optical converter for a predetermined period in accordance with an instruction to shift from the switching standby mode to the normal mode from the control unit, and then the downstream signal from the memory is converted to the electric / optical conversion. Switching circuit (42b, 38b) supplied to the container
And an optical termination system. The optical termination system according to claim 2 , wherein the second OLT unit comprises an idle pattern generator (50b) for generating the idle pattern. The optical termination system according to claim 2 , wherein the control unit includes an idle pattern generator that generates the idle pattern. A memory (30b) for temporarily storing downstream signals from the upper network;
A hash calculation circuit (32b) for calculating a hash value from a downstream signal from the upper network;
A hash table (36b) for storing the hash value and the write address to the memory of the same downstream signal;
Reading means for reading a write address corresponding to a hash value that matches the hash value supplied from the control unit on the hash table;
A memory control circuit for controlling writing and reading of the memory, and in the switching standby mode, in a state in which reading from the memory is prohibited, the predetermined predetermined next to the writing address read by the reading unit from the hash table A memory control circuit (34b) that updates the read address of the memory to the write address of the downstream signal, and reads the memory signal from the memory in the order of storage in the normal mode;
An electrical / optical converter (46b) for converting electrical signals into optical signals;
An idle pattern signal is applied to the electric / optical converter for a predetermined period in accordance with an instruction to shift from the switching standby mode to the normal mode from the control unit, and then the downstream signal from the memory is converted to the electric / optical conversion. Switching circuit (42b, 38b) supplied to the container
OLT unit characterized by comprising. The OLT unit according to claim 5 , further comprising an idle pattern generator (50b) for generating the idle pattern.

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