JP2016046704A - GE-PON system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a GE-PON system capable of performing restoration processing after communication disconnection in a short time for a subscriber side terminal device with authentication registration completed.SOLUTION: In a GE-PON system in an embodiment, a quantization window 20 is provided at the anterior half of a discovery window 10, and a free discovery window 30 is provided at the posterior half. The quantization window 20 is divided into a plurality of identification slots 21. When the authentication registration of an ONU 120 is newly conducted, MPCP processing is performed using the free discovery window 30, and then an unused identification slot 21 is allocated. On the other hand, in restoration processing after communication disconnection, the ONU 120 with authentication registration completed returns a registration request signal 52 to an identification slot 21 allocated to the ONU 120 on receiving a GATE signal 51.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a GE-PON (Gigabit Ethernet (registered trademark) Passive Optical Network) system, and more particularly to a GE-PON system capable of shortening the recovery time of a terminal device on a subscriber side.

  A GE-PON system is known as an access communication network having a Star type or PDS (Passive Double Star) type topology as shown in FIG. 8 (for example, Patent Documents 1 and 2). The GE-PON system is composed of an optical line terminal (OLT) 91 and a terminal unit (ONU: Optical Network Unit) 92 (92 (1), 92 () installed on the subscriber side. 2),..., 92 (n)) are connected to each other via a splitter 93. Such a GE-PON system is applied to, for example, a communication network for FTTH, CATV, automatic meter reading, and the like.

  In the GE-PON system shown in FIG. 8, time division multiplexed (TDM) data is transmitted from the OLT 91 to all ONUs 92. Each ONU 92 extracts only the information addressed to itself from the received data, and discards other data. On the other hand, when data is transmitted from the ONU 92 side to the OLT 91, the data is transmitted using time slots and bandwidths allocated from the OLT 91 by time division multiple access (TDMA). As a result, collision between data is prevented. In the GE-PON system, data exchange between the OLT 91 and the ONU 92 is performed at 1: 1, so that a data transmission delay can be reduced.

  In the GE-PON system, to enable data communication between the OLT 91 and the newly installed ONU 92, it is necessary to establish a PON link for the new ONU 92 and perform authentication registration. In order to establish a PON link, MPCP (Multi-Point Control Protocol) processing standardized by IEEE Std 802.3ah-2004 (Ethernet (registered trademark)) is performed.

  The outline of the MPCP process will be described below with reference to FIG. 9. FIG. 9 shows the procedure of the MPCP process performed to establish the PON link between the OLT 91 and the ONU 92. Time is going in the direction. In the figure, after the ONU 92 is activated, the OLT 91 first transmits a GATE signal 51 for notifying the ONU 92 of the transmission timing. The ONU 92 that has received the GATE signal 51 returns a registration request signal 52 to the OLT 91 after a random delay time calculated by itself. The OLT 91 is provided with the discovery window 10 as a time zone for receiving a signal from the ONU 92, and the OLT 91 detects the ONU 92 in which the registration request signal 52 reaches the OLT 91 within the time zone of the discovery window 10.

  The OLT 91 sets a logical link identifier (Logical Link ID, hereinafter referred to as LLID) for the ONU 92 that is the transmission source of the received registration request signal 52. Then, the registration signal 53 is transmitted to the ONU 92 in order to notify the set LLID to the ONU 92 concerned. When the ONU 92 receives the registration signal 53 in which the LLID information is written from the OLT 91, and then receives the GATE signal 51 ′ for notifying the band and transmission timing from the OLT 91, the registration ACK signal 54 is received as a response signal to the reception of the registration signal 53. Is transmitted to the OLT 91. Thereby, the authentication registration of the ONU 92 is completed and the PON link is established, and data communication between the OLT 91 and the ONU 92 becomes possible. Since a plurality of ONUs 92 are normally connected to one OLT 91, the above MPCP process is performed for each ONU 92.

  In the above-described conventional GE-PON system compliant with IEEE Std 802.3, only the ONU 92 whose registration request signal 52 reaches the OLT 91 within the time window of the discovery window 10 is authenticated and registered in the OLT 91. Therefore, the ONU 92 for which the registration request signal 52 has not reached within the time window of the discovery window 10 needs to repeat the above MPCP process until it is authenticated and registered in the OLT 91.

  Each ONU 92 internally calculates a random delay time in order to avoid collision with a signal from another ONU 92 and shifts the transmission timing from the other ONUs 92. Therefore, the transmission timing is not always different from those of other ONUs 92. Therefore, there is a possibility of collision with a signal transmitted from another ONU 92. The random delay time is determined so that the signal reaches the OLT 91 within the time window of the discovery window 10, but the signal is not transmitted within the time window of the discovery window 10 due to the physical distance to the OLT 91. There is also a risk that it will be impossible to reach.

  For the above reasons, there is an ONU 92 in which the registration request signal 52 does not reach the OLT 91 within the time window of the discovery window 10, especially when starting up a GE-PON system in which a plurality of ONUs 92 request registration at once. Therefore, it takes time until all ONUs 92 are registered for authentication.

JP 2011-130250 A JP 2011-130251 A

  However, in the conventional GE-PON system, not only at the time of start-up, but also when data communication between the OLT and the ONU is completely stopped due to a failure or the like, the data of all ONUs after the cause of the failure is resolved There was a problem that it took a long time before communication was possible. Possible causes of the failure include, for example, a power failure of the ONU due to a power failure or the like, or a failure in the PON section line (for example, disconnection of an optical connector), which prevents data communication. In the conventional method for restoring the GE-PON system, as shown in FIG. 10, in order to re-authenticate and register all ONUs 92, all ONUs 92 request registration for the first GATE signal 51 after removal of a failure or the like. A signal 52 is transmitted to the OLT 91. At this time, for example, a collision occurs as in the registration request signal 52 from the ONU 92 (3) and ONU 92 (n) shown in FIG. 10, or the time window of the discovery window as in the registration request signal 52 from the ONU 92 (4). The OLT 91 is not reached. For this reason, it took time to restore all ONU communications.

  In order to shorten the time required for authentication registration of all the ONUs as described above, for example, a method has been proposed in which the period for performing the MPCP process is shortened to increase the probability that the ONU is registered. However, if the cycle of the MPCP process is shortened, the ratio of the time allocated to the MPCP process increases, which causes a problem that the time for performing the original data communication is shortened.

  Also, Patent Documents 1 and 2 propose methods for shortening the time required for recovery, but it is necessary to perform discovery processing similar to the conventional one at the time of recovery. For this reason, problems such as collision cannot be solved, and the discovery process needs to be repeated. Therefore, there is a problem that it takes time to register all ONUs for authentication.

  The present invention has been made to solve these problems, and provides a GE-PON system capable of performing recovery processing after disconnection of a communication on a subscriber terminal device that has already been registered for authentication in a short time. The purpose is to do.

  A first aspect of the GE-PON system of the present invention is a GE-PON system in which a station-side device and a plurality of subscriber-side terminal devices are connected via an optical fiber via a branching unit. The side device has a quantization window divided into a predetermined number of identification slots and a free discovery window, and a discovery window management unit that manages a discovery window used to authenticate and register the subscriber side terminal device; and An MPCP processing unit that performs MPCP processing for authentication registration of the subscriber side terminal device and sets an identification number of the subscriber side terminal device; and the identification on the subscriber side terminal device that has been authenticated and registered by the MPCP processing A slot information setting unit that allocates any one of the slots and creates identification slot information in which at least the identification number is associated with the slot number of the identification slot Confirming whether a registration request signal is returned to the identification slot after restoration, and re-authenticating and registering the subscriber-side terminal apparatus corresponding to the identification slot to which the registration request signal is returned A restoration unit and a station-side device-side storage unit that stores the identification slot information, and the subscriber-side terminal device performs the MPCP process with the MPCP processing unit and performs the MPCP processing unit to The slot information is read from the OAM frame transmitted from the station side device and stored in the subscriber side terminal device side storage unit, the link processing unit that receives the identification number, the subscriber side terminal device side storage unit, and An OAM processing unit to be read, and when the recovery process is performed, the identification slot information is read from the subscriber side terminal device side storage unit and a delay time at the time of recovery is output to the link processing unit A recovery processing unit, and when the station side device newly authenticates and registers the subscriber side terminal device, the MPCP processing unit transmits a GATE signal to the new subscriber side terminal device. MPCP processing is performed based on a registration request signal returned from the link processing unit to the free discovery window to assign the identification number, and the slot information setting unit is allocated to another subscriber-side terminal device. The identification slot that is not allocated is allocated to the new subscriber-side terminal device, the identification slot information is stored in the station-side device-side storage unit, and the slot information is set in the OAM frame so that the new subscriber side When transmitting to the terminal device and performing recovery processing of the GE-PON system, the recovery processing unit first transmits the GCP from the MPCP processing unit during the recovery processing. When the ATE signal is received, the recovery delay time is output to the link processing unit, the link processing unit returns the registration request signal to the identification slot according to the recovery delay time, and the subscriber side terminal device recovery unit The authentication registration is again performed using the identification slot information with respect to the subscriber-side terminal apparatus that has returned the registration request signal to the identification slot.

  In another aspect of the GE-PON system of the present invention, the MPCP processing unit sets a plurality of identification numbers in the subscriber side terminal device, and the slot information setting unit sets the identification slot for each identification number. It is characterized by associating slot numbers.

  In another aspect of the GE-PON system of the present invention, the slot information setting unit calculates the recovery delay time using distance information to the subscriber-side terminal device, and calculates the calculated recovery delay time. It is included in the identification slot information.

  According to another aspect of the GE-PON system of the present invention, when the subscriber side terminal device that has received the first GATE signal does not store the identification slot information, the link processing unit transmits the registration request signal. It returns to the said free discovery window, It is characterized by the above-mentioned.

  In another aspect of the GE-PON system of the present invention, the slot number is assigned in order from the identification slot at the head of the quantization window, and the slot information setting unit is a distance to the subscriber side terminal device. Are characterized in that the identification slots are assigned in ascending order.

  According to another aspect of the GE-PON system of the present invention, the discovery window management unit is configured such that the maximum number of subscriber-side terminal devices connectable to the station-side device is authenticated and registered, and the identification slot is assigned to each. The free discovery window is deleted.

  In another aspect of the GE-PON system of the present invention, the station-side device creates a registration management table in which at least the identification numbers of all the subscriber-side terminal devices that have been authenticated and registered are described, and a predetermined condition A registration management table management unit that transmits the registration management table to all the subscriber terminal devices when the registration is established, and the subscriber terminal device stores the identification management table upon receipt of the registration management table Number and the identification number described in the registration management table, and when the stored identification number matches any of the identification numbers described in the registration management table, the registration request signal is Return to the assigned identification slot and store the identification number when it does not match any of the identification numbers in the registration management table And further comprising a registration management table checking unit to return a demand signal to said free discovery window.

  Another aspect of the GE-PON system according to the present invention is characterized in that the predetermined condition is when a recovery process of the GE-PON system is performed.

  Another aspect of the GE-PON system of the present invention is characterized in that the predetermined condition is a predetermined period and when the registration management table is reached at the time of updating the registration management table.

  According to another aspect of the GE-PON system of the present invention, the registration management table management unit is configured such that the registration request signal is not returned even if a predetermined time elapses after the registration management table is transmitted. The identification number is deleted from the registration management table.

  In another aspect of the GE-PON system of the present invention, the subscriber side terminal device further includes a reset switch for deleting the identification slot information stored in the subscriber side terminal device side storage unit. Features.

  ADVANTAGE OF THE INVENTION According to this invention, the GE-PON system which can perform the recovery process after communication disconnection with respect to the subscriber side terminal device by which authentication registration was completed can be provided.

It is process explanatory drawing which shows the procedure which performs signal transmission / reception between OLT and several ONU using the discovery window which the GE-PON system of 1st Embodiment of this invention has. It is a block diagram which shows the structure of the GE-PON system of 1st Embodiment. It is process explanatory drawing which shows the process after the authentication registration in the GE-PON system of 1st Embodiment. It is process time explanatory drawing which shows the recovery method of the GE-PON system of 1st Embodiment. It is another process explanation drawing at the time of restoration showing the restoration method of the GE-PON system of the first embodiment. It is process explanatory drawing at the time of the recovery which shows the recovery method of the GE-PON system of 2nd Embodiment of this invention. It is a block diagram which shows the structure of the GE-PON system of 3rd Embodiment of this invention. It is a block diagram which shows the structure of the conventional GE-PON system. It is process explanatory drawing which shows the procedure of the MPCP process in the conventional GE-PON system. It is process explanatory drawing which shows the procedure which restores several ONU in the conventional GE-PON system. It is a block diagram which shows the structure of the conventional GE-PON system when each ONU has two or more LLID. It is process explanatory drawing in the GE-PON system of 1st Embodiment when each ONU has multiple LLID. It is process explanatory drawing at the time of recovery in the GE-PON system of 1st Embodiment when each ONU has two or more LLID. It is process explanatory drawing at the time of the recovery in the conventional GE-PON system when each ONU has two or more LLID.

  A GE-PON system according to a preferred embodiment of the present invention will be described in detail with reference to the drawings. In addition, about each structural part which has the same function, the same code | symbol is attached | subjected and shown for simplification of illustration and description. In the following, the definition of “recovery” is the same as in the past. Even when the data communication between the OLT and the ONU is completely stopped due to a failure, the data of all ONUs after the cause of the failure is resolved This means that communication is possible.

(First embodiment)
A GE-PON system according to a first embodiment of the present invention will be described with reference to FIGS. FIG. 1 is a process explanatory diagram illustrating a procedure for performing signal transmission / reception with a plurality of ONUs using the discovery window of the present embodiment. FIG. 2 is a block diagram showing the configuration of the GE-PON system 100 of this embodiment. The GE-PON system 100 is configured by connecting a plurality of ONUs 120 installed on the subscriber side to an OLT 110 provided on the station building side via a splitter (branch unit) 130. In order to distinguish a plurality of ONUs 120, here, as an example, 120 (1), 120 (2),..., 120 (n) are respectively shown in order from the shortest distance to the OLT 110. Here, n is the number of ONUs 120 connected to the splitter 130.

  Also in the GE-PON system 100 of this embodiment, when a new ONU 120 is authenticated and registered in the OLT 110, MPCP processing conforming to IEEE Std 802.3 is performed to establish a PON link. The OLT 110 of this embodiment includes an MPCP processing unit 111, a slot information setting unit 112, a subscriber side terminal device recovery unit (ONU recovery unit) 113, a station side device side storage unit (OLT side storage unit) 114, and a discovery window. A management unit 115 is provided. Further, the ONU 120 of this embodiment includes a link processing unit 121, an OAM processing unit 122, a recovery processing unit 123, and a subscriber side terminal device side storage unit (ONU side storage unit) 124.

  In the GE-PON system 100 of the present embodiment, a quantization window and a free discovery window are provided in the discovery window of the OLT 110 so that the recovery process after the communication is disconnected can be performed in a short time. The configuration of the discovery window used in this embodiment is shown in FIG. In this figure, time advances from the left to the right in the drawing, and the OLT 110 is arranged at the uppermost stage in the vertical direction of the drawing, and a plurality of ONUs 120 are arranged therebelow. Here, for ease of explanation, the ONUs 120 are arranged in the order of short distance to the OLT 110, but the present invention is not limited to this.

  FIG. 1 shows an example of a discovery window 10 in which a quantization window 20 is provided in the first half and a free discovery window 30 is provided in the second half. The arrangement of the quantization window 20 and the free discovery window 30 is not limited to this, and both can be arranged in the reverse direction. Alternatively, it is possible to divide the discovery window 10 into, for example, three regions, and use each as a free discovery window, a quantization window, and a free discovery window.

The quantization window 20 is divided into a plurality of identification slots 21 with a predetermined time width as a unit (quantization). Each identification slot 21 is assigned a slot number. As an example, slot numbers 1, 2,..., M (m is the number of identification slots 21) are assigned in order from the left to the right in the drawing. Yes. The time width (slot width) of each identification slot 21 is a time in which a margin is added to the time width in which the minimum frame transmitted by the GE-PON system 100 can be received. As an example, when the minimum frame length is 64 bytes and the signal transmission period per bit is 800 ps, the time required to receive the signal of the minimum frame is
64 bytes x 8 bits / byte x 800 ps = 0.4096 μs
It becomes. Therefore, the slot width can be set to 1 μs, for example, by adding a margin to this, but it is not limited to this.

  The predetermined number m of identification slots 21 provided in the quantization window 20 is the number corresponding to the ONU 120 that can be connected to one OLT 110. For example, the maximum number of ONUs 120 that can be connected. The maximum number of ONUs 120 that can be connected to one OLT 110 can be any of 32, 64, 128, and the like, for example. In this case, the number m of the identification slots 21 is 32, 64, 128, or the like.

  The free discovery window 30 is used when, for example, a new ONU 120 newly added to the GE-PON system 100 is registered for authentication. In the MPCP process for authenticating and registering a new ONU 120, a GATE signal 51 for notifying the transmission timing is transmitted to each ONU 120. In response to this GATE signal 51, the new ONU 120 returns a registration request signal 52. The timing is a timing delayed (offset) by the time length of the quantization window 20 so that the registration request signal 52 reaches the free discovery window 30.

  In the GE-PON system 100 of this embodiment, the discovery window management unit 115 manages the discovery window 10 described above, and controls reception of signals from the ONU 120. Also, the MPCP process for authenticating and registering the new ONU 120 is performed between the MPCP processing unit 111 of the OLT 110 and the link processing unit 121 of the ONU 120 as follows. Here, the procedure of the MPCP process will be described by taking as an example a case where the ONU 120 (1) is newly registered for authentication. First, the MPCP processing unit 111 of the OLT 110 transmits a GATE signal 51 for notifying the transmission timing to each ONU 120. When the link processing unit 121 of the ONU 120 (1) receives the GATE signal 51, it calculates a random delay time (indicated by reference numeral 56 in FIG. 1), and transmits the registration request signal 52 to the OLT 110 after the random delay time. . The random delay time is determined so that the registration request signal 52 reaches the free discovery window 30.

  When receiving the registration request signal 52 from the ONU 120 (1), the MPCP processing unit 111 of the OLT 110 sets the LLID for the ONU 120 (1) and receives the set LLID. Is transmitted to the ONU 120 (1). Thereafter, the MPCP processing unit 111 transmits a GATE signal 51 for notifying the transmission timing to each ONU 120.

  When the link processing unit 121 of the ONU 120 (1) receives the registration signal 53 that notifies the LLID from the OLT 110, the link processing unit 121 stores the LLID in, for example, the ONU side storage unit 124. Thereafter, when receiving the GATE signal 51 from the OLT 110, the link processing unit 121 calculates a random delay time so that the registration ACK signal 54 reaches the free discovery window 30, and transmits the registration ACK signal 54 to the OLT 110 after the random delay time. . As a result, the authentication registration of the ONU 120 (1) is completed and the PON link is established.

  When the authentication registration of the ONU 120 (1) is completed as described above, the processing shown in FIG. 3 is performed in the GE-PON system 100 of the present embodiment. FIG. 3 is a process explanatory diagram showing processing after authentication registration. First, the slot information setting unit 112 of the OLT 110 executes the process 61 shown in FIG. The slot information setting unit 112 performs processing for assigning the identification slot 21 to the ONU 120 (1). In this process, the slot information setting unit 112 selects one of the identification slots 21 that are not assigned to other ONUs 120 and assigns it to the ONU 120 (1). FIG. 1 shows an example in which the identification slot 21 with the slot number 2 (identification slot 21 (1) shown in FIG. 1) is assigned to the ONU 120 (1).

  Further, the slot information setting unit 112 calculates a delay time at the time of restoration described below as a timing at which the ONU 120 (1) responds to the OLT 110 at the time of restoration after the occurrence of a failure. The recovery delay time is a delay time from when the ONU 120 (1) receives the first restored GATE signal 51 to when the registration request signal 52 is returned. The slot information setting unit 112 receives the registration request signal 52 when the ONU 120 (1) receives the first GATE signal 51 after recovery and the recovery delay time elapses based on the distance information to the ONU 120 (1). , The recovery delay time for the ONU 120 (1) is determined so that the registration request signal 52 reaches the identification slot 21 assigned to the ONU 120 (1).

  When the slot information setting unit 112 calculates the recovery delay time for the ONU 120 (1), at least the identification number of the ONU 120 (1) and the recovery delay time are assigned to the slot number of the identification slot 21 assigned to the ONU 120 (1). Are stored in the OLT side storage unit 114 of the OLT 110 as identification slot information. As the identification number of the ONU 120 (1) stored as identification slot information, for example, LLID can be used.

  Next, the slot information setting unit 112 executes the process 62 shown in FIG. In the process 62, the slot information setting unit 112 writes the identification slot information stored in the OLT side storage unit 114 in an OAM (Operations, Administration, Maintenance) frame, and transmits the OAM frame to the ONU 120 (1). When the above OAM frame is received by the ONU 120 (1), the ONU 120 (1) executes the process 63 shown in FIG. In process 63, the OAM processing unit 122 of the ONU 120 (1) reads the identification slot information described in the OAM frame and stores it in the ONU side storage unit 124. As a result, the identification slot information related to the ONU 120 (1) is shared by both the OLT 110 and the ONU 120 (1).

  In the above description, the authentication registration for the ONU 120 (1) and the creation / storage of the identification slot information have been described. As illustrated in FIG. 1, when there is an ONU 120 that is newly registered in addition to the ONU 120 (1) (FIG. 1). In addition, ONU 120 (2), ONU 120 (3), and ONU 120 (n) are also newly registered.) In parallel with ONU 120 (1), authentication registration of new ONU 120 and assignment of identification slot 21 (in FIG. The identification slots 21 (2), 21 (3), and 21 (n) are assigned to the ONU 120 (2), ONU 120 (3), and ONU 120 (n), respectively, and the process of creating / saving the identification slot information is performed. Done.

  In the GE-PON system 100 of the present embodiment, a quantization window 20 and a free discovery window 30 are provided in the discovery window 10, and each ONU 120 is assigned to each of a predetermined number of identification slots 21 that are quantized in the quantization window 20. As a result, the recovery process can be performed collectively for the plurality of ONUs 120 that have been registered for authentication before the occurrence of a failure such as communication disconnection as follows. As a result, the time required for the recovery of the GE-PON system 100 can be significantly reduced as compared with the conventional case. For example, a discovery window having a time width of about several hundreds of μs is used several times to several tens of times in order to allow all ONUs to communicate data in the conventional recovery processing. In this embodiment, however, a single discovery window is used. It becomes possible to re-register all ONUs. In addition, when there is a free time in the discovery window, the registration processing time can be further shortened. Here, “re-registration” in the present invention refers to data communication using slot information that has been registered once.

  The recovery processing after communication disconnection in the GE-PON system 100 will be described below with reference to FIG. FIG. 4 is a process explanation diagram at the time of restoration showing the restoration method of the GE-PON system of the present embodiment. When the failure is removed and recovery is possible, the MPCP processing unit 111 of the OLT 110 first transmits the first GATE signal 51 to each ONU 120.

  In the ONU 120 that has been registered for authentication before the occurrence of the failure, when the GATE signal 51 is received, the recovery processing unit 123 reads the identification slot information from the ONU-side storage unit 124 and the recovery delay time included in the identification slot information (for example, the ONU 120 The restoration delay time of (1) is indicated by reference numeral 57 in FIG. The link processing unit 121 returns the registration request signal 52 to the OLT 110 after being delayed by the recovery delay time input from the recovery processing unit 123. As a result, the registration request signal 52 transmitted from each ONU 120 reaches each identification slot 21 of the quantization window 20 assigned to each ONU 120.

  When the return of the registration request signal 52 to each identification slot 21 of the quantization window 20 is completed, the ONU restoration unit 113 of the OLT 110 performs the identification slot 21 of each quantization window 20 with respect to the first GATE signal 51 after restoration. It is confirmed whether or not the registration request signal 52 is returned. Then, authentication registration is performed again with respect to the ONU 120 corresponding to the identification slot 21 to which the registration request signal 52 is returned using the respective identification slot information. As a result, the ONU 120 that has been authenticated and registered again establishes the PON link and resumes data communication.

  As described above, in the recovery method of the GE-PON system 100 according to the present embodiment, when the first GATE signal 51 after recovery is received for the ONU 120 that has been authenticated and registered before the failure occurs, the identification assigned to each The registration request signal 52 is returned to the slot 21, and there is no possibility that the registration request signals 52 from two or more ONUs 120 collide. Accordingly, the ONU recovery unit 113 of the OLT 110 can detect recoverable ONUs 120 at a time and restart data communication. As a result, the MPCP processing for the recoverable ONU 120 can be omitted, and the recovery processing time can be significantly shortened compared to the conventional case.

  On the other hand, for the ONU 120 newly registered at the time of recovery (ONU 120 (i) in the example shown in FIG. 4 corresponds to this), the MPCP processing unit 111 of the OLT 110 and the ONU 120 (i The normal MPCP processing is performed with the link processing unit 121. That is, for the first GATE signal 51 after restoration, the link processing unit 121 of the ONU 120 (i) transmits the registration request signal 52 to the OLT 110 after a random delay time determined to reach the free discovery window 30. . Thereafter, the MPCP process described above is performed to establish a PON link between the OLT 110 and the ONU 120 (i), and an unused identification slot 21 is assigned to the ONU 120 (i). Further, identification slot information related to the ONU 120 (i) is created by the slot information setting unit 112, and this identification slot information is transmitted to the ONU 120 (i) and shared with the OLT 110.

  Since the MPCP processing of the new ONU 120 (i) is performed using the free discovery window 30 separated from the quantization window 20 used for the restoration processing of the registered ONU 120, the signal from the new ONU 120 (i) Can collide with a signal from the registered ONU 120, and the authentication registration of the new ONU 120 (i) can be completed in a short time.

  When the number of ONUs 120 that have been registered for authentication reaches the maximum number of ONUs 120 that can be connected to the OLT 110, no new ONU 120 is registered for authentication. Therefore, it is not necessary to use the free discovery window 30. Therefore, when the number of registered ONUs 120 reaches the maximum number, the free discovery window 30 can be deleted to shorten the time width of the discovery window 10, thereby further shortening the recovery processing time. Is possible.

  In the discovery window 10 illustrated in FIG. 4, the identification slots 21 to which the ONUs 120 are assigned are selected with an interval (leaving unused identification slots 21 in between). On the other hand, as shown in FIG. 5, the ONUs 120 can be assigned in order from the smallest slot number. In particular, it is preferable to assign the ONU 120 having a remarkably short distance to the identification slot 21 having the smallest slot number and assign the ONU 120 having a remarkably long distance to the identification slot 21 having the large slot number. Accordingly, the delay time can be shortened so that the registration request signal 52 is returned to the identification slot 21 having the smallest slot number in order from the ONU 120 having the shortest distance. As a result, the time until the registration request signal 52 is returned from all the target ONUs 120 can be shortened, and the recovery of the GE-PON system 100 can be completed early.

  In the above description, the case where only one LLID is set for each ONU has been described. However, the number of LLIDs set for each ONU is not limited to one. For example, as illustrated in FIG. The above LLID (hereinafter referred to as multi-LLID) may be set. Process explanatory diagrams of this embodiment in this case are illustrated in FIGS. FIG. 12 corresponds to the process explanatory diagram shown in FIG. 1, and FIG. 13 corresponds to the recovery process explanatory diagram shown in FIG. FIG. 14 shows a diagram corresponding to the conventional process explanation diagram at the time of recovery shown in FIG.

(Second Embodiment)
A GE-PON system according to a second embodiment of the present invention will be described with reference to FIG. FIG. 6 is a restoration startup process diagram for explaining the restoration method of the GE-PON system of the present embodiment. In the recovery method of the present embodiment, before the first GATE signal 51 after recovery is transmitted from the OLT 110, the registration management table management unit provided in the OLT 110 transmits the registration management table to all ONUs 120 by broadcast. . The registration management table created by the registration management table management unit has at least the identification number of the ONU 120 that has been registered for authentication. As the identification number, for example, an LLID or a MAC address can be used.

  Each ONU 120 is provided with a registration management table check unit. When the registration management table check unit receives the registration management table, it determines whether or not its own identification number is included in the registration management table. When the own identification number is included in the registration management table, it is determined that the ONU 120 has been registered. When the registration management table check unit of the ONU 120 that has been determined to have received the first GATE signal 51 after restoration is received from the OLT 110, the registration request signal is delayed by the restoration delay time read from the ONU side storage unit 124. 52 is returned. As a result, the registration request signal 52 is returned to the identification slot 21 allocated to the ONU 120 concerned. Since the registration request signal 52 returned from the ONU 120 determined to be registered has a recovery delay time set to be transmitted to each identification slot 21, it does not collide with another registration request signal 52. The recovery process can be performed at high speed.

  The registration management table used to determine whether or not each ONU 120 is registered has identification slot information of all ONUs 120 stored in the OLT storage unit 114 of the OLT 110 as registration information. The registration management table check unit of each ONU 120 may determine whether or not it is registered by comparing with the identification slot information stored in its own ONU storage unit 124.

  On the other hand, when it is determined that the identification number of the ONU 120 is not included in the registration management table, the registration management table check unit of the ONU 120 determines that authentication registration is newly required, and requests the free discovery window 30 to register. A signal 52 is returned. Thereby, MPCP processing by the OLT 110 is performed, and after completion of the MPCP processing, processing for assigning the identification slot 21 and creating / saving the identification slot information is performed. Since the MPCP processing of the new ONU 120 is performed using the free discovery window 30 that is separated from the quantization window 20 used for the recovery processing of the registered ONU 120, the signal from the new ONU 120 is transmitted from the registered ONU 120. The authentication registration of the new ONU 120 can be completed in a short time.

  In the GE-PON system of the present embodiment, it has been described above that at the time of recovery, it is determined whether the ONU 120 is already registered for authentication or the ONU 120 that requires new authentication registration using the registration management table. Not only when the system is restored, but also when performing authentication registration processing, a registration management table may be transmitted to all ONUs 120 to check whether each ONU 120 has been registered. Alternatively, the registration management table may be transmitted from the OLT 110 to all the ONUs 120 at a predetermined cycle (for example, a cycle of 300 s which is the aging time of the MAC address learning table) to periodically check the registered ONUs 120. Good.

  Further, when the registration management table is transmitted to each ONU 120 and the above determination is made, if there is an ONU 120 to which the registration request signal is not returned in the assigned identification slot 21, or for a certain period (for example, on the order of several hundred seconds) Period) When there is an ONU 120 with no response, the identification information of the ONU 120 is deleted from the registration management table, and the identification slot 21 assigned to the ONU 120 is initialized to unused. The identification information is deleted from the registration management table, and the ONU 120 newly performs authentication registration processing.

  As described above, by using the registration management table to determine whether each ONU 120 has already been registered for authentication, the latest authentication registration information (identification information of all ONUs 120) stored in the OLT 110 and each ONU 120 are The stored identification information can be matched.

(Third embodiment)
A GE-PON system according to a third embodiment of the present invention will be described with reference to FIG. FIG. 7 is a block diagram illustrating a configuration of the GE-PON system 300 according to the present embodiment. In the GE-PON system 300 of the present embodiment, the ONU 320 is provided with a reset switch 301 for deleting (resetting) the identification slot information stored in the ONU side storage unit 324 of the ONU 320.

  An ONU connected to another GE-PON system may be relocated to the GE-PON system in operation. An ONU connected to another GE-PON system stores the identification number and identification slot information set in the other system in the ONU-side storage unit even in a power-off state. For this reason, when connected to the GE-PON system at the transfer destination, the identification number and identification slot information stored in the ONU side storage unit may be used as they are. In particular, if the slot number of the identification slot written in the identification slot information is already assigned to another ONU of the relocation destination GE-PON system, there arises a problem that a collision occurs with this ONU. .

  In order to solve the above problem, it is necessary to clear the identification number and identification slot information stored in the relocated ONU so that MPCP processing for new registration can be performed in the same way as a new ONU. is there. Therefore, in the GE-PON system 300 of this embodiment, the ONU 320 is provided with a reset switch 301. When the ONU 320 is moved to another GE-PON system 300, the identification number and the identification slot information stored in the ONU side storage unit 324 are cleared using the reset switch 301. As a result, the transferred ONU 320 is newly registered in the transfer destination GE-PON system 300, and the identification slot 21 that does not collide with other ONUs 320 is assigned. The reset switch 301 is also useful when the ONU 320 fails and cannot be controlled from the OLT 310.

  In addition, the description in this Embodiment shows an example of the GE-PON system which concerns on this invention, and is not limited to this. The detailed configuration and detailed operation of the GE-PON system in the present embodiment can be changed as appropriate without departing from the spirit of the present invention.

DESCRIPTION OF SYMBOLS 10 Discovery window 20 Quantization window 21 Identification slot 30 Free discovery window 100, 300 GE-PON system 110 Station side apparatus (OLT)
111 MPCP processing unit 112 Slot information setting unit 113 ONU recovery unit 114 OLT side storage unit 120 Subscriber side terminal device (ONU)
121 Link Processing Unit 122 OAM Processing Unit 123 Recovery Processing Unit 124 ONU Storage Unit 130 Splitter 301 Reset Switch

Claims (11)

A GE-PON system in which a station-side device and a plurality of subscriber-side terminal devices are connected via an optical fiber via a branching unit,
The station side device is:
A discovery window management unit for managing a discovery window used to authenticate and register the subscriber-side terminal device, having a quantization window divided into a predetermined number of identification slots and a free discovery window;
An MPCP processing unit configured to set an identification number of the subscriber-side terminal device by performing an MPCP process for authenticating and registering the subscriber-side terminal device;
Slot information setting for assigning any one of the identification slots to the subscriber-side terminal device authenticated and registered by the MPCP process and creating identification slot information in which at least the identification number is associated with the slot number of the identification slot And
Check whether a registration request signal is returned to the identification slot after restoration, and restore the subscriber side terminal device that authenticates and registers the subscriber side terminal device corresponding to the identification slot to which the registration request signal is returned And
A station side device side storage unit for storing the identification slot information,
The subscriber side terminal device is:
A link processing unit that performs the MPCP processing with the MPCP processing unit and receives the identification number from the MPCP processing unit;
A subscriber-side terminal device-side storage unit;
An OAM processing unit that reads out the slot information from the OAM frame transmitted from the station side device and stores it in the subscriber side terminal device side storage unit;
A recovery processing unit that reads the identification slot information from the subscriber side terminal device side storage unit when performing recovery processing and outputs a recovery delay time to the link processing unit, and
When the station side device newly registers and registers the subscriber side terminal device,
The MPCP processing unit transmits a GATE signal, performs MPCP processing based on the registration request signal returned from the link processing unit of the new subscriber terminal device to the free discovery window, and assigns the identification number The slot information setting unit allocates the identification slot that is not allocated to another subscriber-side terminal device to the new subscriber-side terminal device, and stores the identification slot information in the station-side device-side storage unit. Save and set the slot information in the OAM frame and send it to the new subscriber terminal,
When performing recovery processing of the GE-PON system,
When the restoration processing unit receives the GATE signal first transmitted from the MPCP processing unit during the restoration processing, the restoration processing unit outputs the restoration delay time to the link processing unit, and the link processing unit follows the restoration delay time. The registration request signal is returned to the identification slot, and the subscriber-side terminal device restoration unit authenticates again to the subscriber-side terminal device that has returned the registration request signal to the identification slot using the identification slot information. A GE-PON system characterized by registration. The MPCP processing unit sets a plurality of identification numbers in the subscriber side terminal device,
The GE-PON system according to claim 1, wherein the slot information setting unit associates a slot number of the identification slot with each identification number. The slot information setting unit calculates the recovery delay time using distance information to the subscriber-side terminal device, and includes the calculated recovery delay time in the identification slot information. The GE-PON system according to claim 1 or 2. When the subscriber terminal device that has received the first GATE signal does not store the identification slot information,
The GE-PON system according to claim 1 or 2, wherein the link processing unit returns the registration request signal to the free discovery window. The slot number is attached in order from the identification slot at the head of the quantization window,
3. The GE-PON system according to claim 1, wherein the slot information setting unit assigns the identification slots in order of increasing distance to the subscriber-side terminal device. The discovery window management unit deletes the free discovery window when the maximum number of subscriber-side terminal devices that can be connected to the station-side device are authenticated and registered, and the identification slot is assigned to each. The GE-PON system according to claim 1 or 2. The station side device is:
Create a registration management table describing at least the identification numbers of all the subscriber-side terminal devices that have been authenticated and registered, and transmit the registration management table to all the subscriber terminal devices when a predetermined condition is satisfied A registration management table management unit for
The subscriber terminal device
When the registration management table is received, the identification number to be stored is compared with the identification number described in the registration management table, and the identification number to be stored is the number of the identification number described in the registration management table. If it matches any one, the registration request signal is returned to the assigned identification slot, and if the stored identification number does not match any of the identification numbers in the registration management table, the registration request signal is sent to the free identification slot. The GE-PON system according to claim 1, further comprising a registration management table check unit that returns to the discovery window. The GE-PON system according to claim 7, wherein the predetermined condition is when a restoration process of the GE-PON system is performed. The GE-PON system according to claim 7, wherein the predetermined condition is a predetermined period and a time when the registration management table is updated in the station side apparatus. The registration management table management unit includes:
10. The identification number of the subscriber terminal device that does not return the registration request signal even if a predetermined time has elapsed after transmitting the registration management table, is deleted from the registration management table. The GE-PON system according to any one of the above. The subscriber side terminal device is:
The GE-PON system according to claim 1, further comprising a reset switch for deleting the identification slot information stored in the subscriber-side terminal device-side storage unit.

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