JP4818283B2 - PON switching method - Google Patents

Description

The present invention relates to a PON (Passive Optical Network) user apparatus and a PON switching method using the user apparatus.

  In order to realize optical communication at a lower cost, a PON type optical access system has become widespread. This PON is provided with a branching device such as an optical splitter (optical coupler) in the middle of an optical fiber connected from the in-station device (master unit) side of the telephone station or center station to the user device (slave unit) side of the user's house. A plurality of user devices are connected via this branching device. In this way, one in-station device and a plurality of user devices are communicably connected, and one optical fiber is shared by a plurality of user devices, thereby realizing optical communication at low cost.

  In such a PON, a plurality of types (methods) of PONs have been developed and put into practical use in order to increase the speed and functionality (for example, refer to Patent Document 1). For this reason, for example, when an old PON is used, it may be necessary to switch to a new PON in order to increase the speed. In such a case, the PON is conventionally switched as follows.

  As a first method, as shown in FIG. 8, an existing PON, that is, an old OLT (Optical Line Terminal) 110, and all user homes H connected to the OLT 110 are used. The operation of the old ONU (Optical Network Unit, user device) 120 is stopped. Then, all the old ONUs 120 are replaced with the new ONUs 220, and the old OLT 110 is replaced with the new OLT 210, and the operation is resumed. In addition, the code | symbol C in a figure is the closure (connection box) installed on the utility pole.

As a second method, first, as shown in FIG. 9, a new PON 200 is constructed in the same network (transmission system) as the existing PON, that is, the old PON 100. Here, in the old PON 100, the old OLT 110 is installed, and in the new PON 200, the new OLT 210 is installed. Next, adjust the construction date and time according to the convenience of the user, replace the old ONU 120 of the user home H with the new ONU 220, and further disconnect the lead-in wire H1 of the user home H from the optical fiber core 101 of the old PON 100 And connected to the optical fiber core wire 201 of the new PON 200. Such replacement, connection work, and the like are performed for all user homes H. Thereafter, the core wire 101 of the old PON 100 is connected straight, the optical splitter 102 is removed, and the core wire 101 is restored to its original state.
Japanese Patent Laid-Open No. 2007-243796

  By the way, in the first method described above, it is necessary to replace all the old ONUs 120 and the old OLT 110 in a state where there is no spare PON (core wire). Must be stopped. For this reason, it is necessary to shorten the construction period as much as possible by performing construction including replacement at one time. To that end, it is necessary to match the replacement date and time of all the old ONUs 120. However, since the replacement of the old ONU 120 is performed in the user home H, it is extremely difficult to set a date and time that is convenient for all users, and even if it can be set, an operator must be dispatched to each user home H. It requires a lot of workers.

  In the second method, it is necessary to construct a new PON 200 in parallel with the old PON 100. That is, in order to construct a new type of PON 200, as many spare cores 201 for switching as the number of users are necessary. If there are no spare cores 201, it is necessary to lay a new optical cable. In addition, it is necessary to adjust the construction date and time by listening to the convenience of all users, which is a great burden on both the user side and the construction contractor side. Furthermore, since the connection switching of the lead-in wire H1 is a pole work on the utility pole, it takes a lot of time, labor, and construction costs, and there is a risk of erroneous disconnection that mistakes the lead-in wire H1 and the core wire 101 to be separated. Is accompanied. Further, since the core wire 101 of the old PON 100 needs to be restored to its original state, and this operation is also a work on a pillar, a great amount of time, labor, and construction costs are required.

Therefore, an object of the present invention is to provide a PON switching method that can easily perform PON switching .

In order to achieve the above object, according to the first aspect of the present invention, a branching device is provided in an optical fiber that connects the intra-station device side and the user device side so as to communicate with each other. A method for switching connected PONs , wherein a plurality of types of communication means for communicating with a plurality of types of in-station devices, and the communication adapted to the in-station device based on a signal received from the in-station device and connecting means for the means for connecting to the station apparatus side, an apparatus comprising a hybrid user equipment, in a state where the existing station apparatus is being operated, replace the respective user equipment existing in the hybrid user device, all of the After the user device is replaced, the existing in-station device is replaced with a new in-station device.

According to the present invention, when an existing user apparatus is replaced with a hybrid user apparatus in a state where the existing in-station apparatus is in operation, communication adapted to the existing in-station apparatus is performed based on a signal received from the existing in-station apparatus. The means is connected to the in-station device side, and the existing in-station device and the hybrid user device can communicate with each other. Subsequently, after the replacement to all hybrid user devices is completed, when the existing in-station device is replaced with a new in-station device, communication means adapted to the new in-station device based on the signal received from the new in-station device Are connected to the in-station device side, and the new in-station device and all hybrid user devices can communicate with each other.

According to the first aspect of the present invention, it is easy to switch the PON by simply replacing the existing user device with the hybrid user device (this user device) and replacing the existing in-station device with a new PON in-station device. Can be done. As a result, there is no need for a spare core wire for switching or a new optical cable, no work on the pole or restoration of the core wire is required, and it is possible to reduce the schedule adjustment with the user. Cost can be significantly reduced. In addition, since there is no need to disconnect and reconnect the core, there is no risk of erroneous disconnection of the core.

  In addition, while an existing user device is being replaced with this user device, other existing user devices can communicate with the existing in-station device, and after replacement with this user device, Communication with the in-station device becomes possible. That is, the communication is hardly stopped by replacing the user device. Furthermore, when an existing in-station device is replaced with a new in-station device, the new in-station device and this user device can immediately communicate with each other based on a signal received from the new in-station device, and communication is stopped by replacing the in-station device. There is almost nothing to do.

  The present invention will be described below based on the illustrated embodiments.

  FIG. 1 is a schematic block diagram showing a hybrid ONU (PON user equipment) 1 according to an embodiment of the present invention. In this embodiment, the hybrid ONU 1 is a user device that is communicably connected to an OLT (intra-station device) via an optical fiber in two types (two types) of PONs. A case will be described in which the present invention is applied to a new PON that is faster and more functional than a PON. The hybrid ONU 1 mainly includes an optical transmission / reception interface unit 11, an optical reception unit 12, an optical transmission unit 13, a signal system determination unit 14, a first switching control unit 15, and an old PON function unit (communication means). 16, a new PON function unit (communication means) 17, a second switching control unit 18, and a terminal interface unit 19.

  The optical transmission / reception interface unit 11 is an interface for transmitting / receiving optical signals to / from OLTs 2 and 3 (to be described later). The optical transmission / reception interface unit 11 receives downstream optical signals from the OLTs 2 and 3 and transmits upstream optical signals to the OLTs 2 and 3. is there. The optical receiving unit 12 transmits the downstream optical signal transmitted from the optical transmission / reception interface unit 11 to the old PON function unit 16 or the new PON function unit 17 via the first switching control unit 15 and at the same time, a signal system determination unit. 14 is a transmission unit for transmission to the network. The optical transmission unit 13 is a transmission unit that transmits the upstream optical signal transmitted from the old PON function unit 16 or the new PON function unit 17 via the first switching control unit 15 to the optical transmission / reception interface unit 11.

  The signal system determination unit 14 determines the type of PON of the downstream optical signal based on the downstream optical signal transmitted from the optical reception unit 12, and the first switching control unit 15 and the second switching controller 15 based on the determination result. The switching control unit 18 is controlled. That is, from the signal configuration (data frame configuration) of the downstream optical signal, whether the downstream optical signal is an optical signal based on the old PON (from the old OLT 2) or an optical signal based on the new PON (from the new OLT 3) judge. When it is determined that the PON is an old PON, a control command for connection to the old PON function unit 16 is transmitted to the switching control units 15 and 18, and when the PON is determined to be a new PON, the new PON function unit 17 is transmitted. Is transmitted to the switching control units 15 and 18.

  The first switching control unit 15 switches the optical path of the optical signal, and the optical receiving unit 12 and the optical transmitting unit 13 are changed from the old PON function unit 16 or the new PON based on a control command from the signal system determination unit 14. This is connected to the function unit 17. Similarly, the second switching control unit 18 switches the signal path of the electrical signal (digital data signal), and the terminal interface unit 19 is connected to the old PON based on the control command from the signal system determination unit 14. This is connected to the function unit 16 or the new PON function unit 17. Here, when the same control command as the control command previously transmitted from the signal method determination unit 14 is transmitted, the switching control units 15 and 18 do not perform connection switching. That is, the signal system determination unit 14 determines all downstream optical signals. When the types of PONs based on the downstream optical signals are the same, that is, as described later, after communication is established, switching is performed. Connection control is not performed in the control units 15 and 18. Note that after the communication is established, the downstream optical signal may not be transmitted from the optical receiving unit 12 to the signal system determination unit 14. As described above, in this embodiment, the signal system determination unit 14, the first switching control unit 15, and the second switching control unit 18 constitute connection means.

  The old-type PON function unit 16 is a function unit for communicating with the old-type PON OLT 2 and has a configuration equivalent to that of a normal ONU in the old-type PON (such as a PON interface function and an ONU authentication function), and an optical signal A reception processing unit 161 that converts the signal into an electrical signal and a transmission processing unit 162 that converts the electrical signal into an optical signal. Similarly, the new PON function unit 17 is a function unit for communicating with the OLT 3 for the new PON, and has a functional configuration equivalent to that of a normal ONU in the new PON, and includes a reception processing unit 171 and a transmission processing unit 172. It has. Thus, in this embodiment, two types of PON function units 16 and 17 for communicating with two types (two types) of PON OLTs 2 and 3 are provided. Then, based on the downstream optical signal received from the old OLT 2 or the new OLT 3 by the signal method determination unit 14 and the switching control units 15 and 18, the old PON function unit 16 conforming to the transmission source OLT 2 or OLT 3 is used. Alternatively, the new PON function unit 17 is connected to the OLTs 2 and 3 side.

  The terminal interface unit 19 is an interface for transmitting and receiving electrical signals to and from the terminal device 4 such as a personal computer installed in a user home H to be described later, and receives uplink data from the terminal device 4. The downlink data is transmitted to the terminal device 4.

  Next, a processing flow with the OLT when the hybrid ONU 1 having such a configuration is started will be described with reference to a timing chart shown in FIG. Here, it is assumed that the old OLT 2 for the old PON or the new OLT 3 for the new PON is installed as the OLT.

  First, when the hybrid ONU 1 is activated (step S1), an “unregistered transmission permission” signal is transmitted from the OLT to the hybrid ONU 1 (step S2). In response, the hybrid ONU 1 determines whether the OLT that transmitted the “unregistered transmission permission” signal is the old OLT 2 or the new OLT 3, that is, whether the PON is the old or new (step S3). That is, as described above, the signal system determination unit 14 determines the type of PON and controls the switching control units 15 and 18 to connect (activate) the old PON function unit 16 or the new PON function unit 17. Next, a “registration request” signal generated by the connected old PON function unit 16 or new PON function unit 17 is transmitted to the OLT (step S4). At this time, in the case of the old PON function unit 16, a “registration request” signal by the old PON format is transmitted, and in the case of the new PON function unit 17, the “registration request” signal by the new PON format is sent. Send.

  Subsequently, in the OLT, an LLID (Logical Link IDentification, channel) is allocated to the hybrid ONU 1 (step S5), and a “registration notification” signal (with LLID) indicating that the LLID has been registered is transmitted to the hybrid ONU 1. (Step S6). Furthermore, a “transmission permission” signal (with LLID) indicating that communication is possible with the assigned LLID is transmitted from the OLT to the hybrid ONU 1 (step S7). In response, a “registration notification confirmation” signal (with LLID) is transmitted from the hybrid ONU 1 to the OLT (step S8).

  Here, the operation and state of the hybrid ONU 1 in the processing flow as described above will be described with reference to the flowchart of FIG. First, when the power is turned on to start up (step S11), the optical signal reception waiting state is set (step S12). Next, when an “unregistered transmission permission” signal is received from the OLT (“Y” in step S12) and the optical signal is an old PON (“Y” in step S13), as described above. The old PON function unit 16 is connected (actuated) and starts to operate as an old PON ONU (step S14). That is, a “registration request” signal by the old PON format is transmitted to the old OLT 2 to establish communication with the old OLT 2 (step S15), and data communication is started (step S16).

  On the other hand, when the received optical signal is not the old PON (“N” in step S13) but a new PON (“Y” in step S17), the new PON function unit 17 is connected as described above. (Operation) is started to start operation as a new type of PON ONU (step S18). That is, a “registration request” signal by the new PON format is transmitted to the new OLT 3 to establish communication with the new OLT 3 (step S19), and data communication is started (step S16). If it is not any PON ("N" in step S17), the process returns to step S12 and enters an optical signal reception waiting state.

  Subsequently, when communication failure occurs after the start of data communication or communication interruption occurs due to replacement of the OLT as will be described later (step S20), reset / restart (step S21) is performed. The process returns to S12 and enters an optical signal reception waiting state.

  Next, a PON switching method for switching PONs using such a hybrid ONU 1 will be described. Here, a case where an old PON is switched to a new PON will be described. That is, as shown in FIG. 4, in the state where the old PON is constructed, the old OLT 2 is installed in the center station (acquisition station), and the old PON ONU 5 is installed in each user home H. . An optical splitter 7 is provided in the optical fiber core wire 6 that connects the old OLT 2 and the old ONU 5 so that they can communicate with each other, and a plurality of old ONUs 5 are connected via the optical splitter 7. In addition, the code | symbol C in a figure is the closure installed on the utility pole.

  First, the old ONU 5 in each user's house is replaced with the hybrid ONU 1 in a state where such an old PON is operated, that is, in a state where the existing old OLT 2 is operated. Immediately after this replacement, the hybrid ONU 1 functions as an old PON ONU through the above-described startup process, and communication with the old OLT 2 becomes possible. Here, when replacing the hybrid ONU 1, it is necessary to hear about the convenience of each user, but it does not affect other users, so it is not necessary to match the convenience (work date and time) of all users. These may be performed individually according to the convenience of each user. Further, when the old ONU 5 fails, it may be replaced with the hybrid ONU 1. Further, when an optical outlet (such as an optical connector closet) that does not have speciality is applied to the ONU replacement work, the user can perform the operation himself. In this way, the hybrid ONU 1 can be replaced flexibly and easily.

  Next, as shown in FIG. 5, after all the old ONUs 5 connected to the old OLT 2 have been replaced, the old OLT 2 is replaced with a new OLT 3 at the center station. That is, as shown in FIG. 6, the optical fiber 6 is detached from the old OLT 2 and connected to the new OLT 3 to start the new OLT 3. As a result, each hybrid ONU 1 is restarted, and after the startup process as described above, each hybrid ONU 1 functions as an ONU for a new type of PON. As shown in FIG. The OLT 3 and the hybrid ONU 1 can communicate with each other. Here, connection switching (replacement of optical cords) from the old OLT 2 to the new OLT 3 is performed in a time zone in which all users have a low communication frequency, for example, at midnight, and the time required for switching is about 5 to 10 seconds. Therefore, there is little influence on each user.

  As described above, according to this hybrid ONU1, since it can be automatically applied to both new and old PONs, that is, communication can be automatically performed according to the OLTs 2 and 3 installed in the center station. It is possible to easily switch the PON. That is, according to the PON switching method as described above, the PON can be easily switched only by replacing the old ONU 5 with the hybrid ONU 1 and replacing the old OLT 2 with the new OLT 3. As a result, there is no need for a spare core or a new optical cable for switching, no work on the pole or restoration of the core is required, the schedule adjustment with the user is reduced, and the labor, time and cost for switching the PON are reduced. Can be significantly reduced. Moreover, there is no risk of accidental disconnection of the core wire.

  In addition, while the old ONU 5 of a certain user is being replaced, the old ONU 5 or the hybrid ONU 1 of another user is in a state in which communication with the old OLT 2 is possible. Communication is possible automatically (immediately). That is, the communication is hardly stopped by replacing the ONU. Similarly, if the old OLT 2 is replaced with the new OLT 3, the new OLT 3 and the hybrid ONU 1 can immediately communicate with each other based on the signal received from the new OLT 3, and communication may be stopped by replacing the OLT. rare.

  By the way, although the case where the existing old PON is switched to the new PON has been described, even when a new PON is constructed, the PON can be easily switched by applying the hybrid ONU 1. That is, when a new PON is newly constructed, the old OLT 2 is installed in the center station, and the hybrid ONU 1 is installed in each user home H, and the operation is started. Then, when the peripheral equipment environment is prepared and the transition to the new PON is made, the old OLT 2 may be replaced with the new OLT 3. As a result, as described above, each hybrid ONU 1 functions as an ONU for a new PON, and a new PON is constructed.

  Although the embodiment of the present invention has been described above, the specific configuration is not limited to the above embodiment, and even if there is a design change or the like without departing from the gist of the present invention, Included in the invention. For example, in the above embodiment, the signal system determination unit 14 determines the type of PON based on the signal configuration of the optical signal and controls the switching control units 15 and 18, but the following may be used. . That is, when the hybrid ONU 1 is started, one of the old PON function unit 16 and the new PON function unit 17 is always connected, and when the communication is not established, the other new PON function unit 17 or the old PON function unit 16 is connected. You may do it. In addition, the old PON function unit 16 and the new PON function unit 17 have different configurations (separate bodies). However, the PON function units 16 and 17 are integrally configured so that the connection is switched inside. Also good. Furthermore, although the case where two types of PONs are switched has been described, it is needless to say that the present invention can be applied to the case where three or more types of PONs are switched.

It is a schematic block diagram of a hybrid ONU according to an embodiment of the present invention. It is a timing chart which shows the processing flow with OLT at the time of starting of hybrid ONU of FIG. It is a flowchart which shows the action | operation and state of hybrid ONU in the processing flow of FIG. In the PON switching method according to the embodiment of the present invention, it is a schematic configuration diagram showing a state in which an old PON is constructed. FIG. 5 is a schematic configuration diagram illustrating a state in which all old ONUs 5 are replaced with hybrid ONUs after the state of FIG. 4. FIG. 6 is a schematic configuration diagram illustrating a state in which an old OLT is switched to a new OLT after the state of FIG. 5. It is a schematic block diagram which shows the state which switched the old type OLT to the new type OLT after the state of FIG. It is a schematic block diagram which shows the 1st conventional method which switches PON. It is a schematic block diagram which shows the 2nd conventional method which switches PON.

Explanation of symbols

1 Hybrid ONU (PON user equipment)
DESCRIPTION OF SYMBOLS 11 Optical transmission / reception interface part 12 Optical reception part 13 Optical transmission part 14 Signal system determination part (connection means)
15 1st switching control part (connection means)
16 Old PON function unit (communication means)
17 New PON function unit (communication means)
18 Second switching control unit (connection means)
19 Interface unit for terminals 2 Old OLT (station equipment)
3 New OLT (in-station equipment)
5 Old ONU (user equipment)
6 Optical fiber core C Closure H User's house

Claims (1)

A PON switching method in which a branch device is provided in an optical fiber that connects the in-station device side and the user device side so that communication is possible, and a plurality of user devices are connected via the branch device,
A plurality of types of communication means for communicating with a plurality of types of PON in-station devices, and a connection means for connecting the communication means suitable for the in-station device to the in-station device side based on a signal received from the in-station device And a device comprising a hybrid user device,
In a state where the existing in-station device is in operation, each existing user device is replaced with the hybrid user device,
A PON switching method , wherein after replacing all user devices, the existing in-station device is replaced with a new in-station device.

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