JP6470161B2 - Ring type optical access network system, station side device, subscriber side device, station side optical switch, subscriber side optical switch, controller, optical communication method - Google Patents

Description

  The present invention relates to a ring-type optical access network system, a station side device, a subscriber side device, a station side optical switch, a subscriber side optical switch, a controller, and an optical communication method.

  Users of high-speed Internet in FTTH (Fiber To The Home) and mobile services continue to rise and are indispensable for people's lives. On the other hand, the FTTH / mobile / corporate service networks are independently constructed, which is inefficient in terms of operation. Therefore, an access network that accommodates a plurality of services with one device has been proposed (see, for example, Non-Patent Document 1). Further, in order to realize an access network capable of accommodating multiple services, WDM (Wavelength Division Multiplex) / TDM (Time Division Multiplexing) -PON (Passive Optical Networks) using a plurality of wavelengths is used as ITU-T (International Telecommunication). Standardized by Union Telecommunication Standardization Sector) (see Non-Patent Document 2, for example).

  On the other hand, by accommodating a plurality of services in one network, the range of the influence of each service due to the failure becomes larger than the range of the influence due to the failure in the existing network. In current access networks, redundancy is possible by duplexing fibers and devices. However, since it is inefficient to duplicate all the fibers and devices, efficient redundancy can be achieved by constructing a ring access network using an optical switch as in Non-Patent Document 1. .

  Also, depending on the failure location, there are cases where it is possible to cope by switching to a redundant path, and there are cases where it is necessary to move to a different station side device, so it is necessary to select an appropriate countermeasure according to the failure location.

S. Kimura, "Elastic Lambda Aggregation Network (EλAN) -Proposal for Future Optical Access Network-," OECC2013, WP4-4, 2013 ITU-T G. 989.1

  In a ring access network using WDM-PON and an optical switch, when a fiber failure occurs, if the location of the failure cannot be identified, it is necessary to go to the site where the failure occurred and confirm the failure remotely. There is a problem that it cannot be dealt with properly.

  The present invention has been made in view of such circumstances, and a ring-type optical access network system and station-side device that can restore communication by switching to an appropriate redundant path without going to the site when a fiber failure occurs An object of the present invention is to provide a subscriber-side device, a station-side optical switch, a subscriber-side optical switch, a controller, and an optical communication method.

  One aspect of the present invention is a ring-type optical access network including a station-side optical switch connected to a station-side apparatus, a subscriber-side optical switch connected to a subscriber-side apparatus, and a controller that controls the system in an integrated manner. The station-side device is connected to the controller, communicates with the subscriber-side device in accordance with an instruction from the controller, and notifies the controller of communication disconnection when communication disconnection occurs. The station side optical switch is connected to the controller and distributes the signals of the station side device and the subscriber side device to each port according to instructions of the controller, When the optical signal of the side device cannot be received, the controller is notified, and the subscriber side optical switch is connected to the controller, and the controller According to the instructions, the signals of the station side device and the subscriber side device are distributed to each port, and the controller is notified of the communication interruption of the station side device in the event of a fiber failure. When the optical signal from the station side device can be received, the route of the station side device and the subscriber side device in which communication interruption has occurred is changed to a redundant route, and the station side optical switch is changed from the station side device. In the ring type optical access network system, the communication setting information of the station side device is transferred to another station side device and an instruction to change the route is output when the optical signal of the above is not received.

  One aspect of the present invention is a ring-type optical access network including a station-side optical switch connected to a station-side apparatus, a subscriber-side optical switch connected to a subscriber-side apparatus, and a controller that controls the system in an integrated manner. In the system, an optical signal is transmitted / received to / from the subscriber side device at a plurality of wavelengths, a communication disconnection is notified to the controller, and communication setting information is transmitted and received according to an instruction from the controller and a wavelength to be communicated is changed. A plurality of optical signal transmitting units for transmitting optical signals to the subscriber side device, a plurality of optical signal receiving units for receiving optical signals from the subscriber side device, and the subscriber side device. An optical wavelength multiplexing / demultiplexing unit that multiplexes and demultiplexes an optical signal used to communicate with the communication, a communication interruption detection unit that detects and notifies communication interruption when a communication interruption occurs due to a failure, and the subscriber Holding communication setting information with the device, a setting management unit for transmitting and receiving communication setting information according to instructions from the controller, a wavelength control unit for changing the wavelength according to instructions from the controller, and receiving instructions from the controller; A station-side device including a controller signal transmission / reception unit that transmits to the setting management unit or the wavelength control unit and transmits communication setting information from the setting management unit.

  One aspect of the present invention is a ring-type optical access network including a station-side optical switch connected to a station-side apparatus, a subscriber-side optical switch connected to a subscriber-side apparatus, and a controller that controls the system in an integrated manner. In the system, the subscriber-side device that performs transmission / reception of optical signals at a plurality of wavelengths with a single station-side device and changes to another wavelength when a communication loss is detected, detects the communication loss. A communication disconnection detection unit for notification, a wavelength control unit for receiving a notification of the communication disconnection detection unit and transmitting a wavelength change instruction, and a wavelength tunable optical signal transmission unit for changing a wavelength to be transmitted according to the instruction of the wavelength control unit And a wavelength tunable optical signal receiving unit that changes a wavelength to be received in accordance with an instruction from the wavelength control unit.

  One aspect of the present invention is a ring-type optical access network including a station-side optical switch connected to a station-side apparatus, a subscriber-side optical switch connected to a subscriber-side apparatus, and a controller that controls the system in an integrated manner. In the system, the station-side device, the station-side optical switch, the subscriber-side optical switch, and the controller are connected to change the output port for each wavelength according to the instructions of the controller, and one or more ports The station-side optical switch that detects a communication disconnection of an optical signal input at the station and notifies the controller of the communication disconnection, the station-side apparatus port connected to the station-side apparatus, and the station-side optical switch or the subscription Wavelength switching unit for changing a plurality of optical switch ports to be connected to the user side optical switch and a port to be output for each wavelength according to an instruction of the controller An optical demultiplexing unit that demultiplexes an optical signal input from the station side device port, and an optical unit that determines the presence or absence of an optical signal input from the optical demultiplexing unit and notifies the controller of communication disconnection when communication disconnection occurs. A station-side optical switch comprising: a detection unit; and a controller signal transmission / reception unit that receives an instruction from the controller, transmits the instruction to the wavelength switching unit, and transmits a communication disconnection notification received from the light detection unit to the controller. is there.

  One aspect of the present invention is a ring-type optical access network including a station-side optical switch connected to a station-side apparatus, a subscriber-side optical switch connected to a subscriber-side apparatus, and a controller that controls the system in an integrated manner. In the system, the subscriber-side light that is connected to the subscriber-side device, the station-side optical switch, the subscriber-side optical switch, and the controller and changes a port to be output for each wavelength according to an instruction of the controller A switch, a subscriber-side device port connected to the subscriber-side device, a plurality of optical switch ports connected to the station-side optical switch or the subscriber-side optical switch, and for each wavelength according to instructions of the controller A wavelength switching unit that changes a port to be output, and a controller signal that receives an instruction from the controller and transmits the instruction to the wavelength switching unit A subscriber-side optical switch with a receiver.

  One aspect of the present invention is a ring-type optical access network including a station-side optical switch connected to a station-side apparatus, a subscriber-side optical switch connected to a subscriber-side apparatus, and a controller that controls the system in an integrated manner. In the system, the controller that is connected to the station-side device, the station-side optical switch, and the subscriber-side optical switch, and that outputs an instruction to change a communication path in response to a notification of communication disconnection of the station-side device A failure that receives a disconnection of the station side optical switch and the station side optical switch, and determines whether the failure point is the station side or the subscriber side depending on whether or not the station side optical switch is disconnected. The location determination unit receives the failure location notification, calculates the output port for each wavelength to the station side optical switch and the subscriber side optical switch to switch to the redundant path, and obtains the result. A communication path calculation unit for transmitting, a wavelength switching instruction unit for transmitting a result received from the communication path calculation unit to the station side device, the station side optical switch, and the subscriber side optical switch, and the communication path When the result of the calculation unit is received, a setting information management unit that transmits the communication setting information of the station side device to the other station side device, and a notification of communication disconnection from the station side device to the failure location determination unit Then, a request from the setting information management unit is transmitted to the station side device, communication setting information from the station side device is transmitted to the setting information management unit, and an instruction from the wavelength switching instruction unit is transmitted to the station side device. Station-side device port for transmitting to the station-side optical switch and notification of communication disconnection received from the station-side optical switch to the failure location determination unit, and instructions from the wavelength switching instruction unit to the station-side optical switch and the subscriber Optical switch to transmit to the side optical switch A controller that includes a Tchipoto.

  One aspect of the present invention is a ring-type optical access network including a station-side optical switch connected to a station-side apparatus, a subscriber-side optical switch connected to a subscriber-side apparatus, and a controller that controls the system in an integrated manner. An optical communication method performed by a system, wherein the station-side device is connected to the controller, communicates with the subscriber-side device according to an instruction from the controller, and notifies the controller of communication disconnection when communication disconnection occurs. The subscriber-side device communicates with a single station-side device; the station-side optical switch is connected to the controller; and according to instructions from the controller, the station-side device and the subscriber-side device Allocating the signal to each port and notifying the controller when the optical signal of the station side device cannot be received; and H is connected to the controller, and distributes the signals of the station side device and the subscriber side device to each port according to instructions of the controller, and the controller communicates with the station side device when a fiber failure occurs. When the station-side optical switch is able to receive an optical signal from the station-side apparatus upon notification of disconnection, the path of the station-side apparatus and the subscriber-side apparatus in which the communication disconnection has occurred is made a redundant path. If the station side optical switch cannot receive the optical signal from the station side device, the communication setting information of the station side device is transferred to another station side device and an instruction to change the route is output. And an optical communication method.

  According to the present invention, a method for coping with the location of a failed fiber when switching to a redundant path as a countermeasure when a fiber failure occurs and when transferring communication setting information of a station side device to another station side device By changing, it becomes possible to take appropriate measures against the failure, so that it is possible to achieve communication recovery without going to the site.

It is a block diagram which shows the structure of the ring type access network system by one Embodiment of this invention. It is a figure which shows the structure of the station side apparatus 41 shown in FIG. It is a block diagram which shows the structure of the subscriber side apparatus 1-1 shown in FIG. FIG. 2 is a block diagram showing a configuration of a station side optical switch 31 shown in FIG. 1. It is a block diagram which shows the structure of the subscriber side optical switch 21 shown in FIG. It is a block diagram which shows the structure of the subscriber side optical switch 21 shown in FIG. 3 is a flowchart showing a switching operation when a failure occurs in the ring type optical access network system shown in FIG. 1. It is a figure which shows the example of switching operation when the optical fiber transmission line 61 which connects the station side optical switch 31 and the subscriber side optical switch 21 fails. It is a figure which shows the example of switching operation when the fiber which connects the station side optical switch 31 and the station side apparatus 41 fails. It is a block diagram which shows the modification of a ring type access network structure. It is a block diagram which shows the structure of the subscriber side optical switch 21 in the modification of a ring type | mold optical access network. It is a figure which shows the example of switching operation when the fiber which connects the subscriber side apparatus 1-1 and the subscriber side optical switch 21 fails.

  Hereinafter, a ring-type optical access network system according to an embodiment of the present invention will be described with reference to the drawings. FIG. 1 is a block diagram showing the configuration of the ring access network system of the embodiment. In FIG. 1, reference numerals 1-1, 1-2,..., NM denote N × M (N and M are natural numbers of 2 or more) units on the subscriber side. Reference numerals 11, 12, and 13 denote N optical multiplexing / demultiplexing units. Reference numerals 21, 22, and 23 are subscriber-side optical switches.

  Reference numerals 31, 32 and 33 are station side optical switches. Reference numerals 41, 42, and 43 are station side devices. Reference numeral 51 denotes a controller. Reference numeral 61 denotes a ring-shaped optical fiber transmission line. The controller 51 is connected to each station side device and the optical switch, and holds communication path information including a wavelength used by the station side device and the subscriber side device for communication and an optical switch through which the station side device and the optical device pass. Each subscriber-side device and station-side device are connected to a single optical switch.

  Next, the configuration of the station side apparatus shown in FIG. 1 will be described with reference to FIG. FIG. 2 is a diagram illustrating a configuration of the station-side device 41 illustrated in FIG. Since the other two station-side devices 42 and 43 have the same configuration, detailed description thereof is omitted here.

  The station-side device 41 includes a plurality of optical signal transmission units 411, 413, and 415, optical signal reception units 412, 414, and 416, a wavelength control unit 417, a setting management unit 418, and a controller signal transmission / reception using different wavelengths. 419, a communication disconnection detection unit 420, and an optical wavelength multiplexing / demultiplexing unit 421.

  Each of the optical signal transmission units 411, 413, and 415 transmits an optical signal to one or a plurality of subscriber side devices, and always emits light regardless of the presence or absence of a signal to be transmitted to the subscriber side device. Each optical signal receiver 412, 414, 416 receives an optical signal from a single or a plurality of subscriber side devices.

  The wavelength control unit 417 changes the wavelength of the optical signal to be transmitted and received in accordance with the wavelength switching signal received by the controller signal transmission / reception unit 419. The setting management unit 418 transmits setting information through the controller signal transmission / reception unit 419 in accordance with a request for setting information necessary for communication received by the controller signal transmission / reception unit 419.

  The controller signal transmission / reception unit 419 receives a signal from the controller 51, transmits a wavelength switching instruction to the wavelength control unit 417, transmits a setting information request instruction to the setting management unit 418, and receives a signal from the communication disconnection detection unit 420. The communication disconnection information and the setting information from the setting management unit 418 are received and transmitted to the controller 51.

  The communication disconnection detection unit 420 transmits the current wavelength that cannot be communicated to the controller 51 through the controller signal transmission / reception unit 419 when communication with the subscriber side device is disconnected due to a failure and communication is not started for a certain period of time. The optical wavelength multiplexing / demultiplexing unit 421 multiplexes the optical wavelengths oscillated from the plurality of optical signal transmission units 411, 413, and 415, inserts them into the optical fiber transmission line 61, and oscillates from the plurality of subscriber side devices. The optical wavelength is demultiplexed and transmitted to the optical signal receivers 412, 414, and 416.

  Next, the configuration of the subscriber side apparatus 1-1 shown in FIG. 1 will be described with reference to FIG. Since the configuration of the other subscriber side devices is the same, detailed description is omitted here. FIG. 3 is a block diagram showing a configuration of the subscriber side apparatus 1-1 shown in FIG. The subscriber side device 1-1 includes a wavelength variable optical signal transmitter 11, a variable wavelength optical signal receiver 12, a communication disconnection detector 13, and a wavelength controller 14. The wavelength variable optical signal transmission unit 11 transmits an optical signal to the station side device, and changes the wavelength to be transmitted in accordance with an instruction from the wavelength control unit 14. The wavelength tunable optical signal receiving unit 12 receives an optical signal from the station side device, and changes the wavelength to be received in accordance with an instruction from the wavelength control unit 14.

  The communication disconnection detection unit 13 transmits the current wavelength that cannot be communicated to the wavelength control unit 14 when communication with the station side device is disconnected due to a failure and communication is not started for a certain period of time. The wavelength control unit 14 confirms the wavelength at which communication is not started from the communication disconnection detection unit 13 and transmits an instruction to the wavelength tunable optical signal transmission unit 11 and the wavelength tunable optical signal reception unit 12 to switch to a different wavelength.

  Next, the configuration of the station side optical switch 31 shown in FIG. 1 will be described with reference to FIG. The same applies to the other station side optical switches 32 and 33, and therefore, detailed description thereof is omitted here. FIG. 4 is a block diagram showing a configuration of the station side optical switch 31 shown in FIG. The station-side optical switch 31 includes a wavelength switching unit 311, a station-side device port 312, two optical switch ports 313 and 314, an optical demultiplexing unit 315, a light detection unit 316, and a controller signal transmission / reception unit 317. Composed.

  The wavelength switching unit 311 performs switching to the corresponding port in accordance with an instruction from the controller 51 that has received the optical signal from the optical switch ports 313 and 314 or the optical demultiplexing unit 315 from the controller signal transmission / reception unit 317. The station-side device port 312 transmits the optical signal received from the station-side device 41 to the optical demultiplexing unit 315 and the optical signal received from the wavelength switching unit 311 to the station-side device 41 connected thereto.

  The optical switch ports 313 and 314 transmit the optical signal received from the optical switch to the wavelength switching unit 311 and to the optical switch to which the optical signal received from the wavelength switching unit 311 is connected. The optical demultiplexing unit 315 demultiplexes and transmits the optical signal received from the station side device port 312 to the optical detection unit 316 and the wavelength switching unit 311.

  The light detection unit 316 receives the optical signal transmitted from the station side device 41 from the optical demultiplexing unit 315 and, when the optical signal cannot be received, from the station side device 41 via the controller signal transmission / reception unit 317. The controller 51 is notified that the optical signal cannot be received. The controller signal transmission / reception unit 317 notifies the controller 51 of information that the optical signal of the station-side device received from the light detection unit 316 cannot be received, and transmits a wavelength switching instruction from the controller 51 to the wavelength switching unit 311.

  Next, the configuration of the subscriber side optical switch 21 shown in FIG. 1 will be described with reference to FIG. The same applies to the other optical switches 22 and 23 on the subscriber side, and detailed description thereof is omitted here. FIG. 5 is a block diagram showing a configuration of the subscriber-side optical switch 21 shown in FIG. The subscriber-side optical switch 21 includes a wavelength switching unit 211, a subscriber-side device port 212, two optical switch ports 213 and 214, and a controller signal transmission / reception unit 215.

  The wavelength switching unit 211 performs switching to the corresponding port in accordance with an instruction from the controller 51 received from the controller signal transmission / reception unit 215 for the optical signal from the optical switch ports 213 and 214 or the subscriber side device port 212. The subscriber-side device port 212 transmits, for example, an optical signal received from the subscriber-side device 1-1 to the wavelength switching unit 211, and transmits, for example, the optical signal received from the wavelength switching unit 211 to the subscriber-side device 1-1. To do.

  The optical switch ports 213 and 214 transmit the optical signal received from the optical switch to the wavelength switching unit 211 and to the optical switch to which the optical signal received from the wavelength switching unit 211 is connected. The controller signal transmission / reception unit 215 transmits the wavelength switching instruction from the controller 51 to the wavelength switching unit 211.

  Next, the configuration of the controller 51 shown in FIG. 1 will be described with reference to FIG. FIG. 6 is a diagram showing a configuration of the controller 51 shown in FIG. The controller 51 includes a failure location determination unit 511, a communication path calculation unit 512, a wavelength switching instruction unit 513, a setting information management unit 514, optical switch ports 515, 516, and 517, station side device ports 518 and 519, 520.

  The failure location determination unit 511 receives communication disconnection information from the station side devices 41 to 43 from the station side device ports 518 to 520 and is directly connected to the station side devices 41 to 43 connected to the station side device ports 518 to 520. The station side optical switches 31 to 33 check whether or not the optical signals are received from the station side devices 41 to 43, and if the optical signals are continuously received, the optical signal path change instruction is sent to the optical signals. Cannot be received, the change instruction of the station side devices 41 to 43 is transmitted to the communication path calculation unit 512.

  The communication path calculation unit 512 holds path information indicating which optical switch the station side apparatuses 41 to 43 and the subscriber side apparatuses 1-1 to NM are communicating with, and from the failure location determination unit 511. New communication path is calculated according to the path change instruction or the station side apparatus 41 to 43 change instruction, and the new communication path is transmitted to the wavelength switching instruction unit 513. If the station side apparatuses 41 to 43 need to be changed, setting is performed. An instruction to replace setting management information of the station side devices 41 to 43 is transmitted to the information management unit 514.

  The wavelength switching instruction unit 513 calculates the wavelengths and communication paths at which the station side devices 41 to 43 and the subscriber side devices 1-1 to NM can communicate with each other on the new communication path received from the communication path calculation unit 512, The station side devices 41 to 43 transmit information specifying the wavelength to be used in the setting information newly received from the setting information management unit 514 to the station side device ports 518 to 520, and the optical switch specifies the port through which the calculated wavelength passes. Information to be transmitted to the optical switch ports 515 to 517.

  The setting information management unit 514 transmits a setting information request instruction for the station side devices 41 to 43 to the station side device ports 518 to 520 in accordance with the setting information replacement instruction of the station side devices 41 to 43 received from the communication path calculation unit 512. Then, the setting information transmitted from the station side devices 41 to 43 is received according to this request, and the setting information received by this request is transmitted to the new station side devices 41 to 43.

  The optical switch ports 515 to 517 are connected to the controller signal transmission / reception units 317 and 215 of the station side optical switches 31 to 33 or the subscriber side switches 21 to 23, and transmit a wavelength switching instruction from the wavelength switching instruction unit 513. The optical signals from the station side devices 41 to 43 from the side optical switches 31 to 33 receive information that cannot be received.

  The station side device ports 518 to 520 are connected to the controller signal transmission / reception unit 419 of the station side devices 41 to 43, and transmit setting information request instructions to the station side devices 41 to 43 in accordance with instructions from the setting information management unit 514. The setting information transmitted from the station side devices 41 to 43 is transmitted to the setting information management unit 514, and the setting information of the station side devices 41 to 43 to be added transmitted from the setting information management unit 514 is transmitted to the station side devices 41 to 43. The wavelength switching instruction transmitted from the wavelength switching instruction unit 513 is transmitted to the station side devices 41 to 43.

  Next, referring to FIG. 7, the switching operation when a failure occurs in the ring type optical access network system shown in FIG. 1 will be described. FIG. 7 is a flowchart showing a switching operation when a failure occurs in the ring type optical access network system shown in FIG.

  First, the controller 51 receives a disconnection of communication using the wavelength l from the station side device n (any one of the station side devices 41 to 43, here, for example, the station side device 41) (step S1). Subsequently, the controller 51 confirms whether or not the wavelength l can be received from the station-side optical switch 31 connected to the station-side device 41 (step S2). If light is received, the controller 51 determines that a failure has occurred on the subscriber side rather than the station-side optical switch 31, and switches the communication path using the wavelength l to a redundant path (reverse to the normal path). An instruction is transmitted to each optical switch (step S3).

  On the other hand, if the light is not received, the controller 51 requests the station side apparatus 41 for setting information for communication using the wavelength l and copies the setting information to the setting information management unit 514 (step S4). Then, the controller 51 shifts the setting information by copying the setting information of the wavelength l in the station side device 41 from the setting information management unit 514 to the wavelength l ′ in the other station side device n ′ (step S5). Further, the controller 51 changes to the wavelength l ′ to be used, and transmits an instruction to change the communication path of the wavelength l ′ to each optical switch (step S6). Each optical switch sets a port through which the wavelength l 'passes according to an instruction from the controller.

  Next, the first switching pattern when a failure occurs will be described. FIG. 8 is a diagram showing an example of the switching operation when the optical fiber transmission line 61 connecting the station side optical switch 31 and the subscriber side optical switch 21 fails.

  The station side device 41 communicates with the subscriber side devices 1-1, 1-2,..., 1-M via the station side optical switch 31 and the subscriber side optical switch 21, using the wavelength l. doing. At this time, if the optical fiber transmission line 61 fails, the controller 51 receives a communication interruption of the wavelength 1 from the station side device 41. The controller 51 confirms that it has not received undetectable information on the wavelength l from the station-side optical switch 31 connected to the station-side device 41, and a failure has occurred on the subscriber side from the station-side optical switch 31. Judge. The controller 51 sends an instruction to change each port through which the wavelength l passes so that the communication path of the wavelength l passes through the station side optical switches 31, 32, 33 and the subscriber side optical switches 23, 22, 21 in order. Transmit to each optical switch. The change of the port through which the wavelength l of each optical switch passes is completed, and the communication between the station side device 41 and the subscriber side devices 1-1, 1-2,..., 1-M is restored.

  Next, the second switching pattern when a failure occurs will be described. FIG. 9 is a diagram illustrating an example of a switching operation when a fiber connecting the station-side optical switch 31 and the station-side device 41 fails.

  The station side device 41 communicates with the subscriber side devices 1-1, 1-2,..., 1-M via the station side optical switch 31 and the subscriber side optical switch 21, using the wavelength l. doing. At this time, when the fiber breaks down, the controller 51 receives the communication interruption of the wavelength 1 from the station side device 41 and the station side optical switch 31. The controller 51 determines that a failure has occurred on the station side from the station side optical switch 31. The controller 51 requests communication setting information using the wavelength l from the station side device 41. The controller 51 selects a wavelength l ′ that can be newly used in the station side apparatus 42 or a redundant wavelength l ′ that is determined in advance. After receiving the setting information, the controller 51 transmits an instruction to the station side device 42 to use the selected wavelength l ′ together with the setting information. In addition, the controller 51 instructs to change each port through which the wavelength l ′ passes so that the communication path of the wavelength l ′ sequentially passes through the station side optical switches 32 and 33 and the subscriber side optical switches 23, 22, and 21. Is transmitted to each optical switch. The change of the port through which the wavelength l ′ of each optical switch passes and the addition of the setting information of the station side device are completed, and the station side device 41 and the subscriber side devices 1-1, 1-2,. M's communication will be restored.

  Next, a modification of the ring optical access network shown in FIG. 1 will be described with reference to FIG. FIG. 10 is a block diagram showing a modification of the ring access network configuration. The controller 51 is connected to each of the station side devices 41 to 43 and the optical switch, and holds communication path information including a wavelength used for communication between the station side device and the subscriber side device and an optical switch through which the station side device is connected. Each of the subscriber side devices 1-1 to NM is connected to a plurality of subscriber side optical switches 21 to 23, and each of the station side devices 41 to 43 has a single station side optical switch 31 to 33, respectively. Connected.

  Next, the configuration of the subscriber side optical switches 21 to 23 shown in FIG. 10 will be described with reference to FIG. FIG. 11 is a block diagram showing a configuration of the subscriber side optical switch 21 in a modification of the ring type optical access network. Since the configurations of the other subscriber side optical switches 22 and 23 are the same, detailed description thereof is omitted here.

  The subscriber-side optical switch 21 in the modification includes a wavelength switching unit 211, a subscriber-side device port 212, two optical switch ports 213 and 214, an optical demultiplexing unit 216, an optical detection unit 217, and a controller signal. The transmission / reception unit 215 is configured.

  The wavelength switching unit 211 performs switching to the corresponding port in accordance with an instruction from the controller 51 received from the controller signal transmission / reception unit 215 for the optical signal from the optical switch ports 213 and 214 or the subscriber side device port 212. The subscriber-side device port 212 connects the optical signal received from the subscriber-side devices 1-1 to 1-M to the wavelength switching unit 211, and connects the optical signal received from the wavelength switching unit 211 to the subscriber-side device 1-1. Transmit to ~ 1-M.

  The optical switch ports 213 and 214 transmit the optical signal received from the optical switch to the optical demultiplexing unit 216 and to the optical switch to which the optical signal received from the wavelength switching unit 211 is connected. The optical demultiplexing unit 216 demultiplexes and transmits the optical signal received from the optical switch port 213 to the optical detection unit 217 and the wavelength switching unit 211.

  The optical detection unit 217 receives the optical signal transmitted from the station side devices 41 to 43 from the optical demultiplexing unit 216, and when the optical signal cannot be received, the controller signal transmission / reception unit 215 sends the optical signal to the station side devices 41 to 41. The controller 51 is notified that the optical signal from 43 cannot be received.

  The controller signal transmission / reception unit 215 notifies the controller 51 of information that the optical signals of the station side devices 41 to 43 received from the light detection unit 217 cannot be received, and transmits a wavelength switching instruction from the controller 51 to the wavelength switching unit 211. To do.

  Next, a third switching pattern at the time of occurrence of a failure will be described with reference to FIG. FIG. 12 is a diagram illustrating an example of a switching operation when a fiber connecting the subscriber-side device 1-1 and the subscriber-side optical switch 21 has failed.

  The station side device 41 communicates with the subscriber side devices 1-1, 1-2,..., 1-M via the station side optical switch 31 and the subscriber side optical switch 21, using the wavelength l. doing. At this time, if a fiber connecting the subscriber-side device 1-1 and the subscriber-side optical switch 21 fails, the controller 51 receives a communication disconnection of the wavelength l from the station-side device 41. The controller 51 confirms that it has not received undetectable information on the wavelength l from the station side optical switch 31 and the subscriber side optical switch 21, and a failure has occurred on the subscriber side from the subscriber side optical switch 21. to decide. The controller 51 transmits an instruction to change each port through which the wavelength l passes to each optical switch so that the communication path of the wavelength l passes through the station side optical switch 31 and the subscriber side optical switches 21 and 22. The change of the port through which the wavelength l of each optical switch passes is completed, and the communication between the station side device 41 and the subscriber side devices 1-1, 1-2,..., 1-M is restored.

  In the above description, the optical media converter or PON using WDM that can be externally controlled by the controller 51 can be realized by using, for example, NG-PON2 and WDM-PON, which are next-generation optical access systems. it can.

  As described above, in a PON system combined with wavelength division multiplexing, a photodetector is added to the station-side optical switch, and a controller is connected to each optical switch and station-side device, so that the redundant path is automatically established. Since a switchable ring-type optical access network is constructed, communication can be restored by switching to an appropriate redundant path without going to the site when a fiber failure occurs.

  A part of the ring optical access network in the above-described embodiment may be realized by a computer. In that case, a program for realizing this function may be recorded on a computer-readable recording medium, and the program recorded on this recording medium may be read into a computer system and executed. Here, the “computer system” includes an OS and hardware such as peripheral devices. The “computer-readable recording medium” refers to a storage device such as a flexible medium, a magneto-optical disk, a portable medium such as a ROM and a CD-ROM, and a hard disk incorporated in a computer system. Furthermore, the “computer-readable recording medium” dynamically holds a program for a short time like a communication line when transmitting a program via a network such as the Internet or a communication line such as a telephone line. In this case, a volatile memory inside a computer system serving as a server or a client in that case may be included and a program held for a certain period of time. Further, the program may be a program for realizing a part of the above-described functions, and may be a program capable of realizing the functions described above in combination with a program already recorded in a computer system. It may be realized using hardware such as PLD (Programmable Logic Device) or FPGA (Field Programmable Gate Array).

  As mentioned above, although embodiment of this invention has been described with reference to drawings, the said embodiment is only the illustration of this invention, and it is clear that this invention is not limited to the said embodiment. is there. Therefore, additions, omissions, substitutions, and other modifications of the components may be made without departing from the technical idea and scope of the present invention.

  When changing to a redundant path as a countermeasure when a fiber failure occurs and when transferring the communication setting information of the station side device to another station side device, by changing the countermeasure method for each location of the failed fiber, Appropriate countermeasures can be taken against failures, so that it can be applied to applications where it is essential to restore communications without going to the site.

  1-1 to NM: Subscriber side device, 11, 12, 13 ... Optical multiplexing / demultiplexing unit, 21, 22, 23 ... Subscriber side optical switch, 31, 32, 33 ... Station side optical switch, 41, 42, 43 ... Station side device, 51 ... Controller, 61 ... Optical fiber transmission line

Claims (3)

Ring type comprising a station-side optical switch connected to a station-side apparatus, a subscriber-side optical switch connected to a single subscriber-side apparatus communicating with the single station-side apparatus, and a controller that controls the system as a whole An optical access network system,
The station side device is connected to the controller, communicates with the subscriber side device according to instructions from the controller, and notifies the controller of communication disconnection when communication disconnection occurs .
The station-side optical switch is connected to the controller, distributes the signals of the station-side apparatus and the subscriber-side apparatus to each port according to instructions from the controller, and receives the optical signal of the station-side apparatus when the controller cannot receive the optical signal Notify
The subscriber side optical switch is connected to the controller, and distributes the signals of the station side device and the subscriber side device to each port according to instructions of the controller,
In the event of a fiber failure, when the station side optical switch is able to receive the optical signal from the station side device, the controller has lost communication at the time of a fiber failure. If the route of the station side device and the subscriber side device is changed to a redundant route, and the station side optical switch cannot receive the optical signal from the station side device, the communication setting information of the station side device is A ring-type optical access network system that outputs instructions to change the route while moving to another station. Ring type comprising a station-side optical switch connected to a station-side apparatus, a subscriber-side optical switch connected to a single subscriber-side apparatus communicating with the single station-side apparatus, and a controller that controls the system as a whole a Contact Keru the controller to the optical access network system,
Means for connecting to the station side device, outputting an instruction for communication with the subscriber side device to the station side device, and receiving a communication disconnection notification from the station side device when a communication disconnection of the station side device occurs When,
The station-side optical switch is connected, and the station-side optical switch outputs an instruction to distribute the signals of the station-side apparatus and the subscriber-side apparatus to each port, and the station-side optical switch Means for receiving a notification when the switch cannot receive the optical signal of the station side device;
Means for connecting to the subscriber-side optical switch, and outputting to the subscriber-side optical switch an instruction to distribute the station-side device and the signal of the subscriber-side device to each port ;
In the event of a fiber failure, when the station-side optical switch is able to receive an optical signal from the station-side device, triggered by a notification of communication disconnection of the station-side device, the station-side device in which a communication disconnection has occurred And when the station-side optical switch is not able to receive the optical signal from the station-side apparatus, the communication setting information of the station-side apparatus is changed to another station side. A controller that outputs an instruction to change the path while moving to the device . Ring type comprising a station-side optical switch connected to a station-side apparatus, a subscriber-side optical switch connected to a single subscriber-side apparatus communicating with the single station-side apparatus, and a controller that controls the system as a whole An optical communication method performed by an optical access network system,
The station-side device is connected to the controller, communicates with the subscriber-side device according to instructions from the controller, and notifies the controller of communication disconnection when communication disconnection occurs ;
It said controller when the station-side optical switch is connected to the controller, distributes the signal of the subscriber-side device and the station side device to each port in accordance with an instruction of the controller can not receive the optical signal of the station-side device A step to notify
The subscriber-side optical switch is connected to the controller, and distributes the signals of the station-side device and the subscriber-side device to each port according to instructions from the controller;
When the controller is in the event of a fiber failure, the station-side optical switch can receive an optical signal from the station-side apparatus, triggered by a notification of communication disconnection of the station-side apparatus. If the route of the station side device and the subscriber side device is changed to a redundant route, and the station side optical switch cannot receive the optical signal from the station side device, the communication setting information of the station side device is And a step of outputting an instruction to change the route while moving to another station side device.

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