JP2000332857A - N+1 redundant configuration circuit - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an (N+1) redundant configuration circuit that provides an inexpensive unit configuration and a small mount space. SOLUTION: Interface panels (1)-(N) transmit signals from another device 2 to a plurality of subscriber devices through one transmission line. On the other hand, the interface panels (1)-(N) receive signals from the subscriber devices 31-33 and transmit the signals to the other device 2. On the occurrence of a fault of an interface panel (i), a device control circuit 11 recognizes fault information, a band control circuit 12 selects the interface panel (N+1) and throws an optical switch 17 to a transmission line equivalent to the interface panel G). As a result, a transmission line in the unit is changed from 'band control circuit - interface panel (i)-subscriber devices' into 'band control circuit - interface panel (N+1) - subscriber devices' to restore the line without the need for interrupting the line on the fault occurrence of the interface panel (i).

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an N + 1 redundant circuit, and more particularly, to a P + 1 circuit having N identical interface boards.
ON (Passive Optical Network)
k) An N + 1 redundant configuration circuit that implements an N + 1 redundant configuration function for a device that performs a transmission scheme.

[0002]

2. Description of the Related Art As a conventional example of this type of PON transmission apparatus, there has been proposed a star-type optical subscriber transmission apparatus disclosed in Japanese Patent Application Laid-Open No. 9-284325.

[0003] In the conventional example described in the above-mentioned publication, a plurality of subscriber units and one station unit are provided with an active system and a standby system, respectively.
A system interface section is provided, these are connected by two systems of optical transmission lines, and the information of the active system is always held in the standby system. This significantly reduces the time of disconnection of the transmission line when switching the transmission line. In this case, the reliability as an optical transmission device is improved.

[0004]

However, in the conventional PON transmission device, the redundant configuration of the interface board is one.
+1 or 1+
The first redundant configuration has a disadvantage that the device configuration becomes expensive. In addition, there is a problem that a mounting space is increased due to the 1 + 1 redundant configuration.

[0005] On the other hand, in the case where the redundant configuration is omitted, there is a problem that when the interface board fails, the transmission path is disconnected until the interface board is replaced with a normal interface board.

In addition, there is another problem that the transmission path is interrupted even when the interface board is replaced for regular maintenance or the like.

SUMMARY OF THE INVENTION The present invention has been made in view of the above-mentioned conventional circumstances, and accordingly, an object of the present invention is to provide a novel N + which can eliminate the above-mentioned drawbacks inherent in the prior art.
One redundant configuration circuit is provided.

[0008]

To achieve the above object, an N + 1 redundant configuration circuit according to the present invention comprises a station apparatus for controlling information transmission between another apparatus and a plurality of subscriber apparatuses. And a PON transmission device disposed between the subscriber device and the subscriber device, the station device includes first to Nth and N + 1th
(N is a positive integer) interface boards and the first to Nth
An optical transmission line provided corresponding to the interface board of
A star coupler provided corresponding to the optical transmission line, a device control circuit for detecting a failure of the interface board, and an interface board having a failure based on the failure information detected by the device control circuit, the N + 1th interface A bandwidth control circuit for switching to the board, and an optical switch connected to the (N + 1) -th interface board for switching the (N + 1) -interface board to an optical transmission line corresponding to the failed interface board.

The first to Nth interface boards are P
Holds control information for controlling ON transmission, and the (N + 1) th interface board holds each control information of the first to Nth interface boards, and at the time of normal operation in which no fault has occurred in each of the interface boards. It is characterized in that only the reception is performed, and the optical switch is rotated in order from the first to the Nth to acquire and hold each transmission line information.

[0010] The band control circuit includes a format conversion circuit for converting a format of a transmission signal, and a format conversion circuit corresponding to the first to Nth interface boards between the format conversion circuit and the first to Nth interface boards. A plurality of branch circuits, and the branch circuit that is connected between the (N + 1) th interface board and each of the branch circuits and that corresponds to the interface board in which a failure has occurred is selected and the format conversion circuit outputs And a selector for branching the output signal from the interface board in which the fault has occurred to the (N + 1) th interface board and inputting the branched signal.

Further, the N + 1 redundant configuration circuit according to the present invention comprises:
The first to (N + 1) th interface boards do not hold the control information for controlling the PON transmission, and when the interface boards are switched, the device control circuit transfers the control information of the switching destination and starts the operation. I have.

[0012]

[Function] Points using PON which is a feature of the present invention
FIG. 1 shows the configuration of the multipoint system. In FIG. 1, the interface boards 13 to 15 transmit signals from other devices 2 to a plurality of subscriber devices 31 to 33 using one transmission path. On the other hand, a signal from each subscriber device is received by the interface boards 13 to 15 and transmitted to the other device 2.

Here, an interface board (i) 14
If the device has failed, the failure information is transmitted to the device control circuit 11.
, And the band control circuit 12 switches the signal line to the interface board (N + 1) 16 and at the same time switches the optical switch 17 to the transmission path corresponding to the interface board (i) 14. As a result, the transmission line in the device is changed from “band control circuit 12-interface board (i) 14-subscriber apparatus” to “band control circuit 12-interface board (N +
1) 16-subscriber apparatus ", the line can be restored without breaking the line when the interface board (i) 14 fails.

When a failure occurs, the interface panel (N
+1) All interface boards 13-1 for 16 only
The number of interface boards can be reduced as compared with the case where the redundant configuration is provided in the fifth embodiment.

[0015]

Next, a preferred embodiment of the present invention will be described in detail with reference to the drawings.

FIG. 1 is a block diagram showing one embodiment of the present invention.

[Configuration of Embodiment] Referring to FIG.
In one embodiment of the N + 1 redundant configuration circuit according to the present invention, a station apparatus 1 for controlling information transmission between another apparatus and a plurality of subscriber apparatuses is connected between the other apparatus 2 and each of the subscriber apparatuses 31 to 33. It is arranged in.

The station device 1 includes a device control circuit 11 for detecting a fault in the interface board and an interface board N +
1, a bandwidth control circuit 12 for switching the N + 1 interface board to a transmission path corresponding to the failed interface board, a plurality of interface boards 13 to 15, and a support for these interface boards 13 to 15. And the optical switch 17 for switching the optical transmission lines 51 to 53.

In FIG. 1, a station apparatus 1 assigns a downstream signal to each of the subscriber units 31 to 33 by a band control circuit 12, converts the signal to an optical signal by interface boards 13 to 16, and transmits the optical signal by an optical fiber. This downstream optical signal is optically branched by star couplers 41 to 43 on the way and distributed to the subscriber units 31 to 33. Each of the subscriber devices 31 to 33 converts an optical signal into an electric signal, extracts only information transmitted to itself, and outputs the information.

On the other hand, the upstream signal is transmitted to the subscriber units 31 to 33.
The transmission timing is controlled by the band control circuit, and the signal is converted into an optical signal. The optical signal is combined with signals from other subscriber apparatuses by the star couplers 41 to 43 and received by the station apparatus 1. In the station device 1, the optical signal is converted into an electric signal, and the band control circuit 12
The format is converted and transmitted to the other device 2.

FIG. 2 is a block diagram showing one embodiment of the band control circuit 12 and the interface boards 13 to 16.

Referring to FIG. 2, the interface board (i) 14 includes control information (i) 1 for controlling PON transmission.
42 is held.

More specifically, the band control circuit 12 includes a format conversion circuit 121 for converting the format of a transmission signal, and a branch circuit 122 connected to the format conversion circuit 121 and provided for each interface board. , 123, and 124, and a selector 125 for selecting a branch circuit corresponding to the interface board in which a failure has occurred when one of the interface boards has a failure.

The interface board (1) 13 has a main signal circuit 131 connected to the branch circuit 122 and control information (1) 132, and the interface board (i) 14 has a main signal circuit 131 connected to the branch circuit 123. The interface board (N) 15 includes a signal circuit 141 and control information (i) 142.
Has a main signal circuit 151 connected to the branch circuit 124 and control information 152.

The interface board (N + 1) 16 includes a main signal circuit 161 connected to the selector 125, control information (1) 132, control information (i) 142, and control information (N).
152.

On the other hand, the interface board (N + 1) 16
Are switched from each interface board, so that each interface board (1) 13, (i) 14,
(N) 15 control information (1) 132 to (N) 152 are stored.

During normal operation (when there is no failure in the interface board), the interface board (N + 1) 16 performs only reception, rotates the optical switches 17 sequentially from 1 to N, and holds each transmission line information.

On the other hand, the band control circuit 12 is mainly composed of a format conversion circuit 121 and a selector 125, and performs switching under the control of switching by the device control circuit 11.

If the device control circuit 11 detects a failure of the interface board (i) 14, the interface board (N + 1) 16 is operated and the bandwidth control circuit 12
The selector 125 switches the interface board (i) 14 to the interface board (N + 1) 16, and the optical switch 17 switches the interface board (N + 1) 16 to the optical transmission line to which the interface board (i) 14 was connected. The interface board (N + 1) 16 starts transmission / reception according to the control information (i) held by itself.

[Operation of Embodiment] Next, the operation of the embodiment according to the present invention will be described.

First, the overall signal flow will be described. A downlink signal is input to the station device 2 and the band control circuit 12
The signal is distributed to each of the subscriber units 31 to 33 and is converted into an optical signal.
53. Star couplers 41 to 43 on the way
And is distributed to each of the subscriber units 31-33.

The subscriber unit converts the optical signal into an electric signal, and extracts and outputs only the information sent to itself.

On the other hand, the transmission timing of the upstream signal is controlled by the subscriber unit, converted into an optical signal, and transmitted to the star coupler 4.
The signals are combined with signals from other subscriber devices at 1 to 43 and received by the station device 1. In the station device 1, the optical signal is converted into an electric signal, the format is converted by the band control circuit 12, and transmitted to the other device 2.

Next, the operation of the actual N + 1 redundant circuit will be described.

First, the circuit configuration shown in FIG. 2 will be described. The interface board (i) 14 holds control information (i) 142 for controlling PON transmission.

On the other hand, the interface board (N + 1) 16
Since switching is performed from each interface board, control information (1) to (N) of each interface board is held. The interface board (N + 1) 16 is connected to the optical switch 17, and is connected to each of the transmission lines (1) 51 to (N) 53 by the optical coupler 17 via star couplers 41 to 43.

During normal operation (when there is no failure in the interface board), the interface board (N + 1) 16 performs only reception, rotates the optical switches 17 sequentially from 1 to N, and obtains each transmission line information. Hold.

On the other hand, as described above, the band control circuit 12 mainly includes the format conversion circuit 121 and the selector 125.
The switching is performed by switching control by the device control circuit 11.

Next, the operation of the interface board (i) 14 in the event of failure in the N + 1 redundant configuration will be described.

During normal operation (when there is no failure in the interface board), the subscriber units 31 to 33 are transmitted from the band control circuit 12 through the interface board (i) 14 as shown by thick lines and shading in FIG. Is connected to the transmission line.

As shown in FIG. 4, when the interface board (i) 14 fails, the device control circuit 11 detects the failure and applies the following operations (a) to (d) to each circuit. To instruct.

(A) The selector 125 is changed so that the transmission path for the band control circuit 12 is changed from the interface board (i) 14 to the interface board (N + 1) 16.

(B) The operation of the interface board (i) 14 is stopped, and the output is stopped so as not to perform transmission / reception.

(C) Interface board (N + 1) 16
In response to this, it operates with the control information (i) 142 to start transmission / reception.

(D) The optical switch 17 is switched so that the interface board (N + 1) 16 and the star coupler (i) 42 are connected.

After the instruction to each circuit is completed, the transmission path is changed as shown by the thick line and the shaded area in FIG. 5, and the transmission path is secured. After the interface board (i) 14 recovers from the failure, the transmission path is changed to the interface board (i) 14 by the device control circuit 11 (the operation opposite to that at the time of the failure is performed) to return to the state shown in FIG. An N + 1 redundant configuration can be employed.

[Other Embodiments] As another embodiment of the present invention, the control information of the switching destination is transferred from the device control circuit at the time of switching without having the control information in the redundant interface board, and the operation is performed. There is a way to get started.
In this case, the switching time is long, but since the same interface board as the other interface boards can be used without using a special one as the redundant interface board, the apparatus can be configured more economically. Becomes

[0048]

As described above, according to the present invention,
Since the N + 1 redundant configuration function is realized for a device that performs the PON transmission method having N identical interface boards, the following effects can be obtained.

(1) To obtain an N + 1 redundant configuration,
The transmission path can be secured without disconnecting the transmission path when the interface board fails.

(2) Since there is only one interface board constituting the redundant configuration, an economical and space-saving configuration can be adopted.

(3) Since the redundant configuration interface board (interface board (N + 1)) holds and collects the control information of each interface board, it is possible to switch instantaneously.

[Brief description of the drawings]

FIG. 1 is a block diagram showing an embodiment according to the present invention.

FIG. 2 is a block diagram showing an embodiment of a band control circuit and an interface board of the station device.

FIG. 3 is a diagram for explaining the operation of the present invention.

FIG. 4 is a diagram for explaining the operation of the present invention.

FIG. 5 is a diagram for explaining the operation of the present invention.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 ... Station apparatus 2 ... Other apparatus 11 ... Device control circuit 12 ... Band control circuit 13-16 ... Interface board 17 ... Optical switch 31-33 ... Subscriber apparatus 41-43 ... Star coupler 51-53 ... Optical transmission path 121 ... Format conversion circuit 125 ... selector

Claims (4)

[Claims] 1. A PON transmission device in which a station device for controlling information transmission between another device and a plurality of subscriber devices is disposed between the other device and the subscriber device. , 1st to Nth, Nth (N is a positive integer)
Interface board, an optical transmission line provided corresponding to the first to Nth interface boards, a star coupler provided corresponding to the optical transmission path, and a device for detecting a failure of the interface board A control circuit, a band control circuit for switching an interface board that has failed due to the failure information detected by the device control circuit to the (N + 1) th interface board,
An optical switch for switching an +1 interface board to an optical transmission line corresponding to the failed interface board. 2. The first to Nth interface boards,
Holding the control information for controlling the PON transmission, and
The interface board holds each control information of the first to Nth interface boards, and performs only reception at the time of normal operation in which no failure occurs in each of the interface boards, and moves the optical switch to the first to Nth. 2. The N + 1 redundant configuration circuit according to claim 1, further comprising acquiring and holding each transmission line information by rotating sequentially. 3. The band control circuit comprises: a format conversion circuit for converting a format of a transmission signal; and the first to Nth interface boards between the format conversion circuit and the first to Nth interface boards. And a plurality of branch circuits provided corresponding to the interface board, and selecting the branch circuit connected between the (N + 1) th interface board and each of the branch circuits and corresponding to the interface board in which a failure has occurred, and selecting the format conversion circuit. 2. The N + 1 redundant configuration circuit according to claim 1, further comprising: a selector for branching an output signal from a faulty interface board to the (N + 1) th interface board for input. 4. The apparatus according to claim 1, wherein the first to (N + 1) th interface boards do not hold control information for controlling PON transmission, but transfer control information of a switching destination by the device control circuit when the interface boards are switched, and start an operation. The N + 1 redundant configuration circuit according to claim 1, further comprising: