JPH03191626A - Optical transmission line monitoring system - Google Patents

Abstract

PURPOSE:To easily monitor the abnormality of a subscriber's system optical transmission line by generating a monitoring pulse at every prescribed time by each terminal side and transmitting it to the optical transmission line, and detecting it at a center side. CONSTITUTION:On a subscriber side S1, a monitoring pulse generator 14, and an optical transmitter 5 for transmitting its output pulse are provided, and the output of the optical transmitter 5 is transmitted to a station side M1 through an optical multiplexer 8 and an optical transmission line 9. In this case, a power source circuit 12 for sending out a monitoring pulse is set so as to operate for a short time at every prescribed time with a timer circuit 15. Accordingly, the pulse generator 14 and the optical transmitter 5 output the monitoring pulse at every prescribed time, and transmit the monitoring pulse at every prescribed time to the station side M1. In the station side M1, the received data of an optical receiver 6 is supplied to a pulse detecting circuit 10. When the monitoring pulse is detected in a longer period than prescribed, the detecting circuit 10 outputs a transmission line abnormality signal.

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to a transmission system for monitoring an optical transmission path connecting a main device and a terminal device.

[Conventional technology]

Conventionally, monitoring of an optical transmission line connecting a main device and a plurality of terminal devices has been carried out by switching each terminal device with an optical switch and checking the connection status of the optical switch, as shown in Japanese Patent Laid-Open No. 56-149840, for example. It was detected optically.

[Problem to be solved by the invention]

However, this method of detecting the connection status of an optical switch is intended for use on a large scale, such as in a factory, and is not suitable for small-scale transmission methods such as subscriber telephone lines. .

An object of the present invention is to enable easy monitoring of abnormalities in subscriber optical transmission lines.

[Means to solve the problem]

In order to achieve the above objective, each terminal device generates a monitoring pulse at a predetermined time interval, transmits it through an optical transmission line by wavelength multiplexing, and detects this monitoring pulse at the center side. .

In addition, after confirming that the normal bus is not being used, the monitoring pulses generated at predetermined time intervals on each terminal device side are switched to the transmission data using a changeover switch and transmitted to the center side. It is designed to detect monitoring pulses.

In addition, a loop switch is installed on each terminal side to connect the downlink from the center side and the uplink to the center side, and after confirming that the normal path is not established, this loop is controlled by the center side. A loopback system is established by switching a switch, and a monitoring pulse is sent to this loop bank system to monitor the transmission path.

[Effect]

On the center side, by detecting the transmission status of monitoring pulses transmitted from each terminal side at predetermined time intervals, it is possible to determine whether the optical transmission path is normal or not.

Further, when a loopback system from the center side is established, it can be determined whether the optical transmission line is normal or not by detecting the transmission state of the monitoring pulse returned by the loopback system.

〔Example〕

A first embodiment of the present invention will be described below with reference to FIG.

In the figure, M indicates the station side, sl indicates each subscriber side, and station g
jM l and each subscriber S1 are connected by an optical transmission line 9 made of an optical fiber cable. The station M1 is provided with an optical transmitter 1 for transmitting data input to the terminal 1a, and the optical signal λ transmitted from the optical transmitter 1 is supplied to the optical multiplexer/demultiplexer 7 on the station side. From the demultiplexer 7 to the optical transmission line 9
is transmitted to the desired subscriber side S1. On the subscriber side S1, a subscriber side optical multiplexer/demultiplexer 8 is connected to the optical transmission line 9, and an optical signal λ separated by the optical multiplexer/demultiplexer 8 is obtained.

is supplied to the optical receiver 2, the optical receiver 2 demodulates the received data from the optical signal λ1, and outputs the received data from the received data output terminal 2a.

Further, the subscriber side S1 is provided with an optical transmitter 3 that transmits data input to the terminal 3a, and the optical transmitter 3 sends an optical signal λ2 (λ2 has a different wavelength from λ1) to the subscriber side. It is supplied to the side optical multiplexer/demultiplexer 8, and from this optical multiplexer/demultiplexer 8 to the station side M via the optical transmission line 9.

to be transmitted. Then, the optical signal λ2 obtained from the optical multiplexer/demultiplexer 7 on the station side M is supplied to the optical receiver 4, which demodulates the received data from the optical signal λ2, and outputs the received data from the received data output terminal 4a. Output the received data.

With the above configuration, normal data transmission and reception is performed through call-by-call type two-way communication, but in this example,
In order to monitor the state of the optical transmission line 9, a monitoring pulse sending circuit is provided on each subscriber side S. That is, a monitoring pulse generator 14 and an optical receiver 5 for transmitting the output pulses of the monitoring pulse generator 14 are provided, and the optical signal λ transmitted from the optical transmitter 5 is transmitted.

(λ is a wavelength different from λ1 and λ2) is supplied to the optical multiplexer/demultiplexer 8 on the subscriber side, and transmitted from the optical multiplexer/demultiplexer 8 to the station side M by wavelength multiplexing via the optical transmission line 9.

In this case, the monitoring pulse generator 14 and the optical transmitter 5 are
Power is supplied from a power supply circuit 12, separate from the power supply circuit 13 for the optical receiver 2 and optical transmitter 3 for data. The power supply circuit 12 for sending out monitoring pulses is set by a timer circuit 15 to operate for a short period of time at regular intervals. (For example, set it to operate for one minute every 24 hours.

Therefore, the monitoring pulse generator 14 and the optical transmitter 5 output monitoring pulses at regular intervals, and the monitoring pulse generator 14 and the optical transmitter 5 output monitoring pulses at regular intervals.

A monitoring pulse is transmitted at regular intervals.

On the station side M1, an optical receiver 6 for receiving the optical signal λ of this monitoring pulse is connected to an optical multiplexer/demultiplexer 7, and the received data of this optical receiver 6 is detected as a monitoring pulse. Supplied to circuit 10. The pulse detection circuit IO detects the DC level of the monitoring pulse, and when detection is performed for a certain period of time or more, a trigger pulse is supplied to the counting circuit 11. This counting circuit 11 is reset by the supplied trigger pulse and starts counting. Also,
It is determined whether the next trigger pulse will be input after a time (for example, 24 hours) set by the timer circuit 15 of each subscriber side S1. When a trigger pulse is supplied at each set time, a transmission line normal signal is output from the terminal 11a, and when the trigger pulse supply interval is longer than the set time, a transmission line abnormal signal is output from the terminal 11a.
Output from b. In this manner, when a transmission path abnormality signal is obtained at the terminal 11b, an abnormality in the transmission path is notified.

Next, a second embodiment of the present invention will be described with reference to FIG.

In this example as well, data is sent and received using call-by-call type two-way communication. In the figure, M2 indicates the station side, and S
Reference numeral 2 indicates each subscriber side, and the station side M2 and each subscriber S2 are connected by an optical transmission line 21. And on the station side M2,
Optical transmitter 16 that transmits data input to terminal 16a
The optical signal λ1 sent from the optical transmitter 16 is supplied to the optical multiplexer/demultiplexer 19 on the station side, and is transmitted to the desired subscriber side S2 through the optical transmission line 21. On the subscriber side S2, a subscriber side optical multiplexer/demultiplexer 22 is connected to the optical transmission line 21, and the optical signal λ1 separated by the optical multiplexer/demultiplexer 22 is supplied to the optical receiver 23, and the optical signal λ1 is supplied to the optical receiver 23. A receiver 23 receives an optical signal λ.

The received data is demodulated from the received data output terminal 23a, and the received data is outputted from the received data output terminal 23a.

Further, on the subscriber side S2, the data obtained at the terminal 25a is supplied to the optical transmitter 24 via the switch circuit 25. This switch circuit 25 is also supplied with a monitoring pulse from a monitoring pulse generator 26, and selectively supplies the transmission data input to the terminal 25a and the monitoring pulse to the optical transmitter 24. In this case, switching of the switch circuit 25 is controlled by a switch control circuit 27. This switch control circuit 27 checks whether transmission data is supplied to the terminal 25a, and when there is transmission data, controls the transmission data inputted to the terminal 25a to be supplied to the optical transmitter 24, and transmits the data. When there is no data,
The output pulses of the monitoring pulse generator 26 are controlled to be supplied to the optical transmitter 24.

Then, the optical signal λ2 sent from the optical transmitter 24 is supplied to the optical multiplexer/demultiplexer 22 on the subscriber side, and is transmitted from the optical multiplexer/demultiplexer 22 to the station side Mt via the optical transmission line 21. In this case, subscriber side S
! The optical transmitter 24 receives power from a power supply circuit 28 . Further, the monitoring pulse generator 26 is also connected to this power supply circuit 2.
Receives power supply from 8. In this case, the power supply circuit 28 is operated under the control of the power supply control circuit 29 and the timer circuit 30, and the power supply control circuit 29 receives the optical signal λ from the station side M2 by the optical receiver 23. The timer circuit 30 supplies power to the optical transmitter 24 and the monitoring pulse generator 26 for a short period of time (for example, 1 minute) every fixed period of time (for example, 24 hours). Controls the supply of

Then, on the station side M2, the optical signal λ2 from the subscriber side S2 obtained by the optical multiplexer/demultiplexer 19 is supplied to the optical receiver 17, and the optical receiver 17 demodulates the received data from the optical signal λ2,
This received data is output from the received data output terminal 17a.

In this example, the received signal of the optical receiver 17 is supplied to the monitoring pulse detection circuit 18, and the pulse detection circuit 18 detects the DC level of the monitoring pulse. , supplies a trigger pulse to the counting circuit 20. Then, the count circuit 20 is reset by the trigger pulse and starts counting. Further, the timer circuit 30 of each subscriber side S2 identifies whether or not the set interval is reached, and when the set interval is reached, a transmission path normal signal is output from the terminal 20a, and when it is longer than the set interval, the transmission path is transmitted. A road abnormality signal is output from the terminal 20b. In this way, when a transmission path abnormality signal is obtained at the terminal 20b, an abnormality in the transmission path is notified.

According to the configuration of the second embodiment, since the optical transmitter 24 of each subscriber side S2 transmits normal data and the monitoring pulse, a transmitter dedicated to the monitoring pulse is not required. In this case, since it is determined whether or not the normal bus is being used and the switch circuit 25 is switched, the normal bus is not disturbed by sending out the monitoring pulse. In addition,
When a normal bus is being used, it can be determined that the optical transmission line 21 is normal without sending out a monitoring pulse.

Next, a third embodiment of the present invention will be described with reference to FIG.

In this example, an example is shown in which the downlink and uplink are separate optical transmission paths, and is indicated by M in the figure.

indicates the station side, S indicates each subscriber side, and the station side M3 and each subscriber S are connected by a downlink optical transmission path 33 and an uplink optical transmission path 39. Then, on the station side M, the data input to the terminal 31a is transferred to the switch circuit 31.
is supplied to the optical transmitter 32 via.

A monitoring pulse from a monitoring pulse generator 42 is also supplied to this switch circuit 31, and the transmission data obtained at the terminal 31a and the monitoring pulse are selectively supplied to the optical transmitter 31. In this case, switching of the switch circuit 31 is controlled by the activation detection circuit 41. This activation detection circuit 41 checks whether transmission data is supplied to the terminal 31a, and when there is transmission data, controls the transmission data obtained at the terminal 31 to be supplied to the optical transmitter 32, so that the transmission data is When the activation control signal is supplied from the timer circuit 43, which will be described later, the monitoring pulse generator 4
The optical transmitter 32 is controlled to supply two output pulses to the optical transmitter 32.

The monitoring pulse generator 42 and the activation detection circuit 41 are supplied with an activation control signal from a timer circuit 43 at predetermined time intervals (for example, 24 hours) to operate them.
Also, before outputting this activation control signal, loop control data is transmitted from the loop control circuit via the optical transmitter 32.

The optical signal transmitted from the optical transmitter 32 is transmitted to the optical receiver 34 on the subscriber side S via the optical transmission line 33, and the received signal from the optical receiver 34 is received via the loop switch 35. The received data is supplied to the data output terminal 35a, and the received data is output from the received data output terminal 35a. In this case, switching of the loop switch 35 is controlled by a loop control circuit 37, which will be described later, to establish a loop bank system that supplies the output signal of the optical receiver 34 to the optical transmitter 36 at a predetermined time. Then, the transmission data obtained at the terminal 35b is supplied to the optical transmitter 36 via the loop switch 35, and the optical signal transmitted from the optical transmitter 36 is transmitted to the station side M, via the optical transmission line 39.
The received signal of the optical receiver 38 is outputted from the received data output terminal 38a.

Here, returning to the configuration of the subscriber side S, the optical receiver 3
The received signal of 4 is supplied to a loop control circuit 37, and when this loop control circuit 37 receives the loop control data sent from the loop control circuit 40 of the station side M, the loop switch 35 controls the output of the optical receiver 34. Signal to optical transmitter 3
Establish a loopback system to return to 6. When the loop control data is not being received, the output data of the optical receiver 34 is supplied to the terminal 35a, and the data obtained at the terminal 35b is supplied to the optical transmitter 36.

Then, on the station side M, the received signal of the optical receiver 38 is supplied to the monitoring pulse detection circuit 44 together with the terminal 38a, and the pulse detection circuit 44 performs DC level detection of the monitoring pulse. When this is done, a trigger pulse is supplied to the counting circuit 45. And the count circuit 45
is reset by the trigger pulse and starts counting. Furthermore, this count time is compared with the time set by the timer circuit 43, and when the set interval is reached, a transmission line normal signal is output from the terminal 45a, and when it is longer than the set interval, a transmission line abnormal signal is output. is output from the terminal 45b.

Here, to explain the operation when monitoring the transmission path, first, when a predetermined period of time (for example, 24 hours) has elapsed since the timer circuit 43 last outputted the activation control signal, the loop control circuit 40 first outputs loop control data. With this loop control data, the loop switch 35 is activated on the subscriber side S.
Establish a loop bank system. In this state, the activation control signal is transmitted to the monitoring pulse generator 42 and the activation detection circuit 41.
When the normal pass is not performed, the switch circuit 31 is switched to the pulse generator 42 side, and the pulse generator 42 outputs a monitoring pulse.

This monitoring pulse is transmitted from the optical transmitter 32 to the subscriber side S via the optical transmission line 34, and the monitoring pulse received from the optical receiver 34 to the optical transmitter 36 is transmitted through the loop back system by the loop switch 35. Returning, this monitoring pulse is returned from the optical transmitter 36 to the office side M3 via the optical transmission line 39, and the pulse detection cycle is completed! 44 for detection. When the sending of the monitoring pulse is finished, the loop control circuit 40 sends out a loop cancellation command, and the loop control circuit 37 on the subscriber side S cancels the loop bank system by the loop switch 35.

After operating in this way, when a transmission path abnormality signal is obtained at the terminal 45b, the downlink or uplink transmission path 33 or 3
9 abnormalities are notified. According to the configuration of this third embodiment, even when the uplink and downlink optical transmission paths are separated,
The state of the optical transmission line can be monitored using the monitoring pulse signal.

〔Effect of the invention〕

According to the present invention, the state of the optical transmission path can be monitored by simply detecting the reception state of the monitoring pulse on the station side. in this case,
Since the monitoring pulse only needs to be output at predetermined intervals (for example, every 24 hours), power consumption is low. Furthermore, it can be monitored without affecting normal paths, and is suitable for large-scale transmission systems such as telephone lines.

[Brief explanation of drawings]

Fig. 1 is a block diagram showing a first embodiment of the present invention, Fig. 2 is a block diagram showing a second embodiment of the present invention, and Fig. 3 is a block diagram showing a third embodiment of the present invention. It is. 9, 21.33.39... Optical transmission line, 10.18.4
4... Monitoring pulse detection circuit, 11.20.45...
- Count circuit, 14, 26.42... Monitoring pulse generator, 15.30.43... Timer circuit, 25.3
1... Switch circuit, 35... Loop switch, 3
7.40...Loop control circuit.

Claims (1)

[Claims] 1. In an optical transmission system in which bidirectional communication is performed by optical transmission between a center side and each terminal side, a monitoring pulse is generated at each predetermined time on each terminal side, and the monitoring pulse is 1. An optical transmission path monitoring method, characterized in that a monitoring pulse is transmitted to the center side, and a monitoring pulse transmitted at the center side is detected. 2. The optical transmission path monitoring system according to claim 1, wherein the monitoring pulse generated at each terminal side is transmitted to the center side by wavelength multiplexing with other transmission data. 3. The optical transmission path monitoring system according to claim 1, wherein the monitoring pulse generated at each terminal side is transmitted to the center side by switching to a transmission path for other transmission data. 4. The monitoring pulse generated on each terminal side is characterized in that after confirming that the normal path is not being used, the transmission path is switched to another transmission data transmission path and transmitted to the center side. The optical transmission line monitoring system according to claim 1. 5. In an optical transmission system in which bidirectional communication is performed between a center side and each terminal side using separate optical transmission paths for uplink and downlink, a loop is established at each terminal side at predetermined time intervals under control from the center side. A back system is established, a monitoring pulse is sent from the center side to this loop back system, and the monitoring pulse returned by this loop back system on each terminal side is detected at the center side. Optical transmission path monitoring method. 6. Optical transmission line monitoring according to claim 5, characterized in that the establishment of a loopback system on each terminal side by control on the center side is performed after confirming that no normal path is being performed. method.