JPH09321715A - Optical reception monitor system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To avoid continuing communication in the state of a deteriorated transmission quality on a receiving side at the time of communication processing such as detecting the disconnection of an optical connector on a transmission side so as to deteriorate a transmission power. SOLUTION: A light transmission circuit 12 and a light receiving circuit 41 are connected through a transmission line 11 using the optical connector. When reflected and returned light from the transmission path becomes not less than a prescribed power, an optical fiber amplifier 22 on the side of the circuit 12 judges the generation of the disconnection of the optical connector and deteriorates the output of the amplifier 22. At the circuit 41, a branching coupler 52 branches an optical signal 31, an input monitor 55 monitors the deterioration of power, and when a counter 57 measures that this state is continued more than a prescribed time, the optical signal inputted from the branching coupler 52 to an inhibit circuit 63 through an optic/electric conversion circuit 32 is inhibited from being outputted to a frame synchronizing circuit 34. Thereby synchronizing processing is made impossible and reception by switching the optical signal to another transmission line 42 is realized.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical reception monitoring system for monitoring disconnection of an optical connector, and more particularly, to monitor an optical signal sent from a transmission line to cope with disconnection of the optical connector and other obstacles. Optical reception monitoring system.

[0002]

2. Description of the Related Art If an optical connector comes off for some reason,
There is a possibility that laser light may leak to the outside and harm the visual system of the human body. Therefore, an optical communication system using laser light has conventionally been provided with an optical reception monitoring circuit to deal with disconnection of an optical connector.

FIG. 2 shows an example of a conventional optical reception monitoring system. In this system, an optical transmission circuit 12 and an optical reception circuit 13 are arranged via a transmission line 11. The optical transmission circuit 12 has an optical fiber amplifier 22 that amplifies the optical signal 13. Optical fiber amplifier 22
The amplified optical signal 23 output from the optical fiber is sent out from the first transmission line connection point 25 ₁ to the transmission line 11, and is transmitted via a plurality of transmission line connection points 25 ₂ , 25 ₃ , ... 25 _N on the way. It reaches the receiving circuit 13.

The optical transmission circuit 12 is provided with a reflection monitor 27 for monitoring the reflected light at the _first transmission line connection point 25 ₁ which is the first connection point with the transmission line 11. Reflection monitor 27
Output signal 28 is a feedback control circuit (CONT)
29 is input. An optical output control signal 30 is supplied from the feedback control circuit 29 to the optical fiber amplifier 22.

On the other hand, in the optical receiving circuit 13, the optical signal 31 sent through the _Nth transmission line connection point 25 _N is input to the photoelectric conversion circuit (O / E) 32 and converted into an electrical signal.
The converted electric signal 33 is a frame synchronization circuit (SYNC).
The data is input to 34 and the synchronization processing is performed.

In such an optical reception monitoring system, when the optical connector is disconnected at any of the transmission line connection points 25 ₁ , 25 ₂ , ... 25 _N and an unconnected portion is generated, the end face of the optical fiber is aired. Touch to cause reflection. As a result, the reflected return light returns to the optical fiber amplifier 22 of the optical transmission circuit 12. The reflection monitor 27 accordingly outputs the output signal 28.
Increase. The feedback control circuit 29 detects the increase of the output signal 28 and controls the output of the optical fiber amplifier 22 by the optical output control signal 30.
That is, the output of the optical fiber amplifier 22 is not stopped when the disconnection of the optical connector is detected, but in this state, the optical fiber amplifier 22 sends out an optical signal of low output to the extent that there is no danger of the human body being harmed. The control is performed to reduce the output so that This means that when the condition of disconnection of the optical connector is resolved, the reflection monitor 27 detects that the reflected light is reduced, and the feedback control circuit 29 can restore the optical output of the optical fiber amplifier 22 to the normal state again. To do so.

[0007]

In the conventional optical reception monitoring system shown in FIG. 2, the output of the optical fiber amplifier 22 is lowered when the optical connector is disconnected, so that the optical receiving circuit 13 is sufficient. The optical signal 31 of power cannot be received. At this time, when the frequency of error occurrence is high, the optical receiving circuit 13 side can detect an abnormality and take action such as switching the transmission path. However, in the case where infrequently occurring errors occur continuously, the communication will continue forever in a state where the transmission quality is deteriorated.

Therefore, an object of the present invention is to allow the receiving side to continue the communication indefinitely when the transmitting side detects the disconnection of the optical connector and reduces the transmitting power. It is to provide an optical reception monitoring system that eliminates the problem.

[0009]

According to a first aspect of the present invention, there is provided an input monitor for monitoring the power of an optical signal sent from a transmission side through a transmission line connecting an optical fiber with an optical connector. (B) When the power of the optical signal suddenly decreases, the time measuring means for measuring the time during which the decreasing state continues, and (c) the time measuring means continuously continues for a predetermined time or longer. The optical reception monitoring system is provided with a signal transmission prohibiting means for prohibiting the optical signal from being sent to the circuit at the subsequent stage when the time is measured.

That is, according to the first aspect of the present invention, the power of the optical signal sent through the transmission line is monitored by the input monitor, and when the power of the optical signal sharply decreases, the decrease state continues. The optical signal is post-staged as a failure that has a high probability of not being promptly recovered, such as disconnection of the optical connector on the transmitting side, when the measured time exceeds the predetermined time. To prevent the adverse effect of receiving a signal whose transmission quality is degraded forever.

According to a second aspect of the present invention, (a) an optical fiber amplifier for sending an optical signal to a transmission line to which an optical fiber is connected by an optical connector, and a reflection for detecting reflected return light returning from the transmission line. An optical transmission circuit including a monitor and signal power reduction control means for reducing the power of the optical signal output from the optical fiber amplifier when the reflection monitor detects reflected return light having a predetermined power or more, and (b) a transmission line. An input monitor for monitoring the power of the optical signal sent from the transmission side via the, and for measuring the time during which the decrease state continues when the power of the sent optical signal sharply decreases. An optical receiving circuit provided with a clocking means and a signal transmission inhibiting means for inhibiting an optical signal from being sent to a circuit in a subsequent stage when the clocking means continuously clocks a time longer than a predetermined time. It is provided on the light reception monitoring system.

That is, according to the second aspect of the invention, the optical reception monitoring system comprises an optical transmission circuit and an optical reception circuit. Then, the optical transmission circuit reduces the power of the optical signal sent from the optical fiber amplifier to the transmission line, assuming that the optical connector disconnection has occurred when the reflected return light returning from the transmission line exceeds a predetermined power. In the optical receiver circuit, the input monitor monitors the power of the optical signal sent from the transmission side,
When this decreases sharply, the time when the decreasing state continues is measured by the time measuring means. The decrease in the power of the optical signal is
There are those that occur instantaneously due to the signal form or temporary fluctuations, and those that occur for a certain length of time, such as when the optical connector comes off. Therefore, when the time measuring means continuously measures a predetermined time or more, the optical signal is prohibited from being sent to the circuit in the subsequent stage, and in other cases, the prohibition is not performed. Thus, when a failure such as a disconnection of the optical connector that is unlikely to be recovered immediately occurs, it is possible to prevent the harmful effect of receiving a signal whose transmission quality is deteriorated forever.

According to the third aspect of the present invention, (a) an optical fiber amplifier for sending an optical signal to a transmission line to which an optical fiber is connected by an optical connector, and a reflection for detecting reflected return light returning from the transmission line. An optical transmission circuit including a monitor and signal power reduction control means for reducing the power of the optical signal output from the optical fiber amplifier when the reflection monitor detects reflected return light having a predetermined power or more, and (b) a transmission line. Branching means for branching the optical signal sent from the transmitting side via the optical path, optical / electrical signal converting means for converting one optical signal branched by the branching means into an electrical signal, and this optical / electrical signal conversion A synchronization processing means for inputting the electrical signal after being converted by the means to perform synchronization processing, an input monitor for monitoring the signal power of the other optical signal branched by the branching means, and this input The time measuring means, which is arranged between the optical / electrical signal converting means and the synchronous processing means, measures the time during which the reduction state continues when Nita detects a sudden decrease in the power of the optical signal. An optical reception monitoring system is provided with an optical receiving circuit having a signal transmission inhibiting means for inhibiting the output of an input electric signal when the time continuously counted for a predetermined time or longer.

That is, according to the third aspect of the invention, the optical reception monitoring system comprises an optical transmission circuit and an optical reception circuit. Then, the optical transmission circuit reduces the power of the optical signal sent from the optical fiber amplifier to the transmission line, assuming that the optical connector disconnection has occurred when the reflected return light returning from the transmission line exceeds a predetermined power. In the optical receiving circuit, the optical signal sent from the transmitting side via the transmission path is branched by the branching means and divided into two. Then, one optical signal is converted into an electric signal by the optical / electrical signal converting means as a normal processing, and this is input to the synchronous processing means to perform the synchronous processing. The power of the other optical signal branched by the branching means is monitored by the input monitor, and when the input monitor detects a sudden decrease in the power of the optical signal, the time keeping means is measured by the time measuring means. , When the time is continuously counted for a predetermined time or longer, the optical signal is transmitted to the synchronous processing means with respect to the signal transmission prohibiting means arranged between the optical / electrical signal converting means and the synchronous processing means. To ban. Also in the case of the invention described in claim 3, when a failure such as a disconnection of the optical connector that is unlikely to be recovered promptly occurs, a harmful effect of receiving a signal whose transmission quality is deteriorated forever is prevented. be able to.

According to a fourth aspect of the present invention, in the optical reception monitoring system according to the first or second aspect, the transmission path is switched when the signal transmission prohibiting means prohibits the optical signal from being sent to the subsequent circuit. It is characterized by comprising a transmission line switching means. That is, when the signal transmission prohibiting means prohibits the optical signal from being sent to the circuit at the subsequent stage, the circuit part at the subsequent stage is prohibited from sending the signal whose transmission quality is deteriorated, and the path for receiving the optical signal is switched. , Enables the reception of optical signals with no problem in transmission quality.

According to a fifth aspect of the present invention, the optical reception monitoring system according to the third aspect is characterized by comprising a transmission path switching means for switching the transmission path when the synchronization processing means detects a loss of synchronization. That is, while prohibiting the transmission of the signal whose transmission quality is deteriorated to the circuit part in the subsequent stage,
By switching the path through which the optical signal is received, it is possible to receive the optical signal with no problem in transmission quality.

[0017]

BEST MODE FOR CARRYING OUT THE INVENTION

[0018]

DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be described in detail below with reference to embodiments.

FIG. 1 shows an optical reception monitoring system according to an embodiment of the present invention. The same parts as those in FIG. 2 are designated by the same reference numerals, and the description thereof will be appropriately omitted.

The optical reception monitoring system of this embodiment has a structure in which an optical transmission circuit 12 and an optical reception circuit 41 are connected via a transmission line 11. The optical receiving circuit 41 also includes a standby communication unit (not shown) that switches the optical signal that is the same as the optical signal 23 transmitted by the optical transmitting circuit 12 to another transmission path 42 and receives the optical signal. The optical receiving circuit 41 includes an optical reception monitoring circuit 44 that starts receiving an optical signal and an opto-electric conversion circuit (O / O).
E) 32 and a frame synchronization circuit (SYNC) 34. The optical reception monitoring circuit 44 is provided between the Nth transmission line connection point 25 _N and the input side of the photoelectric conversion circuit 32, and between the output side of the photoelectric conversion circuit 32 and the input side of the frame synchronization circuit 34. It is arranged.

The branch coupler 52 the light reception monitoring circuit 44 for branching a part with transmitting it to input optical signal 31 obtained from the transmission path connection point 25 _N of the N to photoelectric conversion circuit 32 An input monitor 55 that inputs the branched optical signal 54 and monitors the signal power thereof, and a power drop detection signal 56 that is output when the input monitor 55 detects the drop state of the signal power. A counter 57 for inputting and counting the duration, and this counter 5
An oscillator (OSC) 59 for supplying a clock 58 for performing a counting operation to the counter 7 and a prohibition signal 61 output from a counter 57 when the power drop detection signal 56 does not stop even after counting a predetermined count value. And an inhibit circuit (INH) 63 which inputs the signal and sends out the passage of the electric signal 62. Here, the prohibiting circuit 63 is the photoelectric conversion circuit 3
This is a kind of switch circuit that performs on / off control when the converted electric signal 62 output from 2 is input and sent as an electric signal 65 to the frame synchronization circuit 34.

The circuit operation of such an optical reception monitoring system will be described below. First, the operation in a normal state in which the optical connector disconnection does not occur and the reflection monitor 27 of the optical transmission circuit 12 does not detect an increase in reflected light will be described. In this case, since the optical connector disconnection has not occurred, the optical fiber amplifier 22 amplifies the optical signal 21 with a normal amplification factor,
It is sent to the transmission line 11 via the first transmission line connection point 25 ₁ . In the optical receiving circuit 41, this is received by the photoelectric conversion circuit 32 via the branch coupler 52 and converted into an electric signal 62. The converted electric signal 62 passes through the prohibition circuit 63 as it is and is input to the frame synchronization circuit 34, where the synchronization processing is performed. In this normal state, the feedback control circuit 29 does not particularly lower the optical output of the optical fiber amplifier 22, so that the electric signal 62 has sufficient signal power, and good reception is performed.

Next, a case where the optical connector disconnection occurs in this optical reception monitoring system will be described. When the disconnection of the optical connector occurs, the reflection monitor 27 in the optical transmission circuit 12 detects an increase in the reflected light. This causes the reflection monitor 27 to increase the output signal 28. The feedback control circuit 29 detects the increase in the output signal 28 and detects the optical output control signal 30.
Control is performed to reduce the output of the optical fiber amplifier 22. When the optical connector is disconnected, the optical signal 31 is not input to the branch coupler 52 or the input power is reduced. This causes the input monitor 55 to detect the power drop detection signal 5
6 is continuously output. The counter 57 counts the clock 58 supplied from the oscillator 59 and outputs a prohibition signal 61 when the count reaches a count value corresponding to a predetermined time T.

The prohibition signal 61 is input to the prohibition circuit 63. The prohibiting circuit 63 prohibits outputting the electric signal 62 as the electric signal 65 from this point. As a result, the frame synchronization circuit 34 cannot perform the synchronization processing, and detects that some trouble has occurred in the circuit portion in the preceding stage or the transmission path 11. Therefore, a control signal for switching the optical signal to another transmission path 42 and receiving the optical signal is sent to a circuit portion (not shown). That is, for a relatively long period of time, such as when an optical connector disconnection occurs,
When a situation in which recovery from a failure cannot be expected occurs, loss of synchronization is used as a trigger to cause redundant switching of transmission lines in the network system.

On the other hand, a case where the power of the optical signal 23 sent from the optical transmission circuit 12 to the transmission path 11 is instantaneously lowered due to some cause other than the disconnection of the optical connector will be described.
The input monitor 55 detects a decrease in the input power of the branched optical signal 54, and outputs a power decrease detection signal 56 as in the case where the optical connector is disconnected. The counter 57 counts the clock 58 while detecting the power drop detection signal 56. However, in this case, when the power of the optical signal 23 is instantaneously reduced, the supply of the power reduction detection signal 56 is stopped before the counter 57 counts a predetermined count value. As a result, the counter 57 does not output the prohibition signal 61. Then, for example, the count value is initialized by a clear signal generated at a predetermined timing under the condition that the counting operation of the counter 57 is stopped.

When the power of the optical signal 23 is instantaneously lowered in this way, the prohibition circuit 63 is not supplied with the prohibition signal 61, so that the output of the electric signal 65 is continued. Moreover, since the power of the optical signal 23 drops instantaneously, the optical signal 31 is normally received thereafter. As described above, the optical transmission circuit 12 is common in that it detects a decrease in the power of the optical signal 31 in both cases of disconnection of the optical connector and other cases. However, in the former case, transmission line redundancy switching is performed, This prevents the situation where optical signals are continuously received with unstable transmission quality.

In the embodiment described above, the inhibit signal 6
Although it has been decided to input 1 to the prohibition circuit 63 to cause redundant switching of the transmission path of the network system, it is free to input this prohibition signal to other circuit parts to perform the same processing. is there.

[0028]

As described above, according to the first aspect of the present invention, the power of the optical signal sent through the transmission line is monitored by the input monitor, and the power of the optical signal is drastically reduced. Sometimes it is prohibited to send an optical signal to the circuit in the subsequent stage when the time during which the reduction state continues for a predetermined time or more.Therefore, in addition to disconnection of the optical connector, For failures that are not likely to be recovered promptly even if there is a failure of the above, it is possible to prevent the harmful effect of receiving a signal with poor transmission quality indefinitely and to retransmit the signal or receive the signal by another system. Can be given.

According to the second aspect of the invention, when the reflected return light returning from the transmission line has a predetermined power or more, the optical fiber amplifier is sent to the transmission line as if the optical connector is disconnected. In a communication system in which the power of the optical signal to be reduced is monitored, the power of the optical signal sent from the transmission side is monitored at the optical receiving circuit side, and when the power sharply decreases, the time during which the decrease state continues is measured. It is prohibited to send an optical signal to the circuit in the subsequent stage when it is measured for a certain period of time or longer and it is recovered not only by disconnection of the optical connector but also by other faults. For those that are not likely to be performed immediately, prevent the harmful effect of receiving a signal with poor transmission quality indefinitely, and retransmit the signal or receive the signal by another system. It can be obtained.

Further, according to the invention of claim 3, the same effect as that of the invention of claim 2 can be obtained, and in addition, since it is decided to prohibit the transmission of the optical signal to the synchronization processing means for performing the synchronization processing, the synchronization is achieved. It is possible to deal with optical connector disconnection along with other failures that are not dealt with.

Further, in the inventions according to claims 4 and 5, the transmission of the signal whose transmission quality is deteriorated is prohibited to the circuit part in the subsequent stage, and the path for receiving the optical signal is switched to improve the transmission quality. Since it is possible to receive an optical signal without problems, there is an advantage that the signal processing does not require a long time and real-time processing is possible as compared with the case where the optical signal is retransmitted.

[Brief description of drawings]

FIG. 1 is a block diagram showing a main part of a conventional optical reception monitoring system.

FIG. 2 is a block diagram showing a main part of an optical reception monitoring system according to an embodiment of the present invention.

[Explanation of symbols]

 11 transmission line 12 optical transmission circuit 22 optical fiber amplifier 25 transmission line connection point 27 reflection monitor 29 feedback control circuit 32 photoelectric conversion circuit 34 frame synchronization circuit 52 branch coupler 55 input monitor 57 counter 59 oscillator 63 inhibition circuit

─────────────────────────────────────────────────── ─── Continuation of the front page (51) Int.Cl. ⁶ Identification code Internal reference number FI technical display area H04B 10/04 10/06 10/08

Claims (5)

[Claims] 1. An input monitor for monitoring the power of an optical signal sent from a transmission side through a transmission line connecting an optical fiber with an optical connector, and a decrease state when the power of the optical signal sharply decreases. And a signal transmission for prohibiting the optical signal from being sent to a subsequent circuit when the time measuring means continuously measures a time longer than a predetermined time. An optical reception monitoring system comprising: a prohibition unit. 2. An optical fiber amplifier for sending an optical signal to a transmission line to which an optical fiber is connected by an optical connector, a reflection monitor for detecting reflected return light returning from the transmission line, and this reflection monitor is a predetermined one. An optical transmission circuit including a signal power reduction control unit that reduces the power of the optical signal output from the optical fiber amplifier when the reflected return light having a power or more is detected, and is transmitted from the transmission side via the transmission path. And an input monitor for monitoring the power of the optical signal, and a time measuring means for measuring the time during which the power of the transmitted optical signal sharply decreases, and the time measuring means for measuring in advance. An optical receiving circuit having a signal transmission inhibiting means for inhibiting the optical signal from being sent to a circuit in the subsequent stage when a time period longer than a predetermined time is continuously measured. Optical receiver monitoring system for the. 3. An optical fiber amplifier for sending an optical signal to a transmission line to which an optical fiber is connected by an optical connector, a reflection monitor for detecting reflected return light returning from the transmission line, and this reflection monitor is a predetermined one. An optical transmission circuit including a signal power reduction control unit that reduces the power of the optical signal output from the optical fiber amplifier when the reflected return light having a power or more is detected, and is transmitted from the transmission side via the transmission path. Means for branching the optical signal, an optical / electrical signal converting means for converting one optical signal branched by the branching means into an electric signal, and an electric signal after being converted by the optical / electrical signal converting means To perform a synchronization process, an input monitor for monitoring the signal power of the other optical signal branched by the branching device, and an input monitor for monitoring the signal power of the optical signal. Is arranged between the optical / electrical signal converting means and the synchronization processing means, the time measuring means measuring the time during which the decrease state continues when a rapid decrease in An optical reception monitoring system comprising: an optical reception circuit having a signal transmission inhibiting means for inhibiting the output of an input electric signal when the above time is continuously measured. 4. The transmission path switching means for switching the transmission path when the signal transmission prohibiting means prohibits sending an optical signal to a circuit in a subsequent stage. The optical reception monitoring system described. 5. The optical reception monitoring system according to claim 3, further comprising a transmission line switching unit that switches the transmission line when the synchronization processing unit detects out of synchronization.