JP2002335214A - Optical communication equipment - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an optical communication equipment which can simply detect abnormality in the reflecting level of signal light and a fluctuation in an output level and control an output corresponding thereto. SOLUTION: Signal light amplified by an erbium-added optical fiber 13 is outputted through a second connector 19 to the outside but one part thereof is photodetected by a first photodiode 21 in a beam splitting circuit 18 arranged at its preceeding stage and inputted to a reflection alarm detection/automatic power control part 42. Besides, light reflected and inputted from the side of the second connector 19 is photodetected from the beam splitting circuit 18 to the side of a second photodiode 26 and similarly inputted to the reflection alarm detection/automatic power control part 42. The reflection alarm detection/ automatic power control part 42 compares a value, which is provided by dividing the level or operating the difference of these two signals 22 and 43, with a reference value and switches an excited diode driving part 41 for driving an excited laser diode 16 to any one of control in the case of abnormality in the reflecting level of signal light and control for the fluctuation in the output level.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical communication device, and more particularly to an optical communication device that controls an output level when a failure occurs in a communication path or the like.

[0002]

2. Description of the Related Art In an optical communication apparatus, when a failure occurs in a communication path composed of an optical fiber or an optical connector, etc.
The transmitted light may leak to the outside and adversely affect the human body. Therefore, measures have been taken to prevent such a situation from occurring (JP-A-7-38).
498, etc.).

FIG. 3 shows an example of such an optical communication device. The signal light input from the first connector 11 of the optical communication device disclosed in Japanese Patent No. 2674558 is input to one end of the erbium-doped optical fiber 13 via the first optical isolator 12 and is directly optically amplified. You. The other end of the erbium-doped optical fiber 13 is connected to one end of a wavelength division multiplexing coupler (WDM) 14. The other end of the wavelength division multiplex coupler 14 is connected to a second isolator 15
And an excitation laser diode (excitation LD) 16. The pumping laser diode 16 is driven by a pumping diode driving unit 17, and the output laser diode is input to a wavelength division multiplexing coupler 14 to pump the erbium-doped optical fiber 13.

On the other hand, the signal light amplified by the pump light in the erbium-doped optical fiber 13 reaches the optical branching circuit 18 via the second isolator 15, where the signal is output to the second connector 19. The light is split into light and signal light received by the photodiode (PD) 21. First
The signal 22 indicating the level of the signal light received by the photodiode 21 is input to the automatic power control unit 23, and the power of the signal light output from the optical branch circuit 18 to the second connector 19 becomes constant. Such a control signal 24 is supplied to the excitation diode driving unit 17.

In this optical communication apparatus, problems such as disconnection of the second connector 19 and disconnection of an optical fiber as a communication path from the optical branching circuit 18 to the second connector 19 are caused by the following problems. Detection is performed based on an increase in reflected light from the point in time. Second connector 19
A part of the reflected light traveling toward the optical branching circuit 18 from the light is received by the second photodiode 26. The output 27 of the second photodiode 26 is the reflection alarm detector 2
8 is input. When the detected reflected light has increased to an abnormal level, the reflection alarm detection unit 28 supplies an output stop signal 29 to the excitation diode drive unit 17 to stop the output of the excitation laser diode 16.

When the fault is recovered after this, it is necessary to determine that the reflected light has become lower than the abnormal level and restart the output of the pump laser diode 16. Therefore, in this optical communication device, the timing signal 32 of a predetermined cycle output from the timing generator 31 is used.
, The short pulse 34 having a very short pulse width is output from the reflection alarm pulse generation unit 33. Only during the supply of the short pulse 34, the pumping diode driver 17 outputs the pumping laser diode 16 at short intervals. As a result, laser light having a pulse width that does not affect the human body is output from the optical branch circuit 18 toward the second connector 19. Reflection alarm detector 28
Is a timing signal 32 output from the timing generator 31
Is used to detect the level of the reflected light. The pump diode driving unit 17 stops the continuous output of the pump laser diode 16 during the abnormal level, but restarts the continuous output of the pump laser diode 16 when the level drops below the abnormal level. This allows the optical communication device to automatically resume normal communication when the failure is recovered.

[0007]

However, in the conventional optical communication apparatus shown in FIG. 3, since the reflection level of the signal light is detected, even if the signal light itself is abnormally output, the reflected light is not reflected. In general, the signal level itself increased only to such an extent that it could not be regarded as abnormal. Therefore, in such a case, control for stopping the output of the signal light could not be performed. Therefore, in order to stop the output of the signal light when the level of the signal light abnormally increases, a circuit portion for constantly monitoring the output level of the signal light is provided, and when this circuit portion detects an abnormal level, It was necessary to add a circuit for stopping the driving of the excitation diode driving unit 17.

However, this causes a problem that the circuit configuration of the optical communication device becomes complicated and the device becomes large.
In particular, the circuit part that detects and controls the abnormal level of reflected light and the circuit part that detects and controls the abnormal level of signal light output are separately provided, which complicates the control of these control units as a whole. did.

SUMMARY OF THE INVENTION It is an object of the present invention to provide an optical communication device capable of easily detecting an abnormality in the reflection level of signal light and a fluctuation in the output level and controlling the output so as to correspond to each. is there.

[0010]

According to the present invention, (a) amplifying means for amplifying the signal light, and (b) a signal for detecting the signal level of the signal light amplified by the amplifying means. Light level detecting means, (c) return light level detecting means for detecting the signal level of return light returning by reflection from the output side of the amplified signal light, and (d) these signal light level detecting means and (E) comparing the ratio detected by the return light level detection unit with a predetermined reference value to detect the ratio of the signal level detected by the return light level detection unit, Comparison determination means for determining whether the signal level of the return light with respect to the signal level of the signal light is larger than a normal value,
(F) first control signal generating means for outputting a signal for setting the signal level of the signal light after the amplification of the amplification means to a predetermined constant value, and (g) amplification of the amplification means. A second control signal generating means for outputting a signal for setting an amplifying state which is repeated in a short time and at a predetermined period for detecting return light, and a signal after being amplified as a result of comparison between the first control signal generating means and the comparing and judging means. When it is determined that the signal level of the return light with respect to the signal level of the light does not exceed the normal value range, the first
The signal output from the control signal generating means is selected and supplied to the amplifying means. When it is determined that the value exceeds the normal value range, the signal output from the second control signal generating means is selected and supplied to the amplifying means. And a control signal selecting means to be provided in the optical communication device.

That is, according to the first aspect of the present invention, the ratio of the signal level of the signal light amplified by the amplifying means to the signal level of the return light returning from the output side of the amplified signal light by reflection is determined. By comparing the ratio detected by the ratio detection means with a predetermined reference value, it is determined whether the signal level of the return light with respect to the signal level of the amplified signal light is larger than a normal value. The determination is made by the determination means. As a result of the comparison by the comparing and judging means, when it is judged that the signal level of the return light with respect to the signal level of the amplified signal light does not exceed the normal value range, the first control signal generating means outputs. The signal is selected and supplied to the amplifying means, and the signal level is controlled to be constant. Further, when it is determined that the value exceeds the normal value range, the signal output from the second control signal generation means is selected and supplied to the amplification means, so that the amplification of the amplification means can be returned and the light can be detected in a short time. A signal for setting an amplification state that is repeated at a predetermined cycle is output, the amplification is practically stopped, and short pulses are output intermittently in preparation for detection when the fault is recovered.

According to the second aspect of the present invention, (a) amplifying means for amplifying the signal light, (b) signal light level detecting means for detecting the signal level of the signal light amplified by the amplifying means, (C) return light level detection means for detecting the signal level of return light returning by reflection from the output side of the amplified signal light, and (d) signal light level detection means and return light level detection means. Dividing means for dividing the detected signal levels from each other;
Comparison determining means for comparing the value divided by the dividing means with a predetermined reference value to determine whether or not the signal level of the return light with respect to the signal level of the amplified signal light is larger than a normal value. (F) first control signal generation means for outputting a signal for setting the signal level of the signal light after amplification of the amplification means to a predetermined constant value, and (g) amplification means. A comparison between the second control signal generating means for outputting a signal for setting the amplification state to be repeated in a short time and at a predetermined period capable of detecting the return light in a short time and (h) comparing and judging means. When it is determined that the signal level of the return light with respect to the signal level of the signal light does not exceed the normal value range, the signal output from the first control signal generating means is selected and supplied to the amplifying means. Judgment is out of range The thereby and a control signal selecting means for supplying to the optical communication apparatus to the amplifier means selects the output signal of the second control signal generating means when.

That is, according to the second aspect of the present invention, the signal level of the signal light amplified by the amplifying means is divided by the signal level of the return light returned by reflection from the output side of the amplified signal light. Means for detecting the ratio of these signal levels, and comparing the value divided by the dividing means with a predetermined reference value, whereby the signal of the return light with respect to the signal level of the signal light after amplification is obtained. Whether or not the level is larger than a normal value is determined by the comparison determining means. As a result of the comparison by the comparing and judging means, when it is judged that the signal level of the return light with respect to the signal level of the amplified signal light does not exceed the normal value range, the first control signal generating means outputs. The signal is selected and supplied to the amplifying means, and the signal level is controlled to be constant. Further, when it is determined that the value exceeds the normal value range, the signal output from the second control signal generation means is selected and supplied to the amplification means, so that the amplification of the amplification means can be returned and the light can be detected in a short time. A signal for setting an amplification state that is repeated at a predetermined cycle is output, the amplification is practically stopped, and short pulses are output intermittently in preparation for detection when the fault is recovered.

According to the third aspect of the present invention, (a) amplifying means for amplifying the signal light, (b) signal light level detecting means for detecting the signal level of the signal light amplified by the amplifying means, (C) return light level detection means for detecting the signal level of return light returning by reflection from the output side of the amplified signal light, and (d) signal light level detection means and return light level detection means. Difference calculating means for calculating a difference between the detected signal levels,
(E) By comparing the value calculated by the difference calculating means with a predetermined reference value, it is determined whether the signal level of the return light with respect to the signal level of the amplified signal light is larger than a normal value. (F) first control signal generating means for outputting a signal for setting the signal level of the signal light having been amplified by the amplifying means to be a predetermined constant value; G) a second control signal generating means for outputting a signal for setting the amplification state to be repeated in a short time and at a predetermined period in which the amplification of the amplifying means can be detected in a short period of time and (h) a result of comparison between the comparing and judging means; When it is determined that the signal level of the return light with respect to the signal level of the amplified signal light does not exceed the normal value range, the signal output from the first control signal generation means is selected and supplied to the amplification means. ,
The optical communication apparatus is provided with control signal selecting means for selecting a signal output from the second control signal generating means when it is determined that the signal exceeds the normal value range and supplying the signal to the amplifying means.

That is, according to the third aspect of the present invention, the difference between the signal level of the signal light amplified by the amplifying means and the signal level of the return light returned by reflection from the output side of the amplified signal light is calculated. The ratio of these signal levels is detected by calculating by the difference calculating means, and the value calculated by the difference calculating means is compared with a predetermined reference value, whereby the return light with respect to the signal level of the amplified signal light is detected. Is determined by the comparing and determining means as to whether or not the signal level is larger than the normal value. As a result of the comparison by the comparing and judging means, when it is judged that the signal level of the return light with respect to the signal level of the amplified signal light does not exceed the normal value range, the first control signal generating means outputs. The signal is selected and supplied to the amplifying means, and the signal level is controlled to be constant. Further, when it is determined that the value exceeds the normal value range, the signal output from the second control signal generation means is selected and supplied to the amplification means, so that the amplification of the amplification means can be returned and the light can be detected in a short time. A signal for setting an amplification state that is repeated at a predetermined cycle is output, the amplification is practically stopped, and short pulses are output intermittently in preparation for detection when the fault is recovered.

According to a fourth aspect of the present invention, in the optical communication device according to any one of the first to third aspects, the second control signal generating means includes a timing for instructing a signal output timing at a predetermined cycle. It is characterized by comprising a generating means and a pulse generating means for generating a pulse having a short time width every time there is an instruction from the timing generating means.

That is, in the invention according to claim 4, the second control signal generating means includes a timing generating means for instructing a signal output timing at a predetermined cycle in order to repeatedly output a short pulse periodically. A pulse generator for generating a pulse having a short time width every time there is an instruction from the timing generator is provided.
Thus, even if a failure such as the disconnection of the connector on the output side occurs, it is possible to prevent the signal light from being radiated so as to cause harm to the human body.

According to a fifth aspect of the present invention, in the optical communication device according to any one of the first to third aspects, the amplifying means is a rare-earth-doped optical fiber, and controls the laser light output from the pump laser diode. Is used to control the presence or absence of amplification and the amplification factor.

That is, the invention according to claim 5 shows, as an example, a case where signal light is directly amplified by a rare earth-doped optical fiber such as an erbium-doped optical fiber. In this case, by controlling the laser light output from the pump laser diode, the output on / off and the amplification factor of the laser light can be controlled.

According to a sixth aspect of the present invention, in the optical communication device according to the first or second aspect, the signal levels detected by the signal light level detecting means and the return light level detecting means are clamped to non-zero values. It is characterized by having clamping means.

That is, in the invention according to claim 6, it is ensured that the ratio or the divided value obtained by providing the clamp means is a finite value.

[0022]

BEST MODE FOR CARRYING OUT THE INVENTION

[0023]

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

FIG. 1 shows the configuration of an optical communication apparatus according to an embodiment of the present invention. In FIG. 1, the same parts as those in FIG. 3 are denoted by the same reference numerals. In the optical communication device according to the present embodiment, the signal light input from the first connector 11 is input to one end of the erbium-doped optical fiber 13 via the first optical isolator 12 and is directly optically amplified. The other end of the erbium-doped optical fiber 13 is a wavelength division multiplex coupler 1
4 is connected to one end. The other end of the wavelength division multiplex coupler 14 is connected to each of the second isolator 15 and the pump laser diode 16. The pumping laser diode 16 is driven by a pumping diode driving unit 41. The output laser diode is input to the wavelength division multiplexing coupler 14 to pump the erbium-doped optical fiber 13.

On the other hand, the signal light amplified by the pumping light in the erbium-doped optical fiber 13 reaches the optical branching circuit 18 via the second isolator 15, where the signal is output to the second connector 19. The light is split into light and signal light received by the photodiode (PD) 21. First
The signal 22 indicating the level of the signal light received by the photodiode 21 is a reflection alarm detection / automatic power control unit 4.
2 is input. Further, the light traveling from the second connector 19 side toward the optical branch circuit 18 is branched here, and one of the lights is received by the second photodiode 26. A signal 43 indicating the signal level detected by the second photodiode 26 is also input to the reflection alarm detection / automatic power control unit 42. The excitation control signal 44 is supplied from the reflection alarm detection / automatic power control unit 42 to the excitation diode driving unit 41.

FIG. 2 shows the reflection alarm detection / automatic power control unit and its surroundings. The reflection alarm detection / automatic power control unit 42 includes a divider 51 that receives the signal 22 output from the first photodiode 21 and the signal 43 output from the second photodiode 26 and divides them. ing. Reflection alarm detection
The automatic power control unit 42 uses two signals 2 instead of the divider 51.
It may be configured by a difference calculator such as a subtractor that calculates the difference between 2, 43.

The divider 51 uses the signal 43 as the signal level of the reflected light as the denominator and the signal 22 as the signal level of the output light as the numerator. Therefore, the divider 51 is controlled so that the value of the signal 43 on the denominator side does not become “0”.
Is provided with a clamp circuit for correcting the input level in advance.

The output 52 of the divider 51 is supplied to a comparator 53
And compared with the reference voltage signal 54. Output 52
Is larger as the amplification factor of the erbium-doped optical fiber 13 is larger, and smaller as the signal component of the reflected light returning from the second connector 19 is larger. Therefore, when an abnormal situation such as disconnection of the second connector 19 occurs, the output 52 becomes the reference voltage signal 54.
And the comparison result 55 becomes “0”. In other cases, the comparison result 55 is “1”. Comparison result 5
5 is a timing generator 56 and a selector (SEL) 57
Are input to both of the selection control terminals. The timing generator 56 outputs a timing signal 58 having a predetermined cycle. The timing signal 58 is input to the reflection alarm pulse generator 59, and outputs a short pulse 61 having a very short pulse width at the input timing.

On the other hand, the signal 22 indicating the level of the signal light received by the first photodiode 21 is also supplied to the automatic power control unit 62. The automatic power control unit 62 controls the level of the input signal 22 to be constant, and inputs the signal 63 obtained as a result to the first input terminal I ₁ of the selector 57. The short pulse 6 periodically generated as described above.
1 is input to the second input terminal I ₂ of the selector 57. When the output 52 of the divider 51 is equal to or lower than the reference voltage signal 54 and the comparison result 55 is “0”, the selector 57 outputs a signal for selecting the _second input terminal I ₂ to the selector 57 as the comparison result 55. I do. In other cases, the selector selects the first input terminal I ₁ and the automatic power controller 6
2 is output to the selector 57 as the comparison result 55.

Therefore, if any abnormality occurs and the second
The level of light returning from the connector 19 becomes larger than a predetermined allowable value, and the comparison result 55 becomes “0”.
Then, the mode is switched to a mode in which the short pulse 61 is output from the reflection alarm pulse generation unit 59 at the timing (period) output by the timing generation unit 56. The excitation diode driving section 41 uses the short pulse 61 as the excitation control signal 44 to output a laser beam from the excitation laser diode 16 with an extremely short pulse width. Therefore, the signal light is output with this extremely short pulse width, and does not affect the human body.

When the fault is recovered in this state, the comparison result 55 changes from "0" to "1" from that point. Then, the selector 57 starts to select the signal 63 obtained from the automatic power control unit 62. Since this is a continuous output, the excitation diode drive unit 41 continuously excites the excitation laser diode 16. That is, this enables continuous output of the signal light at the time of restoration from the failure.

Further, the excitation diode driving section 41 variably controls the output level of the laser beam based on the signal 63 output from the automatic power control section 62 as the excitation control signal 44. Therefore, not only the monitoring of the reflected light but also the monitoring of the output level of the signal light can be performed at the same time.

In the embodiment described above, the optical communication device using the erbium-doped optical fiber 13 has been described. However, the present invention is similarly applied to other optical communication devices using a rare-earth-doped optical fiber or a semiconductor laser fiber. Of course, it can be applied. Also,
Although the optical communication device according to the embodiment is configured as a device that relays signal light, it is not limited to this, and may be configured as, for example, an optical transmitter. Further, in the embodiment, the pumping light is injected from the rear of the erbium-doped optical fiber 13, but the pumping light may be injected from the front.

[0034]

As described above, according to the first to third aspects of the present invention, as a result of the comparison by the comparison / determination means, the signal level of the return light with respect to the signal level of the amplified signal light is a normal level. When it is determined that the value does not exceed the value range, the signal output from the first control signal generating means is selected and supplied to the amplifying means.
The control signal selecting means for selecting the signal output from the control signal generating means and supplying the selected signal to the amplifying means is provided. Even after the signal to be output is selected and supplied to the amplifying means, the first signal is automatically output after the failure is recovered.
Is selected, and the continuous output of the signal light is restarted. Moreover, since the level of the signal light is controlled to be constant, the circuit control of the entire optical communication device is simplified, and the cost of the device can be reduced.

According to the fourth aspect of the present invention, the second control signal generating means instructs the signal output timing at a predetermined cycle in order to repeatedly output a short pulse periodically. And a pulse generating means for generating a pulse having a short time width every time there is an instruction from the timing generating means, so that even if a failure such as disconnection of the output side connector occurs, the human body is not affected. In addition to preventing harmful signal light irradiation, recovery from the failure can be detected immediately, and output of the signal light can be quickly restarted.

According to the sixth aspect of the present invention, there is provided a clamp means for clamping the signal level detected by the signal light level detecting means and the return light level detecting means to a non-zero value. Can be accurately compared.

[Brief description of the drawings]

FIG. 1 is a block diagram illustrating a configuration of an optical communication device according to an embodiment of the present invention.

FIG. 2 is a block diagram showing a reflection alarm detection / automatic power control unit and its periphery according to the embodiment;

FIG. 3 is a block diagram showing an example of a conventionally proposed optical communication device.

[Explanation of symbols]

 13 Erbium-doped optical fiber 16 Pump laser diode 18 Optical branch circuit 19 Second connector 21 First photodiode 22, 43 Signal 26 Second photodiode 41 Pump diode drive unit 42 Reflection alarm detection / automatic power control unit 51 Division Unit 53 comparator 56 timing generator 57 selector 62 automatic power controller

Claims (6)

[Claims] Amplifying means for amplifying the signal light; signal light level detecting means for detecting a signal level of the signal light amplified by the amplifying means; and an output side of the amplified signal light. Return light level detection means for detecting a signal level of return light returned by reflection; ratio detection means for detecting a ratio of signal levels detected by the signal light level detection means and the return light level detection means; Comparison determining means for determining whether the signal level of the return light with respect to the signal level of the amplified signal light is larger than a normal value by comparing the ratio detected by the ratio detecting means with a predetermined reference value. First control signal generating means for outputting a signal for setting the amplification of the amplifying means so that the signal level of the signal light after the amplification becomes a predetermined constant value A second control signal generating means for outputting a signal for setting the amplification of the amplifying means to an amplifying state which is repeated in a short time and a predetermined cycle capable of detecting the return light, and a comparison result of the comparing and judging means. When it is determined that the signal level of the return light with respect to the signal level of the signal light after the signal processing does not exceed the normal value range, a signal output from the first control signal generation means is selected and supplied to the amplification means. When it is determined that the value exceeds the normal value range, the second
And a control signal selecting means for selecting a signal output from the control signal generating means and supplying the selected signal to the amplifying means. Amplifying means for amplifying the signal light; signal light level detecting means for detecting a signal level of the signal light amplified by the amplifying means; and an output side of the amplified signal light. Return light level detection means for detecting a signal level of return light returned by reflection; division means for dividing the signal levels detected by the signal light level detection means and return light level detection means, respectively; By comparing the value divided by a predetermined reference value, a comparison determination unit that determines whether the signal level of the return light with respect to the signal level of the amplified signal light is greater than a normal value, First control signal generating means for outputting a signal for setting the amplification of the amplifying means so that the signal level of the amplified signal light becomes a predetermined constant value; A second control signal generating means for outputting a signal for setting the amplification of the amplifying means to an amplifying state which is repeated in a short time and at a predetermined period capable of detecting the return light; When it is determined that the signal level of the return light with respect to the signal level of the signal light after the signal light does not exceed the normal value range, a signal output from the first control signal generation means is selected and supplied to the amplification means. When it is determined that the value exceeds the normal value range,
And a control signal selecting means for selecting a signal output from the control signal generating means and supplying the selected signal to the amplifying means. Amplifying means for amplifying the signal light, signal light level detecting means for detecting a signal level of the signal light amplified by the amplifying means, and an output side of the amplified signal light. Return light level detection means for detecting a signal level of return light returned by reflection; difference calculation means for obtaining a difference between signal levels detected by the signal light level detection means and the return light level detection means; By comparing the value calculated by the calculating means with a predetermined reference value, comparing and determining means for determining whether the signal level of the return light with respect to the signal level of the amplified signal light is greater than a normal value. A first control signal generator for outputting a signal for setting the amplification of the amplifying means so that the signal level of the amplified signal light becomes a predetermined constant value; A second control signal generating means for outputting a signal for setting the amplification of the amplifying means to an amplifying state that is repeated in a short time and a predetermined cycle capable of detecting the return light, and a comparison result of the comparison determining means, When it is determined that the signal level of the return light with respect to the signal level of the amplified signal light does not exceed the normal value range, a signal output from the first control signal generating means is selected and sent to the amplifying means. And when it is determined that the value exceeds the normal value range, the second
And a control signal selecting means for selecting a signal output from the control signal generating means and supplying the selected signal to the amplifying means. 4. The second control signal generator includes a timing generator for instructing a signal output timing at a predetermined cycle, and generates a pulse having a short time width every time the timing generator instructs. The optical communication device according to claim 1, further comprising a pulse generator. 5. The amplifying means is a rare-earth-doped optical fiber, wherein the presence or absence of amplification and the amplification factor are controlled by controlling laser light output from a pump laser diode. The optical communication device according to claim 3. 6. The apparatus according to claim 1, further comprising a clamp unit for clamping a signal level detected by the signal light level detection unit and a return light level detection unit to a value other than zero. Optical communication device.