JP3332065B2 - System margin measuring device - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

The present invention relates to a system margin measuring device for measuring a system margin of an optical communication system.

[0002]

2. Description of the Related Art The system margin of an optical communication system is as follows.
It refers to the difference between the received light intensity (reception sensitivity) required for the receiver to receive an optical signal at a specified error rate or less and the minimum received light intensity of the receiver. As the receiver is used for a long period of time, various components are deteriorated or the adjustment is shifted, the amount of intersymbol interference increases, and the receiving sensitivity decreases. Therefore, a predetermined difference is given in advance as a system margin between the reception sensitivity and the minimum reception light intensity.

[0003] In the conventional system margin measuring apparatus, when light having the minimum received light intensity is incident on the receiver, the intersymbol interference light is artificially superimposed on the main signal light, and the code error rate characteristic deteriorates in the receiver. By measuring the relationship between the degree of interference and the amount of intersymbol interference, the system margin of the optical communication system is evaluated. FIG. 6 shows a configuration example of a conventional system margin measuring device.

In FIG. 1, a main signal light transmitted from a transmitter 21 is received by a receiver 25 via an optical fiber 22-1, an attenuator 23-1, an optical coupler 24, and an optical fiber 22-2. On the other hand, the intersymbol interference light output from the intersymbol interference signal light source 26 is transmitted to the optical coupler 2 via the attenuator 23-2.
4 and superimposed on the main signal light. An optical power meter (PM) 27 for monitoring the input power of the receiver 25 is connected to the optical coupler 24. With such a configuration,
The attenuator 23-1 is adjusted to set the receiver input optical power of the main signal light, and the attenuator 23-2 is adjusted to that value to change the intersymbol interference light, and the light is generated by the receiver 25. The system margin is measured by detecting the bit error rate.

[0005]

The system margin measuring device shown in FIG. 6 is applied to a one-way optical communication system and cannot be applied to a two-way optical communication system as it is. In the bidirectional optical communication system, the upstream and downstream transceivers face one optical fiber transmission line, and it is necessary to measure the system margin for each of the upstream and downstream optical communication systems. However, as shown in FIG. 7, in a configuration in which the intersymbol interference light is superimposed on the upstream main signal light, the system margin can be measured by the receiver 25-2 in the upstream optical communication system. Cannot measure the system margin of the optical communication system. Therefore, to perform the measurement, the intersymbol interference signal light source 26, the attenuator 23-2,
The optical coupler 24 needs to be reconnected.

In a two-way optical communication system, opposing transceivers operate while communicating with each other. Therefore, in the configuration shown in FIG. 7, when the loss of the attenuator 23-1 inserted in the transmission path of the main signal light is increased, the input power of both the upstream and downstream receivers is simultaneously reduced, and the system of one optical communication system is reduced. Before measuring the margin, the smaller system margin is in an operation stop state, and the entire system operation is stopped. For this reason, the system margin of each of the upstream and downstream optical communication systems cannot be measured independently.

When the system margin of a bidirectional optical communication system is measured, even if it is necessary to simultaneously monitor the uplink signal power, the downlink signal power, and the intersymbol interference signal power, the configuration shown in FIG. The signal power could not be measured. SUMMARY OF THE INVENTION It is an object of the present invention to provide a system margin measuring apparatus capable of measuring a system margin of a bidirectional transmitting / receiving circuit with a simple configuration in a bidirectional optical communication system using one optical fiber transmission line. I do.

[0008]

SUMMARY OF THE INVENTION A system margin measuring apparatus according to the present invention comprises two optical paths inserted into an optical fiber transmission line.
And the main signal light propagating through the optical fiber transmission line is
Connecting means for switching to and connecting to two optical paths, and two optical paths
And an attenuator that independently gives a loss to the two-way main signal light propagating through the attenuator. As a result, the main signal power can be set independently for uplink and downlink. Further, means for superimposing the attenuator providing a loss to the intersymbol interference light, the intersymbol interference light gives a predetermined loss in both directions of the main signal light, bi
Independent main signal light power and intersymbol interference light power
Monitor measurement, and monitor measurement according to each attenuator setting.
Measured power readings at the output port of the instrument
By providing a means for calibrating based on the value, the power of the intersymbol interference light can be set independently for the uplink and downlink, and the system margin in the bidirectional transmission / reception circuit can be measured.

[0009]

DESCRIPTION OF THE PREFERRED EMBODIMENTS In the following embodiments, a configuration using two circulators as connection means (first embodiment), a configuration using one circulator and one optical coupler (second embodiment) And the third embodiment). Also, a configuration using an optical switch and an optical coupler as means for superimposing the intersymbol interference light on one of the bidirectional main signal lights will be described (each embodiment).

(First Embodiment) FIG. 1 shows a first embodiment of a system margin measuring apparatus according to the present invention. In the figure, a transmitter 2 opposing via one optical fiber transmission line
The main signal light transmitted from 1-1 to the receiver 25-1 is a down signal, and the main signal light transmitted from the transmitter 21-2 to the receiver 25-2 is an up signal. (a) shows an embodiment at the time of a downlink signal test, and (b) shows an embodiment at the time of an uplink signal test.

(During Downlink Signal Test) In FIG. 1A, a downlink signal transmitted from a transmitter 21-1 is transmitted to a port 11-.
1 is input to the circulator 12-1 and separated from the upstream signal path.
1 is input. The intersymbol interference light output from the intersymbol interference signal light source 26 is input to the optical switch 13-1 via the attenuator 23-3, and further to the optical coupler 24-1. The upstream signal and the intersymbol interference light superimposed by the optical coupler 24-1 are input to the circulator 12-2, combined with the upstream signal path again, output as a test signal from the port 11-2, and output to the receiver 25-1. Is entered. Also, a part of the downstream signal and the intersymbol interference light is branched by the optical coupler 24-1 and is transmitted via the optical switch 13-2 to the optical power meter (P
M) 27-1 or monitor port 14. An oblique connector or an isolator is arranged at the monitor port 14.

The power of the downstream signal is measured by splitting a part of the downstream signal by the optical coupler 24-1 and switching the optical switch 13-2 to input to the optical power meter 27-1. At this time, the intersymbol interference light sets the loss of the attenuator 23-3 to infinity or switches the optical switch 13-1 to change the optical coupler 24.
It is set to a state where it is not multiplexed by -1. In addition, the reading value of the optical power meter 27-1 is based on the optical power meter (PM) prepared separately for the downlink signal power at the port 11-2 in advance.
Measure directly at 27-2 and calibrate.

The power of the intersymbol interference light to be superimposed on the downlink signal is obtained by branching a part of the intersymbol interference light by the optical coupler 24-1.
By switching the optical switch 13-2, the optical power meter 27-
Input to 1 and measure. At this time, the downstream signal is transmitted to the attenuator 2
The loss of 3-1 is set to infinity so as not to be multiplexed by the optical coupler 24-1. The optical power meter 27-1
Is measured in advance by directly measuring the intersymbol interference light power at the port 11-2 by an optical power meter 27-2 separately prepared and calibrated.

As described above, by calibrating the value of the optical power meter 27-1 based on the measured value of the optical power meter 27-2, the optical power of the downlink signal and the intersymbol interference light at the port 11-1 can be reduced. Can be set accurately, and attenuator 2
The loss values of 3-1 and 23-3 can be calibrated. Next, the transmitter 21-1 transmits the pulse pattern generator (PP
G) Output a downstream signal intensity-modulated by the test signal given from 15-1. The optical power S of this downstream signal is set by adjusting the attenuator 23-1. On the other hand, the attenuator 23
-3 is adjusted to change the optical power X of the intersymbol interference light,
This intersymbol interference light is superimposed on the downstream signal via the optical switch 13-1 and the optical coupler 24-1, and the intersymbol interference amount (S / X) in the receiver 25-1 is set. Receiver 25
The error rate measuring device (ED) 16-1 connected to -1 detects a code error rate corresponding to the intersymbol interference (S / X) set by the attenuators 23-1 and 23-3, The system margin in the downlink direction (S / X for a predetermined error rate) is measured.

Here, the intersymbol interference (S / X) is defined by the ratio of the peak value of the downlink signal (S) to the peak value of the intersymbol interference light (X). On the other hand, what can be measured is the average power of the downlink signal and the intersymbol interference light. Therefore, in order to know the actual amount of intersymbol interference, it is necessary to determine the extinction ratio (on / off ratio) of a downlink signal or intersymbol interference light from waveform measurement. When the downstream signal or the intersymbol interference light is a signal on a burst, it is necessary to monitor the waveform of each signal and directly measure the peak value. For this purpose, the optical switch 13-2 is switched to take out the branch light to the monitor port 14, and the downstream signal waveform, the intersymbol interference light waveform, or the multiplexed light waveform thereof is monitored.

(Uplink Signal Test) In FIG. 1B, the uplink signal transmitted from the transmitter 21-2 is transmitted to the port 11-
2 is input to the circulator 12-2, separated from the downstream signal path, and passed through the attenuator 23-2 to the optical coupler 24-2.
2 is input. The intersymbol interference light output from the intersymbol interference signal light source 26 is input to the optical switch 13-1 via the attenuator 23-3, and further to the optical coupler 24-2. The downstream signal and the intersymbol interference light superimposed by the optical coupler 24-2 are input to the circulator 12-1, are combined with the downstream signal path again, are output as a test signal from the port 11-1, and are output to the receiver 25-2. Is entered. In addition, a part of the upstream signal and the intersymbol interference light is branched by the optical coupler 24-2, and is transmitted through the optical switch 13-2 to the optical power meter 27.
-1 or connected to the monitor port 14.

The power of the upstream signal is measured by splitting a part of the upstream signal by the optical coupler 24-2, switching the optical switch 13-2, and inputting it to the optical power meter 27-1. At this time, the intersymbol interference light sets the loss of the attenuator 23-3 to infinity or switches the optical switch 13-1 to change the optical coupler 24.
It is set to a state where it is not combined at -2. Note that the reading value of the optical power meter 27-1 is based on the optical power meter 27-2 prepared separately in advance for the upstream signal power at the port 11-1.
Measure directly with and calibrate.

The power of the intersymbol interference light superimposed on the upstream signal is obtained by splitting a part of the intersymbol interference light by the optical coupler 24-2.
By switching the optical switch 13-2, the optical power meter 27-
Input to 1 and measure. At this time, the upstream signal is supplied to the attenuator 2
The loss of 3-2 is set to infinity so as not to be multiplexed by the optical coupler 24-2. The optical power meter 27-1
Is calibrated by directly measuring the intersymbol interference light power at the port 11-1 in advance by using a separately prepared optical power meter 27-2.

As described above, by calibrating the value of the optical power meter 27-1 based on the measured value of the optical power meter 27-2, the optical power of the upstream signal and the intersymbol interference light at the port 11-1 can be reduced. Can be set accurately, and attenuator 2
The loss values of 3-2 and 23-3 can be calibrated. Next, the transmitter 21-2 includes a pulse pattern generator 15-2.
And outputs an uplink signal that is intensity-modulated by the test signal given by Similarly, a code error rate corresponding to the intersymbol interference (S / X) set by the attenuators 23-2 and 23-3 is detected, and the system margin in the uplink direction is measured.
To set the intersymbol interference amount (S / X), the optical switch 13-2 is switched to take out the branched light to the monitor port 14, and monitor the upstream signal waveform, the intersymbol interference light waveform, or its combined optical waveform. I do.

(Second Embodiment) FIG. 2 shows a second embodiment of the system margin measuring apparatus according to the present invention. In the figure, a transmitter 2 opposing via one optical fiber transmission line
The main signal light transmitted from 1-1 to the receiver 25-1 is a down signal, and the main signal light transmitted from the transmitter 21-2 to the receiver 25-2 is an up signal. (a) shows an embodiment at the time of a downlink signal test, and (b) shows an embodiment at the time of an uplink signal test.

(During Downlink Signal Test) In FIG. 2A, the downlink signal transmitted from the transmitter 21-1 is transmitted to the port 11-.
1 is input to the optical coupler 24-1 and branched. One of the downstream signals is input to the circulator 12 via the attenuator 23-1, and combined with the upstream signal path to form an optical coupler 24.
-2 is input. The other downstream signal branched by the optical coupler 24-1 is input to the circulator 12 via the attenuator 23-2 and terminated. The intersymbol interference light output from the intersymbol interference signal light source 26 is input to the optical switch 13-1 via the attenuator 23-3, and is further input to the optical coupler 24-
2 is input. The downlink signal and the intersymbol interference light superimposed by the optical coupler 24-2 are output as test signals from the port 11-2 via the optical coupler 24-3, and are output to the receiver 25-1.
Is input to

A part of the downstream signal and the intersymbol interference light is branched by the optical coupler 24-3, and is divided by the optical power meter (PM) 2
7-1. Further, a part of the downstream signal and the intersymbol interference light is branched by the optical coupler 24-2 and is divided by the optical switch 1.
It is connected to the monitor port 14-1 via 3-1. The power of the downstream signal is measured by branching a part of the downstream signal by the optical coupler 24-3 and inputting the branched signal to the optical power meter 27-1.
At this time, the intersymbol interference light is set such that the loss of the attenuator 23-3 is made infinite or the optical switch 13-1 is switched so that the optical coupler 24-2 does not multiplex it with the downstream signal.
Note that the reading value of the optical power meter 27-1 is directly measured and calibrated in advance by using an optical power meter (PM) 27-3 separately prepared for the downstream signal power at the port 11-2.

The power of the intersymbol interference light superimposed on the downlink signal is obtained by splitting a part of the intersymbol interference light by the optical coupler 24-3.
Input to the optical power meter 27-1 and measure. At this time,
The downstream signal is set to a state in which the loss of the attenuator 23-1 is made infinite and is not multiplexed by the optical coupler 24-2. Note that the reading of the optical power meter 27-1 is determined in advance by the port 11-2.
Is directly measured and calibrated by an optical power meter 27-3 separately prepared.

As described above, by calibrating the value of the optical power meter 27-1 based on the measured value of the optical power meter 27-3, the optical power of the downlink signal and the intersymbol interference light at the port 11-2 can be reduced. Can be set accurately, and attenuator 2
The loss values of 3-1 and 23-3 can be calibrated. Next, the transmitter 21-1 transmits the pulse pattern generator (PP
G) Output a downstream signal intensity-modulated by the test signal given from 15-1. Hereinafter, similarly, the attenuators 23-1,
A code error rate corresponding to the intersymbol interference (S / X) set by 23-3 is detected by an error rate measuring device (ED) 16-1 and a system margin in a downlink direction is measured. To set the amount of intersymbol interference (S / X), as in the first embodiment, the split light is extracted to the monitor port 14-1, and the downstream signal waveform, the intersymbol interference light waveform, or the multiplexed light thereof is used. Monitor the waveform.

(Uplink Signal Test) In FIG. 2B, the uplink signal transmitted from the transmitter 21-2 is transmitted to the port 11-
2 to the optical couplers 24-3 and 24-2. The intersymbol interference light output from the intersymbol interference signal light source 26 is input to the optical switch 13-1 via the attenuator 23-3,
Further, it is input to the optical coupler 24-2. Optical coupler 24-
The upstream signal and the intersymbol interference light superimposed in 2 are input to the circulator 12 and separated from the downstream signal path. The upstream signal and the intersymbol interference light output from the circulator 12 are input to the optical coupler 24-1 via the attenuator 23-2, are combined with the downstream signal path, and are output from the port 11-1 as a test signal. , Receiver 25-2.

A part of the upstream signal and the intersymbol interference light is branched by the optical coupler 24-1 and connected to the optical power meter (PM) 27-2 via the optical switch 13-2. Also,
The upstream signal is branched by the optical coupler 24-3 and the optical switch 13
By connecting to the monitor port 14-2 via -2, the waveform of the upstream signal can be monitored. In addition, the intersymbol interference light is branched by the optical coupler 24-2, and the optical switch 13-
By connecting to the monitor port 14-1 via 1, it is possible to monitor the waveform of the intersymbol interference light.

The power of the upstream signal is measured by splitting a part of the upstream signal by the optical coupler 24-1 and inputting it to the optical power meter 27-2 via the optical switch 13-2. At this time,
The intersymbol interference light sets the loss of the attenuator 23-3 to infinity or switches the optical switch 13-1 to change the optical coupler 24-2.
In such a way that it is not multiplexed with the upstream signal. The read value of the optical power meter 27-2 is calibrated by directly measuring the upstream signal power at the port 11-1 by an optical power meter (PM) 27-3 separately prepared in advance.

The power of the intersymbol interference light to be superimposed on the upstream signal is obtained by branching a part of the intersymbol interference light by the optical coupler 24-1.
By switching the optical switch 13-2, the optical power meter 27-
Input to 2 and measure. The power of the intersymbol interference light at this time is set by the sum of the respective losses of the attenuators 23-3 and 23-2. Therefore, before inputting the upstream signal,
A correspondence table between the intersymbol interference light power and the sum of the loss of each attenuator is created. In addition, the read value of the optical power meter 27-2 is measured and calibrated in advance by measuring the intersymbol interference light power at the port 11-1 with the separately prepared optical power meter 27-3.

As described above, by calibrating the value of the optical power meter 27-2 based on the measured value of the optical power meter 27-3, the optical power of the uplink signal and the intersymbol interference light at the port 11-1 can be reduced. Can be set accurately, and attenuator 2
The loss values of 3-2 and 23-3 can be calibrated. Next, the transmitter 21-2 outputs a pulse pattern generator (PP
G) Output an upstream signal intensity-modulated by the test signal given from 15-2. Hereinafter, similarly, the attenuator 23-2,
A code error rate corresponding to the intersymbol interference amount (S / X) set by 23-3 is detected by an error rate measuring device (ED) 16-2, and a system margin in an uplink direction is measured. To set the intersymbol interference amount (S / X), as in the first embodiment, the split light is extracted to the monitor ports 14-1 and 14-2, and the uplink signal waveform and the intersymbol interference light waveform are converted. Monitor.

(Third Embodiment) FIG. 3 shows a third embodiment of the system margin measuring apparatus according to the present invention. In the figure, a transmitter 2 opposing via one optical fiber transmission line
The main signal light transmitted from 1-1 to the receiver 25-1 is a down signal, and the main signal light transmitted from the transmitter 21-2 to the receiver 25-2 is an up signal. (a) shows an embodiment at the time of a downlink signal test, and (b) shows an embodiment at the time of an uplink signal test.

(During Downlink Signal Test) In FIG. 3 (a), the downlink signal transmitted from the transmitter 21-1 is transmitted to the port 11-
1 is input to the optical coupler 24-1 and branched. One of the downstream signals is input to the circulator 12 via the attenuator 23-1, and combined with the upstream signal path to form an optical coupler 24.
-2 is input. The other downstream signal branched by the optical coupler 24-1 is input to the circulator 12 via the attenuator 23-2 and terminated. The intersymbol interference light output from the intersymbol interference signal light source 26 is input to the optical switch 13-1 via the attenuator 23-3, and is further input to the optical coupler 24-
2 is input. The downlink signal and the intersymbol interference light superimposed by the optical coupler 24-2 are output as test signals from the port 11-2 and input to the receiver 25-1. Also, a part of the downstream signal and the intersymbol interference light is branched by the optical coupler 24-2 and connected to the optical power meter (PM) 27-1 or the monitor port 14 via the optical switches 13-1 and 13-2. You.

As for the power of the downstream signal, a part of the downstream signal is branched by the optical coupler 24-2, and the optical switches 13-1, 13-
2 to the optical power meter 27-1 for measurement.
At this time, the loss of the intersymbol interference light in the attenuator 23-3 is made infinite so that the inter-symbol light is not combined with the downstream signal by the optical coupler 24-2. In addition, the reading value of the optical power meter 27-1 is directly measured in advance by a separately prepared optical power meter (PM) 27-2 at the port 11-2 and calibrated.

The power of the intersymbol interference light superimposed on the downlink signal is obtained by branching a part of the intersymbol interference light by the optical coupler 24-2.
The signal is input to the optical power meter 27-1 via the optical switches 13-1 and 13-2 and measured. At this time, the loss of the downstream signal is made infinite by setting the loss of the attenuator 23-1 to infinity so that the optical coupler 24-2 does not multiplex the downstream signal. The optical power meter 2
The reading of 7-1 is obtained by directly measuring the intersymbol interference light power at the port 11-2 in advance by using a separately prepared optical power meter 27-2, and calibrating the measured value.

As described above, by calibrating the value of the optical power meter 27-1 based on the measured value of the optical power meter 27-2, each optical power of the downstream signal and the intersymbol interference light at the port 11-2 is reduced. Can be set accurately, and attenuator 2
The loss values of 3-1 and 23-3 can be calibrated. Next, the transmitter 21-1 transmits the pulse pattern generator (PP
G) Output a downstream signal intensity-modulated by the test signal given from 15-1. Hereinafter, similarly, the attenuators 23-1,
A code error rate corresponding to the intersymbol interference (S / X) set by 23-3 is detected by an error rate measuring device (ED) 16-1 and a system margin in a downlink direction is measured. To set the intersymbol interference amount (S / X), as in the first embodiment, the branched light is extracted to the monitor port 14 and the downstream signal waveform, the intersymbol interference light waveform, or the multiplexed light waveform thereof is converted. Monitor.

(Uplink Signal Test) In FIG. 3B, the uplink signal transmitted from the transmitter 21-2 is transmitted to the port 11-
2 to the optical coupler 24-2. The intersymbol interference light output from the intersymbol interference signal light source 26 is
3, and is input to the optical switch 13-1 and further to the optical coupler 24-2. The upstream signal and the intersymbol interference light superimposed by the optical coupler 24-2 are input to the circulator 12 and separated from the downstream signal path. The upstream signal and the intersymbol interference light output from the circulator 12 are input to the optical coupler 24-1 via the attenuator 23-2, are combined with the downstream signal path, and are output from the port 11-1 as a test signal. , Receiver 25-2.

A part of the upstream signal and the intersymbol interference light is branched by the optical coupler 24-1 and connected to the optical power meter 27-1 via the optical switch 13-2. Also, a part of the upstream signal and the intersymbol interference light are branched by the optical coupler 24-2, and connected to the monitor port 14 via the optical switches 13-1 and 13-2. The power of the upstream signal is
At 4-1, a part of the upstream signal is branched, and the optical switch 13-
The signal is input to the optical power meter 27-1 via the optical modulators 1 and 13-2 and measured. At this time, the intersymbol interference light is transmitted to the attenuator 23-3.
Is infinite, and the optical coupler 24-2 is set so as not to be multiplexed with the upstream signal. The optical power meter 2
The read value of 7-1 is measured in advance by directly measuring the upstream signal power at the port 11-1 by an optical power meter 27-2 separately prepared and calibrated.

The power of the intersymbol interference light superimposed on the upstream signal is obtained by branching a part of the intersymbol interference light by the optical coupler 24-1.
By switching the optical switch 13-2, the optical power meter 27-
Input to 1 and measure. The power of the intersymbol interference light at this time is set by the sum of the respective losses of the attenuators 23-3 and 23-2. Therefore, before inputting the upstream signal,
A correspondence table between the intersymbol interference light power and the sum of the loss of each attenuator is created. In addition, the reading value of the optical power meter 27-1 is directly measured in advance by the optical power meter 27-2 separately prepared for the intersymbol interference light power at the port 11-1, and calibrated in advance.

As described above, by calibrating the value of the optical power meter 27-1 based on the measured value of the optical power meter 27-2, the optical power of the upstream signal and the intersymbol interference light at the port 11-1 can be reduced. Can be set accurately, and attenuator 2
The loss values of 3-2 and 23-3 can be calibrated. Next, the transmitter 21-2 outputs a pulse pattern generator (PP
G) Output an upstream signal intensity-modulated by the test signal given from 15-2. Hereinafter, similarly, the attenuator 23-2,
A code error rate corresponding to the intersymbol interference amount (S / X) set by 23-3 is detected by an error rate measuring device (ED) 16-2, and a system margin in an uplink direction is measured. To set the intersymbol interference amount (S / X), as in the first embodiment, the split light is extracted to the monitor port 14 and the uplink signal waveform, the intersymbol interference light waveform, or the multiplexed light waveform is calculated. Monitor.

In each of the above-described embodiments, the optical switch 13-1 may be removed, and the intersymbol interference light may be superimposed on only one of the downstream signal and the upstream signal to constitute a one-way system margin measuring device. Comparing the loss of the main signal path of each embodiment described above, the first embodiment with one optical coupler is the smallest, the third embodiment with two optical couplers is next, and the optical coupler is 3 The second embodiment used is the largest. Therefore, in the second embodiment and the third embodiment, an input upstream signal can be monitored.

Since the circulator is expensive,
The second and third embodiments that can be handled by one circulator can be realized at low cost. However, the second embodiment is disadvantageous in cost because three optical power meters are required. In addition, instead of a circulator,
A combination of an isolator and an optical coupler can be used.

[0041]

FIG. 4 shows an embodiment of the intersymbol interference signal light source 26 used in the system margin measuring apparatus of the present invention.
The intersymbol interference signal light source shown in FIG. 4A modulates the oscillation light of the continuously oscillating semiconductor laser 31 with the external modulator 32. The external modulator 32 is driven by an electric signal square wave generator 33 and a drive circuit 34, and outputs intersymbol interference light by an external modulation method.

The intersymbol interference signal light source shown in FIG. 4 (b) modulates the injection current of a continuously oscillating semiconductor laser 31 with an electric signal rectangular wave generator 33 and a driving circuit 34, and directly modulates the intersymbol intersymbol. Outputs interference light. When the stability of the wavelength or spectrum of the intersymbol interference light is required, FIG.
The configuration of the external modulation method of (a) is suitable. The semiconductor laser 31 in this embodiment may be either a multi-longitudinal mode semiconductor laser or a single longitudinal mode semiconductor laser. In the configuration shown in FIG. 4B, an LED or the like may be used instead of the semiconductor laser.

As the waveform of the intersymbol interference light, a 100% modulated rectangular wave that can easily convert the peak power is suitable. However, it is necessary that an optical frequency irrelevant to the main signal light is arbitrarily set, and that the modulation frequency is within the receivable band of the receiver to be measured. FIG. 5 shows an embodiment for wavelength variation of the intersymbol interference signal light source 26 used in the system margin measuring apparatus of the present invention.

In the intersymbol interference signal light source shown in FIG. 5A, the temperature of the semiconductor laser 31 is controlled by the temperature control circuit 35 with respect to the semiconductor laser 31 driven by the electric signal rectangular wave generator 33 and the driving circuit 34. The oscillation wavelength is changed by controlling. The intersymbol interference signal light source shown in FIG.
A tunable semiconductor laser 36 such as a distributed Bragg reflection (DBR) semiconductor laser is used. The oscillation wavelength of the wavelength tunable semiconductor laser 36 is changed by the wavelength control circuit 37.

The intersymbol interference signal light source shown in FIG. 5C has a plurality of semiconductor lasers 31-1 and 31-2 having different oscillation wavelengths.
The output signal of the drive circuit 34 is switched by the RF switch 38, and the semiconductor laser 3 is switched by the optical switch 39.
The output light of 1-1 and 31-2 is switched.

[0046]

As described above, the system margin measuring apparatus according to the present invention provides a simple configuration for the system margin of a two-way optical communication system using one optical fiber transmission line. Can be measured independently of each other.

[Brief description of the drawings]

FIG. 1 is a block diagram showing a first embodiment of a system margin measuring apparatus according to the present invention.

FIG. 2 is a block diagram showing a second embodiment of the system margin measuring device of the present invention.

FIG. 3 is a block diagram showing a third embodiment of the system margin measuring device of the present invention.

FIG. 4 is a block diagram showing an embodiment of an intersymbol interference signal light source 26 used in the system margin measuring apparatus of the present invention.

FIG. 5 is a block diagram showing a configuration of an embodiment for changing the wavelength of the intersymbol interference signal light source 26 used in the system margin measuring apparatus of the present invention.

FIG. 6 is a block diagram showing a configuration example of a conventional system margin measuring device.

FIG. 7 is a block diagram showing a configuration when a conventional system margin measuring device is applied to a bidirectional optical communication system.

[Explanation of symbols]

 Reference Signs List 11 port 12 circulator 13 optical switch 14 monitor port 15 pulse pattern generator (PPG) 16 error rate measuring instrument (ED) 21 transmitter 22 optical fiber 23 attenuator 24 optical coupler 25 receiver 26 intersymbol interference signal light source 27 optical power Meter (PM) 31 Semiconductor laser 32 External modulator 33 Electric signal rectangular wave generator 34 Drive circuit 35 Temperature control circuit 36 Wavelength variable semiconductor laser 37 Wavelength control circuit 38 RF switch 39 Optical switch

──────────────────────────────────────────────────続 き Continuing on the front page (72) Inventor Hiroshi Miyamoto 1-14-5 Kichijoji Honcho, Musashino City, Tokyo Examiner, NTT Electronics Technology Co., Ltd. Norihiro Eguchi (56) References JP-A-5-248995 (JP, A) JP-A-55-132161 (JP, A) JP-A-5-218975 (JP, A) JP-A-2-142247 (JP, A) JP-A-60-229434 (JP, A) ( 58) Field surveyed (Int. Cl. ⁷ , DB name) H04B 17/02 H04B 10/08

Claims (5)

(57) [Claims] 1. A bidirectional optical communication system using one optical fiber transmission line, which is inserted into a transmission line, superimposes intersymbol interference light on bidirectional main signal light, and outputs the power of the intersymbol interference light. in the system margin measuring device for measuring the system margin from the degree of degradation of the bit error rate characteristic to be measured by <br/> a receiver, two optical path of which is inserted into the optical fiber transmission line, said optical fiber Before the main signal light propagating through the transmission line in each direction
Connecting means for switching to and connecting to the two optical paths , an attenuator for independently giving a loss to the bidirectional main signal light propagating through the two optical paths, and an attenuator for giving a loss to the intersymbol interference light Means for superimposing the intersymbol interference light having a predetermined loss on the bidirectional main signal light, and combining the power of the bidirectional main signal light and the power of the intersymbol interference light independently.
Monitor and monitor according to the setting of each attenuator.
Place each measured power reading at the output port of the instrument.
Means for calibrating based on actual measured values . 2. The system margin measuring apparatus according to claim 1, wherein, as means for superimposing the intersymbol interference light on the main signal light, a direction in which the intersymbol interference light is superimposed is switched to one of the bidirectional main signal lights. A system margin measuring device comprising means. 3. The system margin measuring apparatus according to claim 1, further comprising means for branching a part of the bidirectional main signal light and a part of the superimposed intersymbol interference light and monitoring the signal waveform. Characteristic system margin measuring device. 4. The system margin measuring apparatus according to claim 1, further comprising means for switching the wavelength of the intersymbol interference light to a variable or another wavelength. 5. The system margin measuring apparatus according to claim 1, wherein the intersymbol interference light uses a rectangular wave whose peak power can be easily converted, and whose optical frequency is irrelevant to the main signal light , and whose modulation frequency is
A system margin measuring device, wherein a wave number is set to an arbitrary value within a receivable band of a receiver.