JP3535310B2 - Optical transmitter for burst transmission - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical transmitter for burst transmission, and more particularly to an optical transmitter for burst transmission capable of transmitting a burst-like optical signal (that is, an optical burst transmission signal) without deteriorating the duty. The present invention relates to an optical transmitter.

[0002]

2. Description of the Related Art A conventional optical transmitter for burst transmission of this type is shown in FIG. In FIG. 11, reference numeral 1 is a semiconductor laser (LD: Laser Diode) which is an optical signal source for converting a transmission signal into an optical signal.
e) 2 is a monitor photodiode (PD: Photo) for photoelectrically converting and monitoring a transmission signal as an optical signal
Diode), 3 is a preamplifier circuit for converting a current signal (that is, monitor signal 2a) photoelectrically converted by the monitor photodiode 2 into a voltage signal (that is, current-voltage conversion), 4 is a semiconductor laser 1 drive The LD driver circuit 5 for performing the conversion of the transmission signal into the optical signal is a duty adjusting circuit 5 for controlling the signal duty when converting the transmission signal into the optical signal.

In recent years, interest in optical burst transmission is increasing, but in order to realize an optical transmitter for burst transmission at low cost, it is important to operate without adjustment in any environment. However, on the principle of laser oscillation, the semiconductor laser 1 requires a finite oscillation delay time after the current is applied and before the applied current exceeds the threshold value and laser oscillation is started. Therefore, in the pulse response characteristic of the semiconductor laser 1, a constant delay time occurs between the rising edge of the applied pulse and the rising edge of the light emission pulse in response to this. Further, even if the duty adjusting means is used to adjust the duty to 100% with respect to one operating environment (specifically, temperature) of the semiconductor laser 1, the threshold current changes due to a change in the operating environment. However, if the oscillation delay time changes as a result, the duty of the optical transmission waveform becomes 10
It was off from 0%.

When an optical signal is transmitted using such a semiconductor laser 1, the LD driver circuit 4 has a duty of 1
Even if the waveform of 00% is input, the duty of the optical output signal of the semiconductor laser 1 is 1 depending on the delay time of the semiconductor laser 1.
It becomes smaller than 00%, and so-called duty deterioration occurs. When such duty deterioration occurs in the optical output signal, as shown in FIG. 12, the eye pattern of the transmission signal received by the receiving device (not shown) is crushed, and as a result, the code error rate characteristic in burst transmission is increased. Will deteriorate.

Therefore, in the conventional optical transmitter 9 for burst transmission, the duty adjustment circuit 5 preliminarily increases the duty of the input waveform of the LD driver circuit 4 by an amount corresponding to the delay time to compensate the duty of the optical output signal. I was going. Further, in the duty adjusting circuit 5, the delay time compensation amount is fixed after performing the delay amount compensation amount for a certain operating environment during the initial adjustment.

By providing such a duty adjusting circuit 5, the duty of the optical output signal is brought close to 100%, and the adverse effect on the receiving device (not shown) is reduced. Specifically, when the threshold current of the semiconductor laser 1 increases as the operating temperature of the semiconductor laser 1 increases, the oscillation delay time increases, so the duty of the optical output signal (that is, the transmission signal) decreases. Also semiconductor laser 1
When the operating temperature is low, the oscillation delay time of the semiconductor laser 1 is short, and thus the duty of the optical output signal is high. However, in either case, the received eye pattern is crushed and the bit error rate characteristic deteriorates, resulting in a decrease in the minimum reception level of the receiving device (not shown).

In burst transmission, since the transmission signal is a packet-like signal having a different level for each packet, it is necessary to set the identification level based only on the amplitude information, and the duty deterioration caused in the transmitter is caused. Cannot be corrected. Further, the received transmission signal becomes a transmission signal having a remarkably poor duty due to the duty deterioration of the receiving device (not shown) in addition to the duty deterioration of the transmitted transmission signal. Therefore, in the optical transmitter for burst transmission used in burst transmission, it is necessary to output an optical burst transmission signal that does not deteriorate in duty regardless of the operating temperature.

[0008]

However, in such a conventional optical transmitter 9 for burst transmission, although the oscillation delay time changes due to changes in the operating temperature of the semiconductor laser 1 and changes over time, etc. Since the delay time compensation amount is fixed after performing the delay amount compensation amount during the initial adjustment of the duty adjustment circuit 5, it is difficult to sufficiently compensate the duty deterioration of the optical output signal, and as a result, the semiconductor There has been a problem that it is difficult to sufficiently prevent the deterioration of the code error rate characteristic due to the fluctuation of the operating temperature of the laser 1.

The present invention has been made by paying attention to such a conventional problem, and a duty generated according to a duty deterioration amount of an output signal (that is, a monitored transmission signal) monitored by a monitor photodiode. An object of the present invention is to provide an optical transmitter for burst transmission capable of preventing duty deterioration of an output signal (that is, a transmission signal) by correcting the duty adjustment by feeding back a duty of a control signal to a duty adjustment circuit. I am trying.

[0010]

The optical transmission signal in the burst transmission optical transmission device (10) according to claim 1, is a dummy pulse train signal arranged at the head portion of the transmission signal, and a dummy pulse train signal, followed by the dummy pulse train signal. And the arranged data signal. The feedback loop is
It comprises a sample hold circuit (30) and a high-speed duty fluctuation detection circuit (20). When monitoring the dummy pulse train signal, the sample hold circuit (30) outputs a duty control signal (20a) for the dummy pulse train signal to the duty adjusting circuit (40) to perform duty correction on the dummy pulse train signal, When the data signal is transmitted, a duty control signal (20a) for the dummy pulse train signal is held according to the hold control signal (17), and the held duty control signal (20a) is output to the duty adjusting circuit (40). Then, the duty correction is executed for the data signal following the dummy pulse train signal. A high-speed duty fluctuation detection circuit (20) detects the duty deterioration amount with respect to the dummy pulse train signal when monitoring the dummy pulse train signal and detects the duty control signal (20).
a) is generated.

By providing such a high-speed duty fluctuation detection circuit (20) and monitoring the duty of the optical waveform and applying feedback, a dummy pulse train signal including the LD driver circuit (15) to the semiconductor laser (11) is generated. The duty fluctuation can be canceled to make the duty of the output waveform almost 100%.
Further, by holding the duty control signal at the time when the dummy pulse train signal is input by using the sample hold circuit (30), the data control signal following it is also based on the duty control signal (20a) set by the dummy pulse train signal. The output duty can be set to almost 100
% Duty correction can be executed. In addition, since the optimum point for duty adjustment is obtained for each packet, it is unlikely to be affected by changes in conditions, and it is possible to realize a very reliable optical transmission device (10) for burst transmission.

According to another aspect of the optical transmitter (10) for burst transmission, the mark ratio of the dummy pulse train signal is 1/2. When such a dummy pulse train signal having a mark ratio of 1/2 is used, the duty becomes 100% by controlling the average value of the dummy pulse train signal, that is, the low frequency component to be at the center of the amplitude. Feedback becomes easier and the output duty is further increased to 100.
It is possible to execute duty correction to bring it closer to%.

An optical transmitter for burst transmission (10) according to a third aspect is the optical transmitter for burst transmission according to the first or second aspect. The high-speed duty fluctuation detection circuit (20) detects the low-frequency component of the transmitted dummy pulse train signal and compares the low-frequency component to generate the duty control signal (20a), thereby detecting the duty deterioration amount. is there.

By providing such a high-speed duty fluctuation detection circuit (20), monitoring the duty of the optical waveform and applying feedback, the duty of the output waveform of the dummy pulse train signal can be adjusted to almost 100%. Further, by providing the duty control signal (20a), the system can be stabilized at a level where the duty becomes 100% by the time the dummy pulse train signal ends.
Then, at a certain point in time until the dummy pulse train signal ends, it becomes possible to receive the hold control signal 17 from the outside and hold the duty control signal (20a) at that point. ), The duty control signal (20a) does not fluctuate from an appropriate value and the duty of the output waveform of the data signal can be made appropriate.

An optical transmitter for burst transmission (10) according to a fourth aspect is the optical transmitter for burst transmission (10) according to the first to third aspects. The high-speed duty fluctuation detection circuit (20) comprises an automatic threshold control circuit (22), a differential amplifier circuit (23), and a DC comparison circuit (24). The automatic threshold control circuit (22) sets a threshold level (16) at the amplitude center of the transmitted dummy pulse train signal and generates a threshold signal (22a) corresponding to the threshold level (16). The differential amplifier circuit (23) includes the transmitted dummy pulse train signal and the threshold signal (22a).
Are differentially amplified to generate a positive phase differential output signal (23a) and a negative phase differential output signal (23b). The DC comparison circuit (24) has a low frequency component (that is, an average value) of the positive phase differential output signal (23a) and the negative phase differential output signal (23b).
Of the duty control signal (2
0a) is generated.

By providing such a high-speed duty fluctuation detection circuit (20) and monitoring the duty of the optical waveform and applying feedback, the duty of the output waveform of the dummy pulse train signal can be adjusted to almost 100%. Further, by providing the duty control signal (20a), the system can be stabilized at a level where the duty becomes 100% by the time the dummy pulse train signal ends.
Then, it is possible to receive the hold control signal 17 from the outside at a certain point in time until the dummy pulse train signal ends and to hold the duty control signal (20a) at that point in time. Signal, the duty control signal (20a) does not fluctuate from an appropriate value, and the duty of the output waveform of the data signal can be made appropriate.

An optical transmitter for burst transmission (10) according to a fifth aspect is the optical transmitter for burst transmission (10) according to the fourth aspect. The automatic threshold control circuit (22) comprises a lower peak level detection circuit (22B), an upper peak level detection circuit (22A) and a voltage dividing circuit (22C). The lower peak level detection circuit (22B) detects the 1-side level of the transmitted dummy pulse train signal and generates the lower peak level signal (22B-1).

The upper peak level detection circuit (22A)
Is for detecting the 0 side level (30a) and generating the upper peak level signal (22B-2). The voltage dividing circuit (22C) generates a threshold signal (22a) for the threshold level (16) from a predetermined voltage division ratio between the lower peak level signal (22B-1) and the upper peak level signal (22B-2). It is a thing.

By using such a dummy pulse train signal, the duty can be determined based on the duty control signal (20a) set by the dummy pulse train signal even for the data signal that follows it, and the output duty is almost 100%.
The duty correction can be executed. Further, by providing the duty control signal (20a), the system can be stabilized at a level where the duty becomes 100% by the time the dummy pulse train signal ends. Then, at a certain point in time until the dummy pulse train signal ends, the hold control signal 17 is received from the outside, and the duty control signal (20
a) can be held, the duty control signal (20a) does not fluctuate from an appropriate value regardless of what kind of transmission signal (especially the data signal) is received, and the duty of the output waveform of the data signal is appropriate. Will be able to.

The optical transmitter for burst transmission (10) according to claim 6 is the optical transmitter for burst transmission according to claim 4. The automatic threshold control circuit (22) is the automatic threshold control circuit (22) according to claim 4, wherein the lower peak level detection circuit (22B), the reference level generation circuit (22D), and the voltage dividing circuit (22C). ) And. The lower peak level detection circuit (22B) generates the lower peak level signal (22B-1). The reference level generation circuit (22D) generates the reference level signal (22D-1) corresponding to the 0 side level signal (30a) when there is no signal. The voltage dividing circuit (22C) generates a threshold signal (22a) for the threshold level (16) from a predetermined voltage division ratio between the lower peak level signal (22B-1) and the reference level signal (22D-1). Is.

By providing such an automatic threshold control circuit (22), since the reference level signal (22D-1) does not completely reach the 0 side level (30a) of the transmission signal, the threshold level 16 is set. Although the error increases, the number of complicated peak detection circuits can be reduced to perform highly accurate 0-side level detection.

An optical transmitter for burst transmission (10) according to a seventh aspect is the optical transmitter for burst transmission according to the fourth aspect. The automatic threshold control circuit (22) is the automatic threshold control circuit (22) according to claim 4, wherein the lower peak level detection circuit (22B), the upper level hold circuit (22E), and the voltage dividing circuit (22C). And. The lower peak level detection circuit (22B) generates the lower peak level signal (22B-1). The upper level hold circuit (22E) holds the 0-side level signal (30a) when there is no signal at the time when the upper level hold signal (22E-2) is input. The voltage divider circuit (22C) has a lower peak level signal (2
The threshold signal (22a) relating to the threshold level (16) is generated from a predetermined voltage division ratio between 2B-1) and the level of the upper level holding signal (22E-2).

By providing such an automatic threshold control circuit (22), an upper level holding signal (22) from the outside is provided.
Although E-2) is required, the number of complicated peak detection circuits can be reduced and highly accurate 0-side level detection can be performed. An optical transmitter for burst transmission (10) according to claim 8 is the optical transmitter for burst transmission according to any one of claims 1 to 3. The high-speed duty fluctuation detection circuit (20) comprises a direct current comparison circuit (24), a reference level generation circuit (26) and a preamplification circuit (14). The preamplifier circuit (14) amplifies the transmitted dummy pulse train signal. The reference level generation circuit (26) generates a predetermined reference level signal (26a). The DC comparison circuit (24) includes a low frequency component (that is, an average value) of the amplified dummy pulse train signal and a reference level signal (2).
6a) and the duty control signal (20a)
Is generated.

By using such a dummy pulse train signal, the duty can be determined based on the duty control signal (20a) set by the dummy pulse train signal even for the data signal that follows it, and the output duty is almost 100%.
The duty correction can be executed.

The burst transmission optical transmitter (10) according to claim 9 is the burst transmission optical transmitter (10) according to any one of claims 4 to 8, wherein the automatic output adjustment circuit (5) is provided.
0) and generates a level corresponding to the reference level signal (26a) based on the amplitude level expected to be controlled by the automatic output adjustment circuit (50).

By providing such a high-speed duty fluctuation detection circuit (20), monitoring the duty of the optical waveform and applying feedback, the duty of the output waveform of the dummy pulse train signal can be adjusted to almost 100%. Further, the automatic output adjusting circuit (50) drives the semiconductor laser (11) to convert the transmission signal into an optical signal and controls the amplitude of the optical output to a constant level so that the LD drive signal (15a). The current amplitude of is controlled.

By providing such an automatic output adjusting circuit (50) in the burst transmission optical transmitter (10),
The reference level (26a) can be reliably set to the center of the monitor signal.

[0028]

BEST MODE FOR CARRYING OUT THE INVENTION First, the main structure of an embodiment of the present invention will be described. FIG. 1 is a block diagram of an optical transmitter 10 for burst transmission of the present invention. FIG. 2 is a diagram showing a data structure of a transmission signal transmitted by the optical transmitter 10 for burst transmission according to the first embodiment of the present invention.

In FIG. 1, reference numeral 11 denotes a semiconductor laser (LD: Laser Diode shown in FIG. 1) which is a light source,
Reference numeral 12 denotes a photodiode (PD: Photo Diode shown in FIG. 1) that monitors a part of the transmission signal and generates a monitored current signal having a similar relationship to the transmission signal.
e), 14 is a preamplifier circuit that converts the current signal of the monitor photodiode into a voltage, 15 is an LD driver circuit that drives the semiconductor laser 11, 40 is a duty adjustment circuit, 20 is a high-speed duty fluctuation detection circuit, and 30 is a sample. It is a hold circuit.

As shown in FIG. 1, the burst transmission optical transmitter 10 according to the embodiment of the present invention is connected to a duty adjusting circuit 40 and a duty adjusting circuit 40 for correcting the duty of a transmission signal to a predetermined duty. And a duty-cycle adjustment circuit 4
The transmission signal whose duty is corrected by 0 is converted into an optical signal for burst transmission.

As shown in FIG. 1, the feedback loop is composed of a high-speed duty fluctuation detection circuit 20 and a sample hold circuit 30, which detects the duty deterioration amount of the current signal obtained by monitoring the transmission signal with a photodiode. The duty control signal 20a for correcting the duty deterioration amount is generated, and the duty control signal 20a is output to the duty adjusting circuit 40 to execute the duty correction.

By providing such a feedback loop, it is possible to cancel the duty fluctuation of the dummy pulse train signal including the LD driver circuit 15 to the semiconductor laser 11, and moreover, the optimum point of duty adjustment for each packet in burst transmission. Therefore, it is possible to realize a highly reliable optical transmission device 10 for burst transmission that is not easily affected by fluctuations in conditions.

As shown in FIGS. 2A and 2B, the transmission signal is composed of a dummy pulse train signal arranged at the beginning of the transmission signal and a data signal arranged following the dummy pulse train signal. There is. Specifically, a dummy pulse train signal with a mark ratio of 1/2 is added to the transmission signal before the data signal. As a pattern for the dummy pulse train signal, an alternating 1,0 waveform is preferable so that the duty deterioration remarkably appears as the fluctuation of the low frequency component.

By using such a dummy pulse train signal having a mark ratio of 1/2, the duty becomes 100% if the average value of the dummy pulse, that is, the low frequency component is controlled to the center of the amplitude. As a result, feedback is facilitated, and duty correction can be executed to bring the output duty closer to 100%.

The high-speed duty fluctuation detection circuit 20 detects the duty fluctuation of the waveform of the transmission signal from the waveform of the dummy pulse of the monitor photodiode 12 at a high speed as the fluctuation of the low frequency component, and based on the fluctuation amount, outputs the duty control signal. 20a is output. By feeding back the duty control signal to the duty adjusting circuit 40, the duty can be adjusted so as to correct the duty deterioration.

As described above, the duty of the dummy pulse train signal output waveform can be adjusted to almost 100% by monitoring the duty of the optical waveform and applying the feedback. However, as it is, the response of the high-speed duty fluctuation detection circuit 20 is fast, so that the data signal is 1
When the sign of (or 0) is continuous, the duty fluctuation of the dummy pulse train signal is not detected, and the level of the duty control signal 20a is incorrect. To prevent it
The duty control signal 20a is set so that the output duty becomes appropriate with the dummy pulse train signal, and the duty control signal 20a is held by the sample hold circuit in the data signal containing the information, and the level of the duty control signal 20a is fixed at an appropriate value. is doing.

As a result, the duty of the data signal is determined based on the value of the duty control signal 20a set by the dummy pulse train signal, and the output duty is approximately 10
It can be 0%. According to the present invention, the duty variation including the LD driver circuit 15 to the semiconductor laser can be canceled, and the optimum point of the duty adjustment is obtained for each packet. It is possible to realize the optical transmitter 10 for burst transmission having high property.

Next, the configuration of the first embodiment of the present invention will be described. FIG. 3 is a block diagram of the optical transmitter 10 for burst transmission according to the first embodiment of the present invention. Figure 4
FIG. 4 is a diagram for explaining signal processing inside the burst transmission optical transmission device 10 according to the first embodiment of the present invention, and FIG. 4 (a) shows the transmission signal monitored by the monitor photodiode 12. Waveform, FIG. 4B is a waveform of the transmission signal that has been current-voltage converted by the preamplifier circuit 14, FIG.
4C shows the waveform of the threshold signal 22a generated by the automatic threshold control ATC circuit, and FIG. 4D shows the waveform of the positive phase differential output signal 23a and the negative phase differential output signal 23b generated by the differential amplifier circuit 23. Waveforms, FIG. 4E shows the low frequency level 24D− of the positive phase differential output signal 23a and the negative phase differential output signal 23b.
The waveforms of a and 24D-b are shown.

In FIG. 3, 22 is a threshold signal 22 at the center of the amplitude of the output signal of the preamplifier circuit 14 (see FIG. 4B).
Automatic threshold control for setting a (ATC: Au shown in FIG. 3
tomatic Threshold Contro
1) circuit, 23 is a differential amplifier circuit that differentially amplifies the transmission signal around the threshold signal 22a, and 24 is a differential output of the differential amplifier circuit 23 (a positive phase differential output signal 23a shown in FIG. The DC output circuit 30 compares a low frequency component (that is, an average value) of the dynamic output signal 23b), and 30 is a sample hold circuit.

The feedback loop in the optical transmitter 10 for burst transmission comprises a sample hold circuit 30 and a high speed duty fluctuation detecting circuit 20. The high-speed duty fluctuation detection circuit 20 includes an automatic threshold control circuit 22, a differential amplifier circuit 23, and a direct current comparison circuit 24. When the dummy pulse train signal is monitored, the duty deterioration amount for the dummy pulse train signal is detected to detect the duty deterioration. The control signal 20a is generated. Specifically, the duty fluctuation of the transmission signal can be detected as the fluctuation of the average value (low frequency component).

As shown in FIG. 4C, the automatic threshold control circuit 22 sets the threshold level 16 at the center of the amplitude of the transmitted dummy pulse train signal and generates the threshold signal 22a corresponding to the threshold level 16. Is. Differential amplifier circuit 23
4D, the dummy pulse train signal and the threshold signal 22a that have been transmitted are differentially amplified to generate a positive phase differential output signal 23a and a negative phase differential output signal 23b, as shown in FIG. 4D.

As shown in FIG. 4E, the DC comparison circuit 24 compares the low frequency component of the positive phase differential output signal 23a with the low frequency component of the negative phase differential output signal 23b and outputs the duty control signal 20a. To generate. By providing such a high-speed duty fluctuation detection circuit 20 and monitoring the duty of the optical waveform and applying feedback, the duty of the output waveform of the dummy pulse train signal is approximately 100.
% Can be adjusted. By providing such a duty control signal 20a, the system can be stabilized at a level where the duty becomes 100% by the time the dummy pulse train signal ends. Then, at a certain time until the dummy pulse train signal ends, the hold control signal 17 is externally supplied.
It is possible to hold the duty control signal 20a at that point in time and output the data signal without changing the duty control signal 20a from the proper value regardless of what kind of transmission signal, particularly the data signal, is received. The duty of the waveform can be made appropriate.

The transmission signal of the preamplifier circuit 14 is differentially amplified by the differential amplifier circuit 23 around the threshold signal 22a set by the automatic threshold control circuit 22. As a result, at the output of the differential amplifier circuit 23, a differential signal having the same duty as the input signal of the preamplifier circuit 14, that is, the output waveform of the semiconductor laser 11 can be obtained.

The low-frequency component of the differential signal, that is, the average value (low-frequency component) has the same level when the duty of the transmission signal is 100%, but a level difference occurs as the duty deteriorates. This level difference can be compared by the DC comparison circuit 24 having an appropriate gain and taken out as the duty control signal 20a.

The sample hold circuit 30 outputs the dummy pulse train signal when it outputs the duty control signal 24a.
Is output to the duty adjustment circuit 40 to perform duty correction on the dummy pulse train signal, and when the data signal is burst-transmitted, the duty control signal 24a for the dummy pulse train signal is generated according to the hold control signal 17. It holds and outputs the held duty control signal 20a to the duty adjusting circuit 40 to execute the duty correction on the data signal following the dummy pulse train signal.

The duty control signal 20a is fed back to the duty adjusting circuit 40. Since the feedback loop is designed so that the time constant is sufficiently fast, the duty is 100% by the end of the dummy pulse train signal.
At that level, the system stabilizes. Then, at a certain time until the dummy pulse train signal ends, the hold control signal 17 is received from the outside, and the duty control signal 2 at that time is received.
Hold 0a. The duty control signal 20a does not fluctuate from an appropriate value regardless of what kind of transmission signal (especially the data signal) is received, and as a result, the duty of the output waveform of the data signal can be made appropriate.

Next, the DC comparison circuit 24 used in the first embodiment of the invention will be described with reference to FIG. Figure 5
5A is a circuit diagram showing a first embodiment of a DC comparison circuit 24 of the present invention, and FIG. 5B is a circuit diagram showing a second embodiment of the DC comparison circuit 24 of the present invention. Yes, Figure 5
5C is a circuit diagram showing a third embodiment of the DC comparison circuit 24 of the present invention, and FIG. 5D is a diagram showing frequency characteristics of the DC comparison circuit 24.

As shown in FIG. 5A, the DC comparison circuit 24 comprises a comparison circuit 24A having a sufficient gain and a low pass filter 24D connected to its differential input. The low-pass filter 24D includes resistors 24B-1 and 24B-2 connected to the differential inputs of the comparison circuit 24A, and a capacitor 24C-1 connected between the differential inputs.

The low pass filter 24D shown in FIG. 5 (b).
Are resistors 2 connected to the differential inputs of the comparison circuit 24A.
4B-4, 24B-5, and capacitors 24C-2, 24 respectively connected between each differential input and ground
It is composed of C-3.

The low pass filter 24D shown in FIG. 5 (c).
Are resistors 2 connected to the differential inputs of the comparison circuit 24A.
4B-1, 24B-2, and a capacitor 24C-1 connected between the differential inputs. Further, by connecting a resistor 24B-3 and a capacitor 24C-4 to the output of the comparison circuit 24A, a circuit configuration is obtained in which a predetermined characteristic is obtained. The input of the comparison circuit 24A is as shown in FIG.
The same resistance and capacitor as the DC comparison circuit 24 shown in (b) are connected, and the DC comparison circuit 2 shown in FIG.
Of course, it is also possible to connect a resistor and a capacitor similar to those in 4.

An example of frequency characteristics of the DC comparison circuit 24 is shown in FIG.
It shows in (d). First, the DC gain of the comparison circuit 24A is 20.
Take a large value of about 60 dB. Further, the time constant is shortened so that the dummy pulse train signal responds to the continuous period. Specifically, the bit rate of the transmission signal is set to A [bp
s], the base frequency of the 1,0 alternating waveform is approximately A / 2 [Hz], so the dummy pulse train signal B [b
If it is desired to respond and hold within [it], the time constant of the DC comparison circuit 24 may be set so that the gain becomes 0 dB at the frequency A / 2B [Hz]. Actually, the frequency at which the gain is 0 dB is set to A according to the speed of response.
It may be designed to be 3 to 1/3 times the / 2B [Hz].

Next, the automatic threshold control circuit 22 used in the first embodiment of the invention will be described with reference to FIG. FIG. 6 (a) is a circuit diagram showing a first embodiment of an automatic threshold control ATC circuit of the present invention, and FIG. 6 (b) shows a second embodiment of the automatic threshold control ATC circuit of the present invention. FIG. 6C is a circuit diagram shown, and FIG. 6C is a circuit diagram showing a third embodiment of an automatic threshold control ATC circuit of the present invention.

In FIG. 6A, 22A is an upper peak level detection circuit, 22B is a lower peak level detection circuit,
22C is a voltage dividing circuit. The automatic threshold control circuit 22 includes a lower peak level detection circuit 22B, an upper peak level detection circuit 22A, and a voltage dividing circuit 22C.

The lower peak level detection circuit 22B detects the 1-side level of the transmitted dummy pulse train signal and generates the lower peak level signal 22B-1. The upper peak level detection circuit 22A detects the 0 side level and generates an upper peak level signal 22B-2.

The voltage dividing circuit 22C generates the threshold signal 22a from a predetermined voltage division ratio between the lower peak level signal 22B-1 and the upper peak level signal 22B-2. The upper peak level detection circuit 22A and the lower peak level detection circuit 22B detect the upper (ie, 0 side) and lower (ie, 1 side) peak levels of the input signal, and the lower peak level signal 22B-1. And the upper peak level signal 22B-2
And are input to the voltage dividing circuit 22C. As a result, voltage dividing circuit 22C
Then, the intermediate level is obtained to set the threshold level signal 22a at the center of the amplitude.

The automatic threshold control circuit 22 shown in FIG.
Comprises a lower peak level detection circuit 22B, a reference level generation circuit 22D and a voltage dividing circuit 22C. The lower peak level detection circuit 22B has a lower peak level signal 22
B-1 is generated.

The reference level generation circuit 22D is a reference level signal 22D corresponding to the 0 side level signal 30a when there is no signal.
-1 is generated. The voltage dividing circuit 22C includes a lower peak level signal 22B-1 and a reference level signal 22D-1.
The threshold signal 22a is generated from a predetermined voltage division ratio of

As in FIG. 6A, the lower peak level detection circuit 22B22B detects the lower peak level of the input signal (that is, the first side), and the lower peak level signal 22B-
1 and the reference level signal 22D-1 are input to the voltage dividing circuit 22C. For the reference level generating circuit 22D, for example, a dummy preamplifier circuit having the same structure as the preamplifier circuit 14 used is used. With such a configuration, the reference level signal 22D-1 does not completely reach the 0 side level of the transmission signal, so the error of the threshold level 22a increases, but the number of complicated peak detection circuits is reduced. It is possible to detect the 0-side level with high accuracy.

The automatic threshold control circuit 22 shown in FIG. 6 (c).
Comprises a lower peak level detection circuit 22B, an upper level hold circuit 22E and a voltage dividing circuit 22C. The lower peak level detection circuit 22B is for generating the lower peak level signal 22B-1.

The sample and hold circuit 30 holds the 0-side level signal 22E-1 when there is no signal in response to the upper level holding signal 22E-2 input from the outside. The voltage dividing circuit 22C has a lower peak level signal 22B-
The threshold signal 22a is generated from a predetermined voltage division ratio between 1 and the level of the upper hold level signal 22E-2.

As in FIG. 6A, the lower peak level detection circuit 22B detects the lower (ie, 1) peak level of the input signal, and the lower peak level signal 22B-1 and the upper side when there is no signal. The upper level hold signal 22E-2 held by the level hold circuit 22E is input to the voltage dividing circuit 22C. In this case, the external upper level holding signal 22E-
Although 2 is required, the number of complex peak detection circuits can be reduced.

Next, the duty adjusting circuit 40 used in the first embodiment of the invention will be described with reference to FIGS. 7 and 8. FIG. 7 is a circuit diagram illustrating an embodiment of the duty adjusting circuit 40 of the present invention. FIG. 8 is a diagram for explaining the signal processing inside the duty adjustment circuit 40 of the present invention. FIG. 8A is a waveform of an input transmission signal, and FIG.
8B shows the waveform of the duty control signal 20a and the waveform of the LPF signal 41a processed by the low pass filter, FIG.
8C and FIG. 8D show the waveform of the duty control signal 42a that has been differentially amplified by the differential amplifier circuit 23.

In FIG. 7, reference numeral 41 is a low pass filter (LPF), and 42 is a differential amplifier circuit. The input signal (dummy pulse train signal shown in FIG. 8A) is passed through the low-pass filter 41 and the rising and falling edges of the LPF are smoothed.
The signal 41a is differentially amplified around the duty control signal 22a. When the duty control signal 22a is high, the duty of the duty control signal 42a generated by the differential amplifier circuit 42 becomes small (see FIGS. 8B and 8C),
When it is low, the duty of the duty control signal 42a becomes large (see FIGS. 8B and 8D). Thus, the duty of the output waveform can be changed by changing the voltage of the duty control signal 22a.

Next, a second embodiment of the present invention will be described with reference to FIG. FIG. 9 is a block diagram of an optical transmitter 10 for burst transmission according to the second embodiment of the present invention. The first embodiment of the present invention shows an example in which the output of the monitor photodiode 12 is converted into a differential signal (that is, a positive phase differential output signal 23a and a negative phase differential output signal 23b). In the above embodiment, the single-ended output can be used as it is, and the low frequency components can be compared with each other to obtain the circumferential effect.

In FIG. 9, reference numeral 26 is a reference level generation circuit, 24 is a DC comparison circuit for comparing the low frequency component of the output of the amplification circuit 26 with the reference level 26a, and 30 is a sample hold circuit. The direct-current comparison circuit 24, the amplification circuit 25, and the reference level generation circuit 26 constitute the high-speed duty fluctuation detection circuit 20.

The point that the monitored current signal amplified by the DC comparison circuit 24 and the reference level signal 26a designed so that the average level of the monitored transmission signal (current signal) are equal are compared. This is different from the case of the one embodiment. The other points are similar to those of the first embodiment.

In such a configuration, it is difficult to match the reference level signal 26a with the average of the monitored current signals under all conditions, and as a result, the accuracy of feedback is reduced, but the number of components is reduced. It is possible to greatly simplify the circuit.

Next, a third embodiment of the present invention will be described with reference to FIG. FIG. 10 is a block diagram of an optical transmitter 10 for burst transmission according to a third embodiment of the present invention. In FIG. 10, reference numeral 26 is a reference level generation circuit, 24 is a direct current comparison circuit that compares the low frequency component of the output of the amplification circuit 25 with the reference level 26a, 30 is a sample hold circuit, and 50 is automatic output control (APC:
It is an Auto Power Control circuit.
The direct-current comparison circuit 24, the amplification circuit 25, and the reference level generation circuit 26 constitute the high-speed duty fluctuation detection circuit 20. The reference level generating circuit 26 and the automatic output adjusting circuit 50 have the same APC reference level signal 50.
Control is performed based on a.

The third embodiment differs from the first embodiment in that the APC control lube is included. The other points are similar to those of the first embodiment.
The automatic output adjustment circuit 50 controls the current value of the LD drive signal 15a for driving the semiconductor laser 11 and controlling the amplitude of the optical output at a constant level in order to convert the transmission signal into an optical signal. It is a thing.

Since the output amplitude of the semiconductor laser 11 is controlled to a certain level by the automatic output adjusting circuit 50,
The final amplitude level of the monitored current signal (that is, the transmission signal), which is the output of the preamplifier circuit 14, and its central level are known. Therefore, the reference level generation circuit 26 is designed so that the central level and the reference level 26a match.

Since the automatic output adjusting circuit 50 controls based on the APC reference level signal 50a, it is easy to generate the reference level 26a based on the APC reference level signal 50a. In the third embodiment, since there are two feedback loops for duty control and output control, there is a problem that the design of the time constant becomes difficult. However, unlike the embodiment of FIG. 9, the reference level 26a is different. Can be reliably set in the center of the monitored transmission signal.

[0072]

According to the optical transmitter for burst transmission of the first aspect, the duty fluctuation of the dummy pulse train signal including the LD driver circuit to the semiconductor laser can be canceled and the duty adjustment is performed for each packet. Since the optimum point is determined, the optical transmission device for burst transmission can be realized which is not easily affected by fluctuations in conditions and is highly reliable. Further, by using the dummy pulse train signal, the duty can be determined based on the duty control signal set by the dummy pulse train signal even in the data signal that follows, and the duty correction can be executed so that the output duty is almost 100%.

According to the optical transmitter for burst transmission of the second aspect, by using the dummy pulse train signal having the mark ratio of 1/2, the average value of the dummy pulses, that is, the low frequency component becomes the center of the amplitude. If the control is performed in this manner, the duty becomes 100%, feedback is facilitated, and duty correction can be executed to bring the output duty closer to 100%.

According to the optical transmitter for burst transmission of the third aspect, by providing the duty control signal, the system can be stabilized at a level where the duty becomes 100% by the time the dummy pulse train signal ends. Then, at a certain time until the dummy pulse train signal ends, it becomes possible to receive a hold control signal from the outside and hold the duty control signal at that time, regardless of any transmission signal, especially a data signal, It is possible to make the duty of the output waveform of the data signal proper without changing the duty control signal from the proper value.

According to the optical transmitter for burst transmission of the fourth aspect, by providing the duty control signal, the system can be stabilized at a level where the duty becomes 100% by the time the dummy pulse train signal ends. Then, at a certain time until the dummy pulse train signal ends, it becomes possible to receive a hold control signal from the outside and hold the duty control signal at that time, regardless of any transmission signal, especially a data signal, It is possible to make the duty of the output waveform of the data signal proper without changing the duty control signal from the proper value.

According to the optical transmitter for burst transmission of the fifth aspect, by using the dummy pulse train signal,
For the data signal that follows this, the duty can be determined based on the duty control signal set by the dummy pulse train signal, and the duty correction can be executed so that the output duty is almost 100%. Further, by providing the duty control signal, the system can be stabilized at a level where the duty becomes 100% by the time the dummy pulse train signal ends. Then, at some point until the dummy pulse train signal ends,
It is possible to receive a hold control signal from the outside and hold the duty control signal at that time, and the duty control signal does not fluctuate from an appropriate value regardless of what kind of transmission signal (especially data signal) is received. The duty of the output waveform of the data signal can be made appropriate.

According to the optical transmitter for burst transmission of the sixth aspect, by using the reference level signal, the reference level signal does not completely reach the 0 side level of the transmission signal. Although the error increases, the number of complicated peak detection circuits can be reduced to perform highly accurate 0-side level detection.

According to the optical transmitter for burst transmission of the seventh aspect, by using the reference level signal, an upper level holding signal from the outside is required, but the number of complicated peak detecting circuits is reduced. It is possible to detect the 0-side level with high accuracy. According to the optical transmitter for burst transmission of claim 8, by using the dummy pulse train signal, the duty can be determined based on the duty control signal set by the dummy pulse train signal even for the data signal that follows the dummy pulse train signal. The duty correction can be executed so that the duty is almost 100%. Further, by using the reference level generating circuit instead of the ATC circuit and the differential amplifier circuit, the circuit configuration can be further simplified.

According to the optical transmitter for burst transmission of the ninth aspect, by providing the automatic output adjusting circuit in the optical transmitter for burst transmission, the reference level can be reliably set at the center of the monitor signal. Like

[Brief description of drawings]

FIG. 1 is a block diagram of an optical transmitter for burst transmission according to the present invention.

FIG. 2 is a diagram showing a data structure of a transmission signal transmitted by the burst transmission optical transmission device according to the embodiment of the present invention.

FIG. 3 is a block diagram of an optical transmitter for burst transmission according to the first embodiment of the present invention.

FIG. 4 is a diagram for explaining signal processing inside the burst transmission optical transmission device according to the first embodiment of the present invention;
11A is a waveform of a transmission signal monitored by a monitor photodiode (PD), FIG. 11B is a waveform of a transmission signal subjected to current-voltage conversion by a preamplifier circuit, and FIG. ) Is the waveform of the threshold signal generated by the automatic threshold control (ATC) circuit, and FIG. 7D is the waveform of the positive-phase differential output signal and the waveform of the negative-phase differential output signal generated by the differential amplifier circuit. (E) shows low-frequency level waveforms of the positive-phase differential output signal and the negative-phase differential output signal.

5A is a circuit diagram showing a first embodiment of a DC comparison circuit of the present invention, and FIG. 5B is a circuit diagram showing a second embodiment of the DC comparison circuit of the present invention. FIG. 4C is a circuit diagram showing the same, FIG. 6C is a circuit diagram showing a third embodiment of the DC comparison circuit of the present invention, and FIG. 7D is a diagram showing frequency characteristics of the DC comparison circuit.

FIG. 6A is an automatic threshold control (ATC) according to the present invention.
It is a circuit diagram showing a first embodiment of the circuit, the same figure (b) is a circuit diagram showing a second embodiment of the automatic threshold control (ATC) circuit of the present invention, the same figure (c). FIG. 6 is a circuit diagram showing a third embodiment of an automatic threshold control (ATC) circuit of the present invention.

FIG. 7 is a circuit diagram illustrating an embodiment of a duty adjustment circuit of the present invention.

8A and 8B are diagrams for explaining signal processing in the duty adjustment circuit of the present invention. FIG. 8A is a waveform of an input transmission signal, and FIG. 8B is a waveform of a duty control signal and a low frequency band. The waveform of the LPF signal processed by the pass filter, and FIGS. 7C and 7D show the waveform of the LD drive signal differentially amplified by the differential amplifier circuit.

FIG. 9 is a block diagram of an optical transmitter for burst transmission according to a second embodiment of the present invention.

FIG. 10 is a block diagram of an optical transmitter for burst transmission according to a third embodiment of the present invention.

FIG. 11 is a block diagram of a conventional burst transmission optical transmission device.

FIG. 12 is an eye pattern of a transmission signal transmitted by the conventional burst transmission optical transmission device.

[Explanation of symbols]

10 Optical Transmitter for Burst Transmission 11 Semiconductor Laser (LD) 12 Monitor Photodiode (PD) 14 Preamplifier Circuit 15 LD Driver Circuit 16 Threshold Level 20 High Speed Duty Variation Detection Circuit 22 Automatic Threshold Control (ATC) Circuit 22A Upper Peak Level Detection circuit 22B Lower side peak level detection circuit 22C Voltage division circuit 22D Reference level generation circuit 23 Differential amplification circuit 24 DC comparison circuit 24A Comparison circuit 24B-1, 24B-2, 24B-3, 24B-4, 2
4B-5 Resistors 24C-1, 24C-2, 24C-3, 24C-4 Capacitor 24D Low pass filter 25 Amplifying circuit 26 Reference level generating circuit 30 Sample hold circuit 40 Duty adjusting circuit 41 Low pass filter 42 Differential amplifying Circuit 50 Automatic output adjustment (APC) circuit

─────────────────────────────────────────────────── ─── Continuation of the front page (56) References JP-A-7-273388 (JP, A) JP-A 64-39839 (JP, A) JP-A 62-200929 (JP, A) (58) Field (Int.Cl. ⁷ , DB name) H04B 10/00-10/28 H04J 14/00-14/08

Claims (9)

(57) [Claims] Claim: What is claimed is: 1. An input transmission signal is fed to a predetermined feed bar.
Duty adjustment circuit with clock loop
Correction and execute the duty-corrected transmission signal
Optical transmission equipment for burst transmission that converts the signal
In location, the transmission signal, which has been composed of a dummy pulse train signal and said dummy pulse train signal to the subsequently arranged data signals arranged in the head portion, the feedback loop, the dummy pulse train signal when it is transmitted, du detects the duty deterioration amount with respect to the dummy pulse train signal
And fast duty change detection circuit that generates a Ti control signal, when the dummy pulse train signal is transmitted, the duty correction with respect to the dummy pulse train signal and outputs the duty control signal to the dummy pulse train signal to the duty adjustment circuit Is executed and
Input from outside until the end of the pulse train signal
The duty control signal is held according to the hold control signal, and is held when the data signal is transmitted.
And a sample hold circuit for outputting the duty control signal to the duty adjusting circuit to perform duty correction on the data signal . 2. The mark ratio of the dummy pulse train signal is 1 /
The optical transmission device for burst transmission according to claim 1, wherein the optical transmission device is 2. 3. The high-speed duty fluctuation detection circuit detects a low frequency component of the transmitted dummy pulse train signal, compares the low frequency components, and generates the duty control signal.
The optical transmitter for burst transmission according to claim 1 or 2, wherein the duty deterioration amount is detected. 4. The automatic threshold control circuit, wherein the high-speed duty fluctuation detection circuit sets a threshold level at the amplitude center of the transmitted dummy pulse train signal and generates a threshold signal according to the threshold level. A differential amplifier circuit that differentially amplifies the dummy pulse train signal and the threshold signal to generate a positive-phase differential output signal and a negative-phase differential output signal, a low-frequency component of the positive-phase differential output signal, and the negative-phase difference 4. The burst transmission optical transmitter according to claim 1, further comprising: a DC comparison circuit that compares the low frequency component of the dynamic output signal to generate the duty control signal. 5. The automatic threshold control circuit according to claim 4, wherein a lower peak level detection circuit for detecting a 1-side level of the transmitted dummy pulse train signal and generating a lower peak level signal, and a 0 side. An upper peak level detection circuit that detects a level and generates an upper peak level signal, and a voltage dividing circuit that generates a threshold signal applied to a threshold level from a predetermined voltage division ratio between the lower peak level signal and the upper peak level signal, An optical transmitter for burst transmission, comprising: 6. The automatic threshold control circuit according to claim 4,
The lower peak level detection circuit for generating the lower peak level signal, the reference level generation circuit for generating the reference level signal corresponding to the 0 side level signal when there is no signal, and the lower peak level signal. An optical transmitter for burst transmission, comprising: a voltage dividing circuit that generates the threshold value signal from a predetermined voltage dividing ratio with the reference level signal. 7. The automatic threshold control circuit according to claim 4,
The lower peak level detection circuit that generates the lower peak level signal, the upper hold circuit that holds the 0-side level signal when there is no signal according to the upper level hold signal, the lower peak level signal, and the upper hold An optical transmitter for burst transmission, comprising: a voltage dividing circuit that generates the threshold value signal from a predetermined voltage dividing ratio with respect to the signal level of the level. 8. The high-speed duty change detection circuit includes a preamplifier circuit for amplifying the transmitted dummy pulse train signal, a reference level generation circuit for generating a predetermined reference level signal, and an amplified dummy pulse train signal. 4. The burst transmission optical transmitter according to claim 1, further comprising: a DC comparison circuit that compares the low-frequency component of 1) with a reference level signal to generate the duty control signal. . 9. An automatic output adjusting circuit for controlling a current value of an LD drive signal for driving a semiconductor laser and controlling an amplitude of its optical output to a constant level in order to convert a transmission signal into an optical signal. 9. The burst transmission optical transmission according to claim 4, wherein the reference level signal is generated based on an amplitude level expected to be controlled by the automatic output adjustment circuit. apparatus.