JP2014022871A - Optical transmitter - Google Patents

Abstract

PROBLEM TO BE SOLVED: To obtain an optical transmitter which converges extinction curves of a bias control voltage during optimization of modulation signal gain control into a peak point in a short time with high accuracy.SOLUTION: In a control unit 16, a bias control voltage to be applied to a DQPSK modulator 14 is roughly adjusted so that the optical intensity of a DQPSK optical signal monitored by an optical detection unit 15 becomes maximum, and further the bias control voltage to be applied to the DQPSK modulator 14 is fine-adjusted by keeping only modulation signal output from an Ich driver 12 or a Qch driver 13 whichever is to be adjusted alive, so that the peak value of a high frequency signal superposed on the DQPSK optical signal monitored by the optical detection unit 15 becomes minimum, while a gain control signal for the driver to be adjusted is adjusted. Thus, by making adjustment separately for rough adjustment and fine adjustment, the extinction curves of the bias control voltage during the optimization of modulation signal gain control can be converged into a peak point in a short time with high accuracy.

Description

  The present invention relates to an optical transmitter mounted on an optical transceiver device.

As communication traffic increases, the introduction of 40 Gbps optical transceivers is being studied.
In an optical communication system, attention is paid to a differential quadrature phase-shift keying (DQPSK) in which 2-bit information is placed on four phase differences.

  The following Patent Document 1 discloses an Ich driver that amplifies an Ich (real part: In-phase channel) signal and outputs an Ich modulated signal, and a Qch (imaginary part: Quadrature-phase channel) signal that is amplified and Qch modulated signal. A Qch driver that outputs a DQPSK modulator that outputs an Ich modulation signal and a DQPSK optical signal corresponding to the Qch modulation signal, a light detection unit that detects the light intensity of the DQPSK optical signal output from the DQPSK modulator, Based on the light intensity detected by the detector, the Ich bias control voltage and Qch bias control voltage applied to the DQPSK modulator are adjusted, and the Ich gain control signal and Qch gain control signal output to the Ich driver and Qch driver are adjusted. An optical transmitter having a control circuit for adjustment is disclosed.

When optimizing the modulator bias control, a low-frequency dither signal is superimposed on the Ich and Qch control voltages, and an optical signal output from the DQPSK modulator based on the light intensity detected by the light detection unit Feedback control is performed so that the dither error signal is minimized.
As a result, the bias control voltages of Ich and Qch are controlled so as to be the null (NULL) point of the extinction curve of the DQPSK modulator, and the modulation degree is set to less than 100% so that there is no optical loss in this state, and DQPSK Ensure the linearity of the modulator.

Further, when optimizing the modulation signal gain control, the Qch modulation signal and the Qch low-frequency dither signal to the DQPSK modulator are cut off, the optimum value of the modulation degree of the DQPSK modulator is obtained, and the light detection unit Based on the detected light intensity, the output amplitude of the Ich driver is adjusted so that the modulation degree of the DQPSK modulator becomes the optimum value obtained.
Further, the Ich modulation signal and the Ich low frequency dither signal to the DQPSK modulator are cut off, and the modulation degree of the DQPSK modulator becomes the above obtained optimum value based on the light intensity detected by the light detection unit. The output amplitude of the Qch driver is adjusted.
The signal levels of Ich and Qch are matched by matching the modulation degrees of both to the optimum value.

JP 2011-232553 A

Since the conventional optical transmitter is configured as described above, it has the following problems.
In the above Patent Document 1, when the modulator bias control is optimized, the bias control voltage is controlled to be the null point of the extinction curve of the DQPSK modulator as shown in FIG. The degree of modulation is set to less than 100 percent so that there is no noise.

However, in order to accurately adjust the modulation factor when optimizing the modulation signal gain control, the bias control voltage is not the null point of the extinction curve of the DQPSK modulator as shown in FIG. Thus, it is necessary to converge to the peak (PEAK) point of the extinction curve of the DQPSK modulator.
This is because if the modulation signal gain control is optimized at the null point, the low (LOW) level of the amplitude of the modulation signal time waveform is buried in noise, and the amplitude cannot be measured accurately.

  However, when the bias control voltage is converged to the peak point of the extinction curve, it takes a very long time to adjust due to interference between the bias control voltage and the gain control signal, and there is a problem that the adjustment cannot be performed with high accuracy. .

Here, interference between the bias control voltage and the gain control signal will be described.
Since the bias control voltage and the gain control signal together affect the output light intensity of the DQPSK modulator, it is difficult to control the bias control voltage and the gain control signal completely independently.
For example, even if the bias control voltage is adjusted and the output light intensity of the DQPSK modulator is once controlled to be maximized, the DQPSK modulation is performed when the gain control signal is changed by adjusting the gain control signal. The output light intensity of the instrument deviates from the maximum.
Such a phenomenon is called interference between the bias control voltage and the gain control signal.

  An object of the present invention is to obtain an optical transmitter that performs convergence of a bias control voltage to a peak point of an extinction curve in a short time and with high accuracy when optimizing modulation signal gain control.

  In the optical transmitter of the present invention, the control unit applies the bias control voltage applied to the differential quaternary phase modulator so that the light intensity of the differential quaternary phase modulated optical signal monitored by the photodetection unit is maximized. The bias control voltage applied to the differential quaternary phase modulator is monitored by the photodetection unit, using only the modulation signal output from the driver to be adjusted among the in-phase component driver and the quadrature component driver. Fine adjustment is performed so that the peak value of the high-frequency signal superimposed on the differential quaternary phase modulated optical signal is minimized, and the gain control signal for the driver to be adjusted is adjusted.

  According to the present invention, the convergence to the peak point of the extinction curve of the bias control voltage when optimizing the modulation signal gain control is adjusted by dividing into coarse adjustment and fine adjustment, so that the convergence can be achieved in a short time. In addition, it can be performed with high accuracy.

It is a block diagram which shows the optical transceiver apparatus by Embodiment 1 of this invention. It is a flowchart which shows the modulation degree adjustment method by Embodiment 1 of this invention. It is a flowchart which shows the modulation degree adjustment method by Embodiment 2 of this invention. It is explanatory drawing which shows the null point of the extinction curve of a modulator. It is explanatory drawing which shows the peak point of the extinction curve of a modulator.

Embodiment 1 FIG.
FIG. 1 is a block diagram showing an optical transceiver apparatus according to Embodiment 1 of the present invention.
In the figure, the optical transceiver device comprises an optical transmitter 1 and an optical receiver 2.
In the optical transmitter 1, the digital signal processing unit 11 outputs an Ich signal and a Qch signal.
The Ich driver (in-phase component driver) 12 outputs an Ich modulation signal obtained by controlling the gain of the Ich signal.
The Qch driver (orthogonal component driver) 13 outputs a Qch modulation signal obtained by controlling the gain of the Qch signal.
The DQPSK modulator (differential quaternary phase modulator) 14 outputs a DQPSK optical signal corresponding to the Ich modulation signal and the Qch modulation signal.
The light detection unit 15 monitors the DQPSK optical signal output from the DQPSK modulator 14.

In the controller 16, the modulator bias control circuit 17 adjusts the bias control voltage applied to the DQPSK modulator 14 based on the monitor optical signal from the light detector 15.
The modulation signal gain control circuit 18 adjusts the Ich gain control signal output to the Ich driver 12 and the Qch gain control signal output to the Qch driver 13 based on the monitor optical signal from the light detection unit 15. .

In the optical receiver 2, the 1-bit delay interferometer 21 demodulates the input DQPSK optical signal.
The O / E converter 22 converts the demodulated optical signal into an electrical signal and outputs the electrical signal to the digital signal processing unit 11.

Next, the operation will be described.
FIG. 2 shows a flowchart of the modulation degree adjustment method.
In the flowchart shown in FIG. 2, an algorithm divided into coarse adjustment and fine adjustment is introduced so that the bias voltage control for optimizing the modulation signal amplitude can be performed in a short time and with high accuracy.

First, the modulation signal gain control circuit 18 sets all modulation signal outputs of the Ich driver 12 and the Qch driver 13 to OFF (step ST1).
Next, the digital signal processing unit 11 sets a test signal (step ST2).
As the test signal, for example, 10 alternating patterns (a signal in which 1 and 0 are alternately repeated) are set.

The modulator bias control circuit 17 roughly adjusts the bias control voltage applied to the DQPSK modulator 14 so that the light intensity of the DQPSK optical signal monitored by the light detection unit 15 is maximized (step ST3, step ST4). .
As a result, the bias control voltage is converged to the peak point of the extinction curve of the DQPSK modulator 14, as shown in FIG.
By this rough adjustment, first, it becomes possible to shorten the time.

  After the coarse adjustment, the modulation signal gain control circuit 18 sets the modulation signal output to ON only for the driver to be optimized for the modulation signal gain control of the Ich driver 12 and the Qch driver 13 (step ST5).

The modulator bias control circuit 17 finely adjusts the bias control voltage applied to the DQPSK modulator 14 so that the optical time waveform amplitude of the DQPSK optical signal monitored by the light detection unit 15 is minimized (step ST6, step ST6). ST7).
More specifically, the bias control voltage is finely adjusted so that the peak-to-peak value (peak value) of the high frequency component of the DQPSK optical signal monitored by the light detection unit 15 is minimized.
As a result, the bias control voltage deviates from the peak point of the extinction curve by turning on the driver output to be optimized after rough adjustment, but the deviation from the peak point can be corrected by fine adjustment.
Therefore, high precision can be achieved by this fine adjustment.

Based on the DQPSK optical signal monitored by the light detection unit 15, the modulation signal gain control circuit 18 measures the amplitude (modulation degree) for the channel to be optimized set in step ST5, and obtains the desired modulation degree. Adjustment is completed (step ST8, step ST10).
If it is out of specification, the modulation signal gain control circuit 18 outputs a gain control signal to the driver to be optimized (step ST9), and thereafter repeats the processing from step ST6 to step ST9 to thereby obtain the bias control voltage. Are finely adjusted to the peak point of the extinction curve, and the gain control signal for the optimization target driver is adjusted to be within the standard of the desired modulation degree.
In step ST10, the optimization of the modulation signal gain control for one driver is completed.
In the same procedure, the modulation signal gain control for the other driver is optimized, and the degree of modulation of both is matched with the desired degree of modulation.

As described above, according to the first embodiment, for example, when the Ich gain control signal is adjusted, the bias control voltage is once roughly adjusted so as to converge to the peak point of the extinction curve of the DQPSK modulator 14, and thereafter However, the bias control voltage is finely adjusted again to the peak point, and the Ich gain control signal is adjusted to a desired modulation degree.
Therefore, the convergence of the bias control voltage to the peak point of the extinction curve when optimizing the modulation signal gain control is performed by coarse adjustment that maximizes the light intensity of the DQPSK optical signal and the high-frequency signal superimposed on the DQPSK optical signal. By performing the adjustment separately with fine adjustment that minimizes the peak value, convergence can be performed in a short time and with high accuracy.

Embodiment 2. FIG.
The configuration of the optical transceiver apparatus according to the second embodiment is the same as that shown in FIG.
FIG. 3 shows a flowchart of the modulation degree adjustment method according to the second embodiment of the present invention.
In the flowchart shown in FIG. 3, an algorithm divided into coarse adjustment and fine adjustment is introduced so that the bias voltage control when optimizing the modulation signal amplitude can be performed in a short time with high accuracy.

Only the processing different from the flowchart shown in FIG. 2 in the flowchart shown in FIG. 3 will be described below.
In step ST3 and step ST4 in FIG. 2, the bias control voltage applied to the DQPSK modulator 14 by the modulator bias control circuit 17 is set so that the light intensity of the DQPSK optical signal monitored by the light detection unit 15 becomes maximum. Coarse adjustment was made.
In the flowchart shown in FIG. 3, the modulator bias control circuit 17 performs rough adjustment so that the bias control voltage applied to the DQPSK modulator 14 converges to the peak point of the extinction curve of the DQPSK modulator 14 (step ST11). .
As a result, the bias control voltage is converged to the peak point of the extinction curve of the DQPSK modulator 14, as shown in FIG.
By this rough adjustment, first, it becomes possible to shorten the time.

  Switching of the bias control voltage from the null point to the peak point of the extinction curve is only due to the difference in the sign of the control signal. What is necessary is just to add to the software of the modulator bias control circuit 17.

Further, in step ST6 and step ST7 in FIG. 2, the bias control voltage applied to the DQPSK modulator 14 by the modulator bias control circuit 17 is minimized, and the optical time waveform amplitude of the DQPSK optical signal monitored by the light detection unit 15 is minimized. Tweaked so that
In the flowchart shown in FIG. 3, the bias control voltage applied to the DQPSK modulator 14 is roughly adjusted by the modulator bias control circuit 17 so as to converge to the peak point of the extinction curve of the DQPSK modulator 14 (step ST12). .
As a result, the bias control voltage deviates from the peak point of the extinction curve by turning on the driver output to be optimized after rough adjustment, but the deviation from the peak point can be corrected by fine adjustment.
Therefore, high precision can be achieved by this fine adjustment.

As described above, according to the second embodiment, for example, when the Ich gain control signal is adjusted, the bias control voltage is once roughly adjusted so as to converge to the peak point of the extinction curve of the DQPSK modulator 14, and thereafter However, the bias control voltage is finely adjusted again to the peak point, and the Ich gain control signal is adjusted to a desired modulation degree.
Therefore, by adjusting the convergence of the bias control voltage to the peak point of the extinction curve when optimizing the modulation signal gain control separately for coarse adjustment and fine adjustment, the convergence can be achieved in a short time and with high accuracy. It can be carried out.

  In the present invention, within the scope of the invention, any combination of the embodiments, or any modification of any component in each embodiment, or omission of any component in each embodiment is possible. .

  1 optical transmitter, 2 optical receiver, 11 digital signal processor, 12 Ich driver (in-phase component driver), 13 Qch driver (quadrature component driver), 14 DQPSK modulator (differential quaternary phase modulator), 15 Photodetector, 16 Controller, 17 Modulator bias control circuit, 18 Modulated signal gain control circuit, 21 1-bit delay interferometer, 22 O / E converter.

Claims (2)

An in-phase component driver that outputs an in-phase component modulation signal obtained by controlling the gain of the in-phase component signal;
A quadrature component driver that outputs a quadrature component modulation signal obtained by controlling the gain of the quadrature component signal;
A differential quaternary phase modulator that outputs a differential quaternary phase modulated optical signal corresponding to the in-phase component modulated signal and the quadrature component modulated signal;
A photodetector for monitoring the differential quaternary phase modulated optical signal;
The bias control voltage applied to the differential quaternary phase modulator is adjusted based on the monitor light signal from the light detection unit, and the gain control signal output to the in-phase component driver and the quadrature component driver is adjusted. And a control unit that
The control unit
The bias control voltage to be applied to the differential quaternary phase modulator is roughly adjusted so that the light intensity of the differential quaternary phase modulated optical signal monitored by the photodetection unit is maximized,
Utilizing only the modulation signal output from the driver to be adjusted among the in-phase component driver and the quadrature component driver,
Further, the bias control voltage applied to the differential quaternary phase modulator is finely adjusted so that the peak value of the high frequency signal superimposed on the differential quaternary phase modulated optical signal monitored by the photodetection unit is minimized. And adjusting the gain control signal for the driver to be adjusted. An in-phase component driver that outputs an in-phase component modulation signal obtained by controlling the gain of the in-phase component signal;
A quadrature component driver that outputs a quadrature component modulation signal obtained by controlling the gain of the quadrature component signal;
A differential quaternary phase modulator that outputs a differential quaternary phase modulated optical signal corresponding to the in-phase component modulated signal and the quadrature component modulated signal;
A photodetector for monitoring the differential quaternary phase modulated optical signal;
The bias control voltage to be applied to the differential quaternary phase modulator is adjusted, and the gain control signal output to the in-phase component driver and the quadrature component driver is adjusted based on the monitor optical signal from the photodetector. And a control unit that
The control unit
The bias control voltage applied to the differential quaternary phase modulator is coarsely adjusted to converge to the peak point of the extinction curve of the differential quaternary phase modulator,
Utilizing only the modulation signal output from the driver to be adjusted among the in-phase component driver and the quadrature component driver,
Further, the bias control voltage applied to the differential quaternary phase modulator is finely adjusted to converge to the peak point of the extinction curve of the differential quaternary phase modulator, and the gain control signal for the driver to be adjusted is adjusted. Adjusting the optical transmitter.

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