JP6475567B2 - Optical transmitter - Google Patents

Description

  The present invention relates to an optical transmitter.

  As means for generating an optical signal used for an optical transmitter, an optical modulator having a function of modulating the intensity and optical phase of CW light (continuous light) is widely used. There are several types of optical modulators, but in the basic configuration of an optical modulator, an optical input terminal for inputting a CW light source, an optical output terminal for outputting a modulated signal, and an electrical data signal are input. A drive signal input terminal. In an optical modulator in an ideal state, an optical intensity modulation signal and an optical phase modulation signal corresponding to a high-speed electrical signal input to the drive signal input terminal are output from the optical output terminal.

In an actual optical modulator, the quality of the optical signal output from the optical output terminal may deteriorate with time due to temperature fluctuations and other reasons. In particular, the phenomenon of bias drift in which the optimum value of the bias voltage that determines the operating point of the optical modulator and the optical phase difference of the interferometer of the optical modulator fluctuates with time is an optical modulation using LiNbO ₃ (lithium niobate). If the device is left unattended, the optical signal deteriorates within a few hours so that it cannot be demodulated, so in-service ABC (Auto Bias Control) is essential. In addition, since the drive amplitude of the drive amplifier that generates the drive signal may decrease due to deterioration over time, in-service drive amplitude monitoring and automatic adjustment are also important in the long-term operation of the transmitter. .

  There are various approaches to ABC and automatic drive amplitude adjustment, but the bias voltage and modulator drive signal amplitude are slightly dithered to monitor the modulator operating point and drive amplitude condition, and the bias voltage The method of controlling the gain of the driving amplifier is widely adopted because of its simplicity.

Here, an optical transmitter using an MZI (Mach-Zehnder Interferometer) type optical modulator will be described as an example of an optical transmitter widely used at present. FIG. 4 is a diagram illustrating a typical configuration example of the MZI type optical modulator 3 and peripheral devices. The optical modulator 3 includes a first coupler 1, a second coupler 2, first and second drive signal input terminals 4 and 5, and first and second bias voltage application terminals 7 and 8. Have. The CW light input to the optical input terminal of the optical modulator 3 is divided into two CW lights by the first coupler 1 and propagates through the two arms of the MZI. The optical path lengths of these two arms can be slightly changed by an externally applied electric field. The CW light propagated through the two arms is multiplexed by the second coupler 2 and output to the outside via the optical output terminal of the optical modulator 3. The intensity or optical phase of the output light is determined by the delay difference between the CW lights in the two arms. Therefore, by modulating the electric field applied to the two arms, it is possible to generate a light intensity modulation signal, an optical phase modulation signal, or a variation thereof. The electric fields applied to the two arms are the drive signal ￣Data1 input from the first drive signal input terminal 4, the drive signal Data1 input from the second drive signal input terminal 5, and the first bias voltage application terminal 7. composed of two types of the bias voltage _{¯V bias1} applied from the bias voltage _{V bias1} and the second bias voltage applying terminal 8 applied from.

Next, peripheral devices of the optical modulator 3 will be described. The drive amplifier 6 amplifies the data signal and differentially outputs the data signal to generate the drive signals Data1 and ￣Data1. The drive signals Data 1 and ￣ Data 1 output from the drive amplifier 6 are input to the first and second drive signal input terminals 4 and 5. The DC amplifier 10 amplifies the DC voltage output from the variable DC power source 9, and generates a bias voltage V _bias1 and ￣V _bias1 by differentially outputting the DC voltage. The bias voltages V _bias1 and ￣V _bias1 output from the DC amplifier 10 are applied to the first and second bias voltage application terminals 7 and 8.

Dithering for modulator control, it is more style according to the purpose, where vice voltage V _{bias1 is} a dithering added to the voltage value of ¯V _bias1, description will be given of a configuration for performing ABC. Dither signal angular frequency omega _d generated by the oscillator 12, the bias voltage output from the variable DC power supply 9 is superimposed with a bias T (Bias Tee) 11. Here, the angular frequency ω _d is sufficiently lower than the symbol rate of the data signal, and the amplitude of the dither signal is sufficiently smaller than the amplitudes of Data 1 and ￣ Data 1 so as not to affect the transmission signal quality. The modulated light output from the optical modulator 3 is output from the optical output terminal of the optical transmitter, tapped by the optical tap 13, and input to the photodetector 14. The photodetector 14 converts the input modulated light into an electric signal and outputs the electric signal obtained by the conversion to the synchronous detection circuit 15. The synchronous detection circuit 15 uses the output of the oscillator 12 as a reference clock, a component having a variation of the angular frequency ω _d and a component having a variation of an integral multiple of the angular frequency ω _d from the electrical signal obtained by the photodetector 14 ( Harmonics). The synchronous detection result is input to the feedback control circuit 16 to determine whether the bias voltage is excessive or excessive. The determination result is fed back to the variable DC power source 9 to achieve ABC.

How to determine the magnitude of the feedback signal to the variable DC power source 9 from the synchronous detection result differs depending on the modulation format and the drive amplitude, but cannot be generally described. However, as an example, in the configuration of FIG. when generating a CS-RZ signal by signal, to the synchronous detection result component having a variation of omega _d, it may be the result changes the output voltage of the variable DC power supply 9 so as to be 0. When generating an optical signal with a more complicated modulation format, for example, optical QAM, an optical modulator composed of a plurality of MZI composites is required. The asymmetric bias dithering described in Patent Document 1 can be used.

Hiroto Kawakami, Takayuki Kobayashi, Mitsuteru Yoshida, Tomoyoshi Kataoka and Yutaka Miyamoto, "Auto bias control and bias hold circuit for IQ-modulator in flexible optical QAM transmitter with Nyquist filtering", OpticsExpress, 2014, Vol.22, No. 23, p .28163-28168

  In the conventional configuration shown in FIG. 4, the description has been made assuming that ideal CW light is input to the optical modulator 3. However, it is not always easy to generate ideal CW light with an actual CW light source. It is often the case that a slight intensity modulation is superimposed on the optical power due to coherency degradation due to slight fluctuations in the optical phase, multiple reflections or disturbances in the optical circuit. In the ABC circuit and automatic drive amplitude adjustment circuit that detect the dither component superimposed on the modulator output light, irregular fluctuations derived from the unstable output of the CW light source are superimposed on the periodic fluctuations derived from the dither signal. However, since noise is generated in the output of the synchronous detection circuit, there is a problem that a control error may occur.

  Another problem with the conventional configuration is that the circuit scale is doubled when generating a polarization multiplexed signal. In recent optical communication, in order to improve frequency utilization efficiency, it is widely performed to transmit two different signals by polarization multiplexing using carrier CW light generated from one CW light source. Such an ABC circuit and automatic drive amplitude adjustment circuit for an optical transmitter can be realized by operating two optical modulators having the conventional configuration shown in FIG. 4 in parallel and polarization multiplexing the output light. . However, there is a problem that the circuit scale becomes two, and at the same time, a control error derived from the instability of the CW light source described above appears for both of the two polarized waves.

  The present invention has been made in consideration of such circumstances, and its purpose is to monitor the state of the optical modulator by detecting a dither component superimposed on the modulated light and perform various controls. An object of the present invention is to provide an optical transmitter capable of reducing a control error even when a CW light source output is unstable.

  One aspect of the present invention is an optical branching unit that splits CW light output from a CW light source into first CW light and second CW light, and a bias voltage for adjusting an operating point or an internal optical phase. A first optical modulator that has a first bias voltage application terminal group to which is applied and a first drive signal input terminal group to which a drive signal is input, and modulates and outputs the first CW light A second bias voltage application terminal group to which a bias voltage for adjusting an operating point or an internal optical phase is applied, and a second drive signal input terminal group to which a drive signal is input, A second optical modulator that modulates and outputs the second CW light, and a polarization that multiplexes and outputs the optical signal output from the first optical modulator and the second optical modulator. And a first unit for monitoring the optical power of the optical signal output from the first optical modulator. A detector, a second photodetector for monitoring the optical power of the optical signal output from the second optical modulator, and the optical power monitored by the first photodetector and the second photodetector. Differential amplification means for canceling intensity fluctuations superimposed on CW light output from the CW light source by differentially amplifying and outputting an electrical signal, and based on the output from the differential amplification means, Bias voltage applied to one bias voltage application terminal group and the second bias voltage application terminal group, or drive input to the first drive signal input terminal group and the second drive signal input terminal group And an adjustment circuit that adjusts the amplitude of the signal.

  According to another aspect of the present invention, in the optical transmitter described above, the bias voltage applied to the first bias voltage application terminal group or the amplitude of the drive signal input to the first drive signal input terminal group. First dithering means for performing dithering, and a bias voltage applied to the second bias voltage application terminal group or an amplitude of a drive signal input to the second drive signal input terminal group A second dithering means for performing dithering, and a dither signal added by the first dithering means and the second dithering means from the electrical signal differentially amplified by the differential amplifying means or the dithering A synchronous detection circuit that synchronously detects harmonics of the signal, and the adjustment circuit is configured to detect the first bias based on a synchronous detection result by the synchronous detection circuit. The bias voltage applied to the pressure application terminal group and the second bias voltage application terminal group, or the amplitude of the drive signal input to the first drive signal input terminal group and the second drive signal input terminal group adjust.

  In one embodiment of the present invention, in the optical transmitter described above, the first dithering means and the second dithering means use dither signals having different frequencies.

  Further, according to one aspect of the present invention, in the above optical transmitter, the first dithering unit and the second dithering unit use a dither signal having the same frequency and perform dithering in different periods. By doing so, the dither signal is time-shared.

  According to one embodiment of the present invention, in the above-described optical transmitter, the first optical modulator or the second optical modulator is configured by using one Maha-Zehnder interferometer or a plurality of Maha-Zehnder interferometers. .

  Another embodiment of the present invention is an optical branching unit that splits CW light output from a CW light source into first CW light and second CW light, and a bias voltage for adjusting an operating point or optical phase. An optical modulator for modulating and outputting the first CW light, and an output from the optical modulator. A first photo detector for monitoring the optical power of the optical signal, a second photo detector for monitoring the optical power of the second CW light, and the first photo detector and the second photo detector. Differential amplification means for canceling intensity fluctuations superimposed on the CW light output from the CW light source by differentially amplifying and outputting an electrical signal indicating the optical power generated, and output from the differential amplification means On the basis of the, Serial bias voltage is applied to the bias voltage application terminal group or an adjustment circuit for adjusting the amplitude of the drive signal input to the drive signal input terminals, an optical transmitter having a.

  According to one embodiment of the present invention, in the above optical transmitter, the optical modulator is configured using a single Maha-Zehnder interferometer or a plurality of Maha-Zehnder interferometers.

  According to another aspect of the present invention, in the above optical transmitter, the differential amplifying unit attenuates an electrical signal output from the first photodetector or an electrical signal output from the second photodetector. When there is a difference in sensitivity between monitoring by the first photo detector and monitoring by the second photo detector, the difference in sensitivity is reduced by the attenuator.

  According to the present invention, even when the output of the CW light source connected to the input port of the optical modulator is unstable, the control error can be reduced, and highly accurate ABC and drive amplitude adjustment are possible. .

It is a figure which shows the structural example of the optical transmitter in 1st Embodiment. It is a figure which shows the structural example of the optical transmitter in 3rd Embodiment. It is a figure which shows the structural example of the optical transmitter in 5th Embodiment. It is a figure which shows the typical structural example of an MZI type | mold optical modulator and a peripheral device.

  Hereinafter, an optical transmitter according to an embodiment of the present invention will be described with reference to the drawings. The optical transmitter shown in each embodiment has a feature related to automatic control of the optical modulator, and in particular has a feature of controlling the bias voltage of the optical modulator or the amplitude of the drive signal to an optimum value using a dither signal. In each embodiment described below, the same components as those shown in FIG. 4 or the components in the other embodiments are denoted by the same reference numerals, and redundant description is omitted.

<First Embodiment>
FIG. 1 is a diagram illustrating a configuration example of an optical transmitter according to the first embodiment of the present invention. In the first embodiment, it is assumed that ABC (automatic bias voltage adjustment) is applied to an optical transmitter that generates a polarization multiplexed signal. As shown in FIG. 1, the optical transmitter according to the first embodiment includes a polarization maintaining coupler 600, a first optical modulator 3x, a second optical modulator 3y, a first optical tap 13x, and a second optical tap. Optical tap 13y, polarization combiner 601, first drive amplifier 6x, second drive amplifier 6y, first photo detector 14x, second photo detector 14y, first attenuator 603x, second attenuator 603y , Differential amplifier 602, first oscillator 12x, second oscillator 12y, first synchronous detection circuit 15x, second synchronous detection circuit 15y, first feedback control circuit 16x, second feedback control circuit 16y , First variable DC power supply 9x, second variable DC power supply 9y, first bias T11x, second bias T11y, first DC amplifier 10x, and second DC amplifier 10y.

  In the optical transmitter according to the first embodiment, the first photo detector 14x, the second photo detector 14y, the first attenuator 603x, the second attenuator 603y, the differential amplifier 602, and the first oscillator 12x. , Second oscillator 12y, first synchronous detection circuit 15x, second synchronous detection circuit 15y, first feedback control circuit 16x, second feedback control circuit 16y, first variable DC power supply 9x, second The variable DC power supply 9y, the first bias T11x, the second bias T11y, the first DC amplifier 10x, and the second DC amplifier 10y constitute an ABC circuit as an adjustment circuit. However, there are many optical modulators in which the first optical tap 13x and the first photo detector 14x, or the second optical tap 13y and the second photo detector 14y are built in the housing, and the ABC circuit uses these photo taps. The structure connected to the output of a detector may be sufficient.

  The CW light input from the optical input terminal of the optical transmitter is branched into two CW lights (first CW light and second CW light) by the polarization maintaining coupler 600. The first CW light is input to a first optical modulator 3x that generates an optical signal having a first polarization component. The second CW light is input to the second optical modulator 3y that generates an optical signal of the second polarization component. The configuration of the first optical modulator 3x and the second optical modulator 3y is the same as that of the optical modulator 3 shown in FIG.

  The first optical modulator 3x includes first and second drive signal input terminals 4x and 5x as a first drive signal input terminal group, and first and second drive signal input terminals as a first bias voltage application terminal group. Bias voltage application terminals 7x and 8x. In the first optical modulator 3x, the operating point or the optical phase inside the first optical modulator 3x is adjusted according to the bias voltage applied to the first bias voltage application terminal group. Further, light intensity modulation and optical phase modulation are performed on the input first CW light in accordance with the drive signal input from the first drive signal input terminal group.

  The second optical modulator 3y includes first and second drive signal input terminals 4y and 5y as a second drive signal input terminal group, and first and second drive signal input terminals as a second bias voltage application terminal group. Bias voltage application terminals 7y and 8y are provided. In the second optical modulator 3y, the operating point or the optical phase in the second optical modulator 3y is adjusted according to the bias voltage applied to the first bias voltage application terminal group. Further, intensity modulation or optical phase modulation is performed on the input second CW light in accordance with the drive signal input from the second drive signal input terminal group.

  The polarization combiner 601 receives the first polarization component optical signal generated by the first optical modulator 3x and the second polarization component optical signal generated by the second optical modulator 3y. The optical signal obtained by polarization multiplexing and polarization multiplexing is output from the optical output terminal of the optical transmitter.

  Next, peripheral devices of the first optical modulator 3x and the second optical modulator 3y will be described. The first drive amplifier 6x amplifies the data signal and differentially outputs the amplification result to generate the drive signals DataX and ￣DataX. The second drive amplifier 6y amplifies the data signal and differentially outputs the amplification result to generate drive signals DataY and ￣DataY.

  The modulated light output from the first optical modulator 3x is tapped by the first optical tap 13x and converted into an electrical signal by the first photodetector 14x. The electrical signal output from the first photodetector 14x is input to the differential amplifier 602 via the first attenuator 603x. The modulated light output from the second optical modulator 3y is tapped by the second optical tap 13y and converted into an electrical signal by the second photodetector 14y. The electrical signal output from the second photodetector 14y is input to the differential amplifier 602 via the second attenuator 603y. The differential amplifier 602 differentially amplifies the two input electric signals and outputs them to the first synchronous detection circuit 15x and the second synchronous detection circuit 15y. The intensity fluctuation of the CW light before modulation is superimposed on the electric signals output from the first photo detector 14x and the second photo detector 14y, respectively. However, in the process of performing differential amplification in the differential amplifier 602, this fluctuation in intensity is canceled out. When the accuracy error of the optical component and the difference in conversion efficiency between the first photo detector 14x and the second photo detector 14y are not negligible, the first attenuator 603x and the second attenuator 603y are used. After reducing the difference in conversion efficiency, the intensity fluctuation of the CW light contained in the electric signal is completely canceled by differential amplification. If there is a difference in sensitivity in monitoring between the first photo detector 14x and the second photo detector 14y, similarly, the difference in sensitivity is reduced using the first attenuator 603x and the second attenuator 603y. You may do it.

The first oscillator 12x generates a dither signal having an angular frequency ω _dx and outputs the generated dither signal to the first synchronous detection circuit 15x and the bias T11x. The bias T11x superimposes the dither signal having the angular frequency ω _dx on the DC voltage output from the first variable DC power supply 9x and outputs the superimposed DC voltage to the first DC amplifier 10x. The first DC amplifier 10x amplifies a DC voltage on which a dither signal is superimposed, and generates a bias voltage V _biasX and ￣V _biasX by differentially outputting the amplified DC voltage. The bias voltages V _biasX and ￣V _biasX are applied to the first and second bias voltage application terminals 7x and 8x of the first optical modulator 3x.

The second oscillator 12y generates a dither signal having an angular frequency ω _dy and outputs the generated dither signal to the second synchronous detection circuit 15y and the bias T11y. The bias T11y superimposes a dither signal having an angular frequency ω _dy on the DC voltage output from the second variable DC power supply 9y, and outputs the superimposed signal to the second DC amplifier 10y. The second DC amplifier 10y amplifies the DC voltage dither signal is superimposed, the bias voltage _V BiasY by which the output _{differential,} generates a _{¯V biasY.} The bias voltages V _biasY and ￣V _biasY are applied to the first and second bias voltage application terminals 7y and 8y of the second optical modulator 3y.

Here, the angular frequencies ω _dx and ω _dy are determined sufficiently lower than the symbol rate of the data signal so as not to affect the transmission signal quality. Different values are used for the angular frequencies ω _dx and ω _dy , and the frequencies of the two dither signals are different. The amplitude of the dither signal is determined to be sufficiently smaller than the amplitudes of the drive signals DataX and DataY.

The signal amplified by the differential amplifier 602 is input to the first synchronous detection circuit 15x and the second synchronous detection circuit 15y. The signal output from the differential amplifier 602 includes dither components having angular frequencies ω _dx and ω _dy . The first synchronous detection circuit 15x uses the dither signal output from the first oscillator 12x as a reference clock, and is an integer multiple (including 1) of the angular frequency ω _dx from the signal output from the differential amplifier 602. Synchronously detect components with fluctuations. The second synchronous detection circuit 15y has a variation of an integral multiple of the angular frequency ω _dy from the signal output from the differential amplifier 602 using the dither signal output from the second oscillator 12y as a reference clock. Synchronously detect components.

  The first feedback control circuit 16x determines whether the DC voltage (bias voltage) output from the first variable DC power supply 9x is excessive or small based on the synchronous detection result by the first synchronous detection circuit 15x. Judgment is made. The determination result by the first feedback control circuit 16x is fed back to the first variable DC power supply 9x. The first variable DC power source 9x changes the output DC voltage according to the fed back determination result. In this way, ABC for the first optical modulator 3x is achieved. Further, the second feedback control circuit 16y is based on the synchronous detection result by the second synchronous detection circuit 15y, and the DC voltage (bias voltage) output from the second variable DC power source 9y is excessive or small. Determine if there is any. The determination result by the second feedback control circuit 16y is fed back to the second variable DC power supply 9y. The second variable DC power source 9y changes the output DC voltage according to the fed back determination result. In this way, ABC for the second optical modulator 3y is achieved.

  The amount of change in the output of the first variable DC power supply 9x is determined by the first feedback control circuit 16x using a known technique based on the output of the first synchronous detection circuit 15x. Similarly, the amount of change in the output of the second variable DC power supply 9y is determined by the second feedback control circuit 16y using a known technique based on the output of the second synchronous detection circuit 15y. In this way, the bias voltage output from the first variable DC power supply 9x and the second variable DC power supply 9y is adjusted using the synchronous detection results by the first synchronous detection circuit 15x and the second synchronous detection circuit 15y. Is done.

  In the optical transmitter according to the first embodiment described above, although the scale of the ABC circuit is about twice that of the conventional configuration shown in FIG. 4, it is included in the electrical signal indicating the monitoring result of the optical power. A highly accurate ABC can be realized by canceling the intensity fluctuation of the CW light source. In addition, the ABC circuit in the first embodiment is compatible with a polarization multiplexing type optical transmitter.

<Second Embodiment>
In the first embodiment shown in FIG. 1, a configuration in which ABC is applied to an optical transmitter that generates a polarization multiplexed signal has been described. In the optical transmitter according to the second embodiment, as a variation of the first embodiment, dithering is performed on the amplitude of the drive signal instead of the bias voltage, and the first synchronous detection circuit 15x and the second synchronous detection are performed. A configuration may be adopted in which the amplitude of the drive signal output from the first drive amplifier 6x and the second drive amplifier 6y is adjusted using the synchronous detection result by the circuit 15y.

  Specifically, the first feedback control circuit 16x determines whether the amplitude of the drive signal output from the first drive amplifier 6x is excessive or small based on the synchronous detection result by the first synchronous detection circuit 15x. Determine if there is any. The determination result by the first feedback control circuit 16x is fed back to the first drive amplifier 6x, and the amplitude adjustment of the drive signal is achieved. The second feedback control circuit 16y determines whether the amplitude of the drive signal output from the second drive amplifier 6y is excessive or small based on the synchronous detection result by the second synchronous detection circuit 15y. Make a decision. The determination result by the second feedback control circuit 16y is fed back to the second drive amplifier 6y, and the amplitude adjustment of the drive signal is achieved. Note that the amount of change in the amplitude of the first drive amplifier 6x and the second drive amplifier 6y can be determined using a known technique based on each synchronous detection result.

<Third Embodiment>
The optical transmitter according to the first embodiment shown in FIG. 1 has a circuit scale almost twice that of the ABC circuit in the optical transmitter shown in FIG. In the third embodiment, a configuration example of an ABC circuit with a reduced circuit scale is shown. FIG. 2 is a diagram illustrating a configuration example of an optical transmitter according to the third embodiment.

  As shown in FIG. 2, the optical transmitter in the third embodiment includes a polarization maintaining coupler 600, a first optical modulator 3x, a second optical modulator 3y, a first optical tap 13x, and a second optical tap. Optical tap 13y, polarization combiner 601, first photo detector 14x, second photo detector 14y, first attenuator 603x, second attenuator 603y, differential amplifier 602, oscillator 12, synchronous detection circuit 15 , Feedback control circuit 16, first variable DC power supply 9x, second variable DC power supply 9y, first bias T11x, second bias T11y, first DC amplifier 10x, second DC amplifier 10y, switch 604 And a controller 605. In the optical transmitter according to the third embodiment, the first photo detector 14x, the second photo detector 14y, the first attenuator 603x, the second attenuator 603y, the differential amplifier 602, the oscillator 12, and the synchronous detection. Circuit 15, feedback control circuit 16, first variable DC power supply 9x, second variable DC power supply 9y, first bias T11x, second bias T11y, first DC amplifier 10x, second DC amplifier 10y, The switch 604 and the controller 605 constitute an ABC circuit as an adjustment circuit. However, there are many optical modulators in which the first optical tap 13x and the first photo detector 14x, or the second optical tap 13y and the second photo detector 14y are built in the housing, and the ABC circuit uses these photo taps. The structure connected to the output of a detector may be sufficient.

In the optical transmitter according to the first embodiment, the first oscillator 12x and the second oscillator 12y generate dither signals having angular frequencies ω _dx and ω _dy . The optical transmitter according to the third embodiment includes a single oscillator 12 instead of the two first oscillators 12x and the second oscillator 12y, and uses the oscillator 12 for time sharing. Dither signal angular frequency omega _d generated by the oscillator 12, the switch 604 is outputted to one of the bias T11x and bias T11y. When the dither signal is output from the switch 604 to the bias T11x, the dither signal is superimposed on the bias voltage output from the first variable DC power supply 9x by the bias T11x. When the dither signal is output from the switch 604 to the bias T11y, the dither signal is superimposed on the bias voltage output from the second variable DC power supply 9y by the bias T11y. The switching timing of the switch 604 is controlled by the controller 605. In the switching, for example, dithering may be performed in different periods by alternately switching the output destination of the dither signal between the bias T11x and the bias T11y in a predetermined cycle.

In the optical transmitter according to the first embodiment, the first synchronous detection circuit 15x and the second synchronous detection circuit 15y are used. The optical transmitter according to the third embodiment includes a synchronous detection circuit 15 instead of the two first synchronous detection circuits 15x and the second synchronous detection circuit 15y. Synchronous detection circuit 15, the dither signal output from the oscillator 12 as the reference clock, synchronous detection of the variation of the integral multiple of the angular frequency omega _d from the output of the differential amplifier 602 (including one time). The synchronous detection result is input to the feedback control circuit 16 to determine whether the bias voltage is excessive or excessive. The determination result is fed back to either the first variable DC power supply 9x or the second variable DC power supply 9y. The feedback destination of the determination result is controlled by the controller 605. The feedback destination of the determination result is selected from either the first variable DC power supply 9x or the second variable DC power supply 9y so as to coincide with the side on which the dither signal is output by the switch 604 (bias T11x and bias T11y). Is done. The ABC for the first optical modulator 3x and the second optical modulator 3y is achieved by time sharing control of the determination of whether the bias voltage is excessive or excessive and the superposition of the dither signal. The

  According to the optical transmitter in the third embodiment, the number of oscillators and synchronous detection circuits is halved compared to the configurations of the optical transmitters shown in the first and second embodiments, and the scale of the ABC circuit is reduced. It becomes possible to suppress.

<Fourth Embodiment>
In the third embodiment shown in FIG. 2, the configuration in which ABC is applied to an optical transmitter that generates a polarization multiplexed signal has been described. As a variation on the optical transmitter of the third embodiment, instead of the bias voltage output from the first variable DC power supply 9x and the second variable DC power supply 9y, the first drive amplifier 6x and the second drive amplifier it may be subjected to dithering for superimposing a dither signal amplitude to the angular frequency omega _d of the drive signal output from 6y. In this case, the amplitude of the drive signal output from the first drive amplifier 6x and the second drive amplifier 6y may be adjusted by time sharing using the synchronous detection result by the synchronous detection circuit 15. In this case, the feedback control circuit 16 determines whether the amplitude of the drive signal amplified by the first drive amplifier 6x and the second drive amplifier 6y is excessive or small based on the synchronous detection result. I do. The feedback control circuit 16 feeds back the determination result to the first drive amplifier 6x or the second drive amplifier 6y, and controls the amplification factors of the first drive amplifier 6x and the second drive amplifier 6y, so that the drive signal Amplitude adjustment is achieved. Note that the amount of change in the amplitude of the first drive amplifier 6x and the second drive amplifier 6y can be determined using a known technique based on each synchronous detection result.

<Fifth Embodiment>
In the first to fourth embodiments described above, the configuration in which ABC or drive amplitude control is applied to an optical transmitter that generates a polarization multiplexed optical signal has been described. However, ABC and drive amplitude control shown in the first to fourth embodiments can also be applied to an optical transmitter that generates a single-polarized optical signal. In the fifth embodiment, a configuration example in which ABC or drive amplitude control is applied to an optical transmitter that generates a single-polarized optical signal is shown. FIG. 3 is a diagram illustrating a configuration example of an optical transmitter according to the fifth embodiment.

  As shown in FIG. 3, the optical transmitter according to the fifth embodiment includes an optical tap 700, an optical modulator 3, an optical tap 13, a drive amplifier 6, a first photo detector 14x, a second photo detector 14y, The first attenuator 603x, the second attenuator 603y, the differential amplification amplifier 602, the oscillator 12, the synchronous detection circuit 15, the feedback control circuit 16, the variable DC power supply 9, the bias T11, and the DC amplifier 10 are included. In the fifth embodiment, the first photo detector 14x, the second photo detector 14y, the first attenuator 603x, the second attenuator 603y, the differential amplifier 602, the oscillator 12, the synchronous detector circuit 15, and the feedback The control circuit 16, the variable DC power supply 9, the bias T11, and the DC amplifier 10 constitute an ABC circuit as an adjustment circuit. However, there are many optical modulators in which the optical tap 13 and the first photo detector 14x are built in the housing, and the ABC circuit may be connected to the output of the photo detector.

  In the optical transmitter according to the fifth embodiment, the CW light is branched using the optical tap 700 before the CW light input to the optical input terminal of the optical transmitter is input to the optical modulator 3. The CW light branched by the optical tap 700 is converted into an electric signal by the second photodetector 14y. The electrical signal obtained by the second photodetector 14y is not affected by dithering, but is affected by intensity fluctuations of the CW light. The modulated light output from the optical modulator 3 is output from the optical output terminal of the optical transmitter and branched by the optical tap 13 in the same manner as the optical transmitters in the first to fourth embodiments. To the photo detector 14x. The modulated light is converted into an electrical signal by the first photodetector 14x.

  These electric signals obtained by the conversion by the first photo detector 14x and the second photo detector 14y are differentially amplified by the differential amplifier 602, and the amplification result is input to the synchronous detection circuit 15. The intensity fluctuation that the CW light before modulation has is superimposed on both the electrical signals output from the first photo detector 14x and the second photo detector 14y. However, in the process of performing differential amplification in the differential amplifier 602, this intensity fluctuation is canceled out, so that highly accurate ABC is possible.

<Sixth Embodiment>
In the first to fifth embodiments, the configuration of an optical transmitter using an optical modulator based on a single Mach-Zehnder interferometer has been described. However, in order to generate a complex optical signal such as an optical QAM signal, it is necessary to use a nested optical modulator in which a plurality of Maha-Zehnder interferometers are combined. The ABC and drive amplitude control shown in each of the above-described embodiments can be applied to an optical transmitter using such a nest type optical modulator. The ABC of the nest type optical modulator is more complicated than the ABC of the optical modulator using a single Mach-Zehnder interferometer, but can be realized by using asymmetric bias dithering described in Non-Patent Document 1. The modulated light output from the nest type optical modulator is amplified by using a differential amplifier to remove the intensity fluctuation of the CW light source, similarly to the optical transmitters of the first to fifth embodiments. This makes it possible to perform highly accurate ABC.

In the first to sixth embodiments described above, the materials constituting the optical modulators 3, 3x, 3y are not particularly mentioned. Currently, the main types of optical modulators are an LN modulator that uses a refractive index change of an optical waveguide using LiNbO ₃ and a semiconductor optical modulator that uses a refractive index change of a semiconductor. The ABC and the drive amplitude control shown in each of the embodiments can be applied to any type of optical modulator.

  The embodiment of the present invention has been described in detail with reference to the drawings. However, the specific configuration is not limited to this embodiment, and includes designs and the like that do not depart from the gist of the present invention.

  Even when the output of the CW light source is unstable, the present invention can also be applied to applications where it is essential to reduce the control error.

  DESCRIPTION OF SYMBOLS 1 ... 1st coupler, 2 ... 2nd coupler, 3 ... Optical modulator, 3x ... 1st optical modulator, 3y ... 2nd optical modulator, 4, 4x, 4y ... 1st drive signal input Terminals 5, 5x, 5y ... second drive signal input terminal, 6 ... drive amplifier, 6x ... first drive amplifier, 6y ... second drive amplifier, 7, 7x, 7y ... first bias voltage application terminal 8, 8x, 8y ... second bias voltage application terminal, 9 ... variable DC power supply, 9x ... first variable DC power supply, 9y ... second variable DC power supply, 10 ... DC amplifier, 10x ... first DC Amplifier, 10y ... second DC amplifier, 11, 11x, 11y ... bias T, 12 ... oscillator, 12x ... first oscillator, 12y ... second oscillator, 13 ... optical tap, 13x ... first optical tap, 13y ... second optical tap, 14 ... photo detector, 14x ... first photo detector 14 y... Second photo detector, 15... Synchronous detection circuit, 15 x... First synchronous detection circuit, 15 y... Second synchronous detection circuit, 16 ... Feedback control circuit, 16 x. ... second feedback control circuit, 600 ... polarization maintaining coupler, 601 ... polarization combiner, 602 ... differential amplifier, 603x ... first attenuator, 603y ... second attenuator, 604 ... switch, 605 ... Controller, 700 ... Optical tap

Claims (8)

Light branching means for branching the CW light output from the CW light source into the first CW light and the second CW light;
A first bias voltage application terminal group to which a bias voltage for adjusting an operating point or an internal optical phase is applied and a first drive signal input terminal group to which a drive signal is input; A first optical modulator that modulates and outputs CW light;
A second bias voltage application terminal group to which a bias voltage for adjusting an operating point or an internal optical phase is applied and a second drive signal input terminal group to which a drive signal is input; A second optical modulator for modulating and outputting CW light;
Polarization multiplexing means for polarization multiplexing and outputting optical signals output from the first optical modulator and the second optical modulator;
A first photodetector for monitoring the optical power of the optical signal output from the first optical modulator;
A second photodetector for monitoring the optical power of the optical signal output from the second optical modulator;
By differentially amplifying and outputting an electrical signal indicating the optical power monitored by the first photodetector and the second photodetector, intensity fluctuations superimposed on the CW light output from the CW light source are canceled out. Differential amplification means,
A bias voltage applied to the first bias voltage application terminal group and the second bias voltage application terminal group based on an output from the differential amplifying means; or the first drive signal input terminal group; and adjusting circuit for adjusting the amplitude of the drive signal input to said second driving signal input terminals,
First dithering means for performing dithering on the amplitude of a drive signal input to the first drive signal input terminal group;
Second dithering means for performing dithering on the amplitude of the drive signal input to the second drive signal input terminal group;
A synchronous detection circuit for synchronously detecting the dither signal added by the first dithering means and the second dithering means or the harmonics of the dither signal from the electrical signal differentially amplified by the differential amplification means; ,
Have
The adjustment circuit includes a bias voltage applied to the first bias voltage application terminal group and the second bias voltage application terminal group, or the first drive signal based on a synchronous detection result by the synchronous detection circuit. An optical transmitter for adjusting an amplitude of a drive signal input to an input terminal group and the second drive signal input terminal group . The first dithering unit and the second dithering unit employs a dither signal of different frequencies,
The optical transmitter according to claim 1 . The first dithering unit and the second dithering means, using the dither signal of the same frequency, by performing a dithering in different periods respectively, to time-sharing a dither signal,
The optical transmitter according to claim 1 . Light branching means for branching the CW light output from the CW light source into the first CW light and the second CW light;
A first bias voltage application terminal group to which a bias voltage for adjusting an operating point or an internal optical phase is applied and a first drive signal input terminal group to which a drive signal is input; A first optical modulator that modulates and outputs CW light;
A second bias voltage application terminal group to which a bias voltage for adjusting an operating point or an internal optical phase is applied and a second drive signal input terminal group to which a drive signal is input; A second optical modulator for modulating and outputting CW light;
Polarization multiplexing means for polarization multiplexing and outputting optical signals output from the first optical modulator and the second optical modulator;
A first photodetector for monitoring the optical power of the optical signal output from the first optical modulator;
A second photodetector for monitoring the optical power of the optical signal output from the second optical modulator;
By differentially amplifying and outputting an electrical signal indicating the optical power monitored by the first photodetector and the second photodetector, intensity fluctuations superimposed on the CW light output from the CW light source are canceled out. Differential amplification means,
A bias voltage applied to the first bias voltage application terminal group and the second bias voltage application terminal group based on an output from the differential amplifying means; or the first drive signal input terminal group; An adjustment circuit for adjusting the amplitude of the drive signal input to the second drive signal input terminal group;
First dithering means for performing dithering on the bias voltage applied to the first bias voltage application terminal group or the amplitude of the drive signal input to the first drive signal input terminal group;
Second dithering means for performing dithering on the bias voltage applied to the second bias voltage application terminal group or the amplitude of the drive signal input to the second drive signal input terminal group;
A synchronous detection circuit for synchronously detecting the dither signal added by the first dithering means and the second dithering means or the harmonics of the dither signal from the electrical signal differentially amplified by the differential amplification means; ,
Have
The adjustment circuit includes a bias voltage applied to the first bias voltage application terminal group and the second bias voltage application terminal group, or the first drive signal based on a synchronous detection result by the synchronous detection circuit. input terminals and are inputted to the second driving signal input terminals to adjust the amplitude of the drive signal,
The first dithering means and the second dithering means respectively use dither signals having different first and second frequencies,
The differential amplifying means differentially amplifies an electric signal including dither components of the first and second frequencies . Light branching means for branching the CW light output from the CW light source into the first CW light and the second CW light;
A first bias voltage application terminal group to which a bias voltage for adjusting an operating point or an internal optical phase is applied and a first drive signal input terminal group to which a drive signal is input; A first optical modulator that modulates and outputs CW light;
A second bias voltage application terminal group to which a bias voltage for adjusting an operating point or an internal optical phase is applied and a second drive signal input terminal group to which a drive signal is input; A second optical modulator for modulating and outputting CW light;
Polarization multiplexing means for polarization multiplexing and outputting optical signals output from the first optical modulator and the second optical modulator;
A first photodetector for monitoring the optical power of the optical signal output from the first optical modulator;
A second photodetector for monitoring the optical power of the optical signal output from the second optical modulator;
By differentially amplifying and outputting an electrical signal indicating the optical power monitored by the first photodetector and the second photodetector, intensity fluctuations superimposed on the CW light output from the CW light source are canceled out. Differential amplification means,
A bias voltage applied to the first bias voltage application terminal group and the second bias voltage application terminal group based on an output from the differential amplifying means; or the first drive signal input terminal group; An adjustment circuit for adjusting the amplitude of the drive signal input to the second drive signal input terminal group;
Have
The differential amplification means includes
An attenuator for attenuating the electrical signal output from the first photodetector or the electrical signal output from the second photodetector;
When there is a difference in sensitivity between monitoring by the first photo detector and monitoring by the second photo detector , the optical transmitter reduces the difference in sensitivity by the attenuator. The first optical modulator or the second optical modulator is configured using a single Maha-Zehnder interferometer or a plurality of Maha-Zehnder interferometers.
The optical transmitter according to any one of claims 1 to 5 . Light branching means for branching the CW light output from the CW light source into the first CW light and the second CW light;
It has a bias voltage application terminal group to which a bias voltage for adjusting an operating point or optical phase is applied and a drive signal input terminal group to which a drive signal is input, and modulates and outputs the first CW light. An optical modulator;
A first photodetector for monitoring the optical power of the optical signal output from the optical modulator;
A second photodetector for monitoring the optical power of the second CW light;
By differentially amplifying and outputting an electrical signal indicating the optical power monitored by the first photodetector and the second photodetector, intensity fluctuations superimposed on the CW light output from the CW light source are canceled out. Differential amplification means,
An adjustment circuit that adjusts the bias voltage applied to the bias voltage application terminal group or the amplitude of the drive signal input to the drive signal input terminal group based on the output from the differential amplifier;
Having an optical transmitter. The optical modulator is configured using one Maha-Zehnder interferometer or a plurality of Maha-Zehnder interferometers.
The optical transmitter according to claim 7 .

Images