OPTICAL MODULATOR WITH AUTOMATIC BIAS CORRECTION

Abstract

An optical modulator uses an optoelectronic phase comparator configured to provide, in the form of an electrical signal, a measure of a phase difference between two optical waves. The phase comparator includes an optical directional coupler having two coupled channels respectively defining two optical inputs for receiving the two optical waves to be compared. Two photodiodes are configured to respectively receive the optical output powers of the two channels of the directional coupler. An electrical circuit is configured to supply, as a measure of the optical phase shift, an electrical signal proportional to the difference between the electrical signals produced by the two photodiodes.

Claims

1. A method, comprising: modulating, using a first phase modulator, a phase of a first optical signal in a first branch of a modulator to produce a modulated first optical signal; modulating, using a second phase modulator, a phase of a second optical signal in a second branch of the modulator to produce a modulated second optical signal; generating a first input signal and a second input signal based on the modulated first optical signal and the modulated second optical signal, respectively; and adjusting a first bias current and a second bias current of the first phase modulator and a second phase modulator based on an optical phase difference between the first input signal and the second input signal.

2. The method of claim 1, wherein adjusting the first bias current and the second bias current of the first phase modulator and the second phase modulator based on the optical phase difference between the first input signal and the second input signal comprises: receiving, at a first input of an optical directional coupler, the first input signal; receiving, at a second input of the optical directional coupler, the second input signal; generating a first output signal and a second output signal at output terminals of the optical directional coupler based on a difference in power between the first output signal and the second output signal; generating, by a control circuit coupled to the output terminals of the optical directional coupler, a first electrical output and a second electrical output based on the first output signal and the second output signal, respectively; and providing the first electrical output and the second electrical output to the first phase modulator and the second phase modulator, respectively.

3. The method of claim 2, wherein the optical direction coupler comprises a symmetrical optical directional coupler.

4. The method of claim 2, wherein the control circuit comprises a first photodiode configured to receive the first output signal, and a second photodiode configured to receive the second output signal.

5. The method of claim 4, further comprising reverse biasing the first photodiode and the second photodiode.

6. The method of claim 2, wherein the difference in power between the first output signal and the second output signal is indicative of the optical phase difference between the first input signal and the second input signal.

7. The method of claim 1, wherein the first phase modulator and the second phase modulator comprise a first phase modulation diode and a second phase modulation diode, respectively.

8. The method of claim 1, wherein at least one of the first phase modulator or the second phase modulator comprises a Mach-Zehnder modulator.

9. The method of claim 1, wherein generating the first input signal and the second input signal based on the modulated first optical signal and the modulated second optical signal, respectively, comprises: providing the modulated first optical signal to an input terminal of a first directional coupler; generating the first input signal at an output terminal of the first directional coupler; providing the modulated second optical signal to an input terminal of a second directional coupler; and generating the second input signal at an output terminal of the second directional coupler.

10. The method of claim 9, wherein the modulated first optical signal and the first input signal differ in phase, and wherein the modulated second optical signal and the second input signal differ in phase.

11. The method of claim 1, wherein generating the first input signal and the second input signal based on the modulated first optical signal and the modulated second optical signal, respectively, comprises: providing the modulated first optical signal to an input terminal of a first directional coupler; generating a first intermediate signal at an output terminal of the first directional coupler; providing the first intermediate signal to an input terminal of a second directional coupler; generating the first input signal at an output terminal of the second directional coupler; providing the modulated second optical signal to an input terminal of a third directional coupler; generating a second intermediate signal at an output terminal of the third directional coupler; providing the second intermediate signal to an input terminal of a fourth directional coupler; and generating the second input signal at an output terminal of the fourth directional coupler.

12. The method of claim 11, wherein the first intermediate signal and the first input signal differ in phase.

13. The method of claim 11, wherein a phase of the second intermediate signal is equal to a phase of the second input signal.

14. A method, comprising: adjusting, using a first phase modulator, a quiescent phase of a first optical signal in a first branch of a modulator based on a first bias current provided to the first phase modulator; adjusting, using a second phase modulator, a quiescent phase of a second optical signal in a second branch of the modulator based on a second bias current provided to the second phase modulator; generating a first input signal and a second input signal based on the first optical signal and the second optical signal, respectively, wherein a phase of the first input signal is indicative of the quiescent phase of the first optical signal, and wherein a phase of the second input signal is indicative of the quiescent phase of a second optical signal; and adjusting, using a pair of photodiodes, the first bias current and the second bias current based on an optical phase difference between the first input signal and the second input signal, wherein the adjusting reduces a phase difference between the quiescent phase of the first optical signal and the quiescent phase of the second optical signal.

15. The method of claim 14, further comprising reverse biasing each of the pair of photodiodes.

16. The method of claim 14, further comprising forward biasing the first phase modulator and the second phase modulator.

17. The method of claim 14, further comprising: providing the first input signal and the second input signal to an optical directional coupler; and generating a first output signal and a second output signal at output terminals of the optical directional coupler, wherein the first bias current and the second bias current are based on the first output signal and the second output signal, respectively.

18. The method of claim 17, wherein a difference in power between the first output signal and the second output signal is indicative of the optical phase difference between the first input signal and the second input signal.

19. The method of claim 14, wherein at least one of the first phase modulator or the second phase modulator comprises a Mach-Zehnder modulator.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0018] Other advantages and features will become more clearly apparent from the following description of particular embodiments provided for exemplary purposes only and represented in the appended drawings, in which:

[0019] FIG. 1, previously described, schematically shows an exemplary Mach-Zehnder interferometer (MZI) modulator as in the prior art.

[0020] FIG. 2 is a graph illustrating the transmission rate of the modulator of FIG. 1 as a function of the phase difference between the optical waves of the two branches.

[0021] FIGS. 3A through 3D represent different configurations of an MZI modulator combining different types of optical separation and junction units according to the invention.

[0022] FIG. 4 shows an embodiment of an optoelectronic regulation circuit adapted to a first MZI modulator configuration according to the invention.

[0023] FIG. 5 shows an alternative embodiment of the optoelectronic regulation circuit adapted to another MZI modulator configuration according to the invention.

[0024] FIG. 6 shows a detailed example of an optoelectronic regulation circuit according to the invention.

DETAILED DESCRIPTION OF THE EMBODIMENTS

[0025] A P-I-N diode of an MZI modulator, even if its bias current is zero, causes a nonzero optical phase delay, a residual phase shift. This residual phase shift depends on the characteristics obtained after manufacture, such as doping and dimensions. If the two PIN diodes of the modulator could be matched, they would provide the same residual phase shift, which would be offset by the differential structure of the modulator. However, the diodes PINPM, which are formed in optical waveguides, are large compared to diodes used for plain electronic functions, and located far apart from each other at the scale of a semiconductor chip. As a result, it is difficult to match these optical diodes, and unpredictable offsets that are too great to be neglected are generally observed between the residual phase shifts of the two diodes PINPM.

[0026] Despite an accurate adjustment of the bias currents, even in modulator configurations where the two diodes PINPM may have the same phase setting, the quiescent conditions drift with temperature. This drift may be explained by the fact that the rate of change of the phase shift as a function of temperature depends on the operating conditions of the diode PINPM. These operating conditions are generally not identical initially for the two diodes, whereby the phase shifts of the two diodes diverge when the temperature varies.

[0027] The HSPM diodes are also subject to difficulties in matching, but their structure is inherently less sensitive to variability of manufacturing processes. It is noted that the offset between the residual phase shifts of the two HSPM diodes, even after thermal drift, may remain within acceptable limits to be neglected.

[0028] FIGS. 3A through 3D show configurations of MZI modulators differing by combinations of separation and junction units requiring different bias conditions for the diodes PINPM. The structures of the two branches of the modulators are unchanged from FIG. 1.

[0029] FIG. 3A corresponds to the configuration of FIG. 1, already described. The separation unit S1 is a Y-separator and the junction unit J1 is a symmetric directional coupler. Separator S1 maintains the phase of the input optical wave on both outputs, whereas the coupler J1 requires a phase difference of 180 to be in the center of its dynamic range, the desired quiescent condition. Thus, diodes PINPM1 and PINPM2 are biased to introduce an initial phase shift of 180 between the inputs of the coupler J1.

[0030] The two waves exiting the coupler J1 are in phase quadrature, but their phase difference with respect to the input waves is variable depending on the characteristics of the input waves.

[0031] In FIG. 3B, the output directional coupler J1 has been replaced by a Y-combiner J2. Such a combiner transmits 50% of the optical power when the waves at its two inputs are in phase quadrature. The two waves arriving at the diodes PINPM being in phase, the diodes PINPM are biased to introduce the desired phase difference of 90 between the two waves. E.g. the diode PINPM1 is biased to introduce a phase delay of 90 and the diode PINPM2 receives a zero current, corresponding theoretically to a null phase delay. In practice, the diode PINPM2 introduces a residual phase delay at zero bias current, which is difficult to predict, for example 1. In that case, the diode PINPM1 is biased for introducing a phase delay of 90+1=91.

[0032] The configuration of FIG. 3B may be preferred to that of FIG. 3A, because the diode PINPM1 causes less absorption losses than in FIG. 3A. Indeed, a greater phase delay is obtained in FIG. 3A by injecting more charge in diode PINPM1, and absorption losses increase with the number of charges.

[0033] In FIG. 3C, the Y-separator S1 of FIG. 3A has been replaced by a symmetrical directional coupler S2. The input optical wave is applied to one of the channels of the coupler, for example the lower one. In that case, the wave exiting the upper channel of the coupler is delayed by 90 relative to the wave exiting the lower channel. The output coupler J1 requiring a phase difference of 180 to operate in the desired quiescent conditions, it is sufficient that the diode PINPM1 introduce a phase delay of 90 that is added to the delay of 90 introduced by the upper channel of the input coupler S2.

[0034] The absorption losses of the configuration of FIG. 3C are similar to those of FIG. 3B.

[0035] In FIG. 3D, the output directional coupler J1 of FIG. 3C has been replaced by a Y-combiner J2. The input coupler S2 directly produces the phase quadrature desired for the quiescent conditions, between the waves input to the combiner J2. Thus, the diodes PINPM need not introduce additional phase delay. In this case, the two diodes PINPM may be biased at zero current, in theory. This configuration therefore provides the best performance in terms of absorption losses.

[0036] Because the two diodes PINPM operate in similar conditions, this configuration also offers the best performance in terms of thermal drift.

[0037] In practice, the diode PINPM having the highest residual phase delay may be biased at zero current, while the other diode PINPM is biased with a current sufficient to balance the residual phase delay. As it is difficult to know in advance which of the two diodes PINPM has the highest residual phase delay, it is preferred to bias both diodes with non-zero currents, one fixed and one adjustable.

[0038] FIG. 4 shows an embodiment of an optoelectronic circuit for regulating the quiescent conditions of an MZI modulator. The MZI modulator has a configuration similar to that of FIG. 3D. With respect to FIGS. 3A to 3D, the positions of the diodes PINPM have been interchanged with those of the HSPM diodes, so that the diodes PINPM are the first elements in the two branches of the modulator, and are part of a control loop. The HSPM diodes are not included in the loopas mentioned earlier, the drifts of the HSPM diodes may be neglected.

[0039] The optoelectronic regulation circuit, whose principles may be applied to various MZI modulator configurations, such as those illustrated in FIGS. 3A to 3D, measures the optical phase difference between the waves in the two branches of the modulator, and provides the error relative to a desired value in the form of optical power received by photodiodes PD1, PD2. The electrical signals provided by the photodiodes are exploited to vary the bias currents of the diodes PINPM in a direction tending to reduce the error.

[0040] The measurement of the phase difference may be achieved using a symmetrical optical directional coupler DC0 receiving, on its two channels, optical waves derived from the two branches of the modulator. The paths of the derived optical waves are configured so that the phase difference at the input of the coupler DC0 equals 180 when the phase difference between the derived optical waves corresponds to that desired at the input of the junction unit. Under these conditions, the coupler DC0 outputs at each of its channels 50% of the total optical power received. If the phase difference is not equal to 180, one of the channels provides more than 50% of the power, while the other channel provides the complement. The optical waves at the outputs of the two channels of the coupler are provided to two respective photodiodes PD1, PD2. Thus, the difference between the electrical signals generated by the photodiodes represents the optical phase error.

[0041] In FIG. 4, more specifically, the optical outputs of diodes PINPM1 and PINPM2 are provided to the first channels of two respective asymmetric directional couplers DC1 and DC2. The outputs of these first channels are provided to diodes HSPM1 and HSPM2 respectively.

[0042] The couplers DC1 and DC2 are asymmetrical in that the optical power received in the first channel is distributed asymmetrically between the outputs of the first and second channels, for example 98% at the output of the first channel, and 2% at the output of the second channel. The fraction of the output power in the second channel is chosen to be detectable by a photodiode in good conditions.

[0043] The optical waves output by the second channels of the couplers DC1 and DC2 have respective phase delays of 180 and 90 relative to the optical wave input to the modulator (each of the couplers DC1 and DC2 introduces a phase delay of 90 as the wave passes from the first channel to the second). The phase difference between these waves is thus 90 while the coupler/comparator DC0 requires 180. A symmetrical directional coupler DC3 is provided to add the missing 90 phase delay to the 180 optical wave. The coupler DC3 receives in its first channel the 180 wave and provides a 270 wave from its second channel to the upper channel of coupler/comparator DC0.

[0044] A directional coupler DC4 is provided to equalize the optical paths leading to the coupler/comparator DC0. Its first channel connects the coupler DC2 to the lower channel of the coupler DC0, without introducing a phase delay.

[0045] The outputs of the first and second channels of the coupler/comparator DC0 are respectively sensed by the photodiodes PD1 and PD2. These photodiodes are part of an electrical control circuit 10 configured to adjust the bias currents of the diodes PINPM according to the difference between the sensed optical powers. In this modulator configuration, the bias currents are substantially the same, since the diodes PINPM are designed to introduce the same phase delay (as close to 0 as possible.)

[0046] The regulator circuit of FIG. 4 is also usable, as is, in the modulator configuration of FIG. 3B.

[0047] FIG. 5 shows an alternative of the optoelectronic regulation circuit, integrated with an MZI modulator of the type of FIG. 3C. The same elements as in FIG. 4 are designated by the same references. The diode PINPM1 is biased here for introducing a phase delay of 90, so that the second channel of the coupler DC1 provides an optical wave delayed by 270. The second channel of the coupler DC2 still provides a wave delayed by 90. The phase difference between these waves is 180, whereby the two waves may be directly applied to the inputs of the coupler/comparator DC0.

[0048] The configuration of FIG. 5 is simpler than that of FIG. 4 in that it uses two directional couplers less.

[0049] The regulator circuit FIG. 5 is also usable, as is, in the modulator configuration of FIG. 3A.

[0050] FIG. 6 shows a detailed example of electronic circuitry of the optoelectronic regulation circuit 10. The photodiodes PD1 and PD2 are reverse biased by two resistors R1 and R2. The cathodes of diodes PD1 and PD2 are connected respectively to a non-inverting input and an inverting input of a differential transconductance amplifier 20. The diodes PINPM1 and PINPM2 are forward biased by respective constant current sources Ib1 and Ib2. The anodes of diodes PINPM1 and PINPM2 are connected to forward and reverse outputs of the amplifier 20.

[0051] The currents Ib1 and Ib2 are set by design to the typical values required to introduce the quiescent phase difference corresponding to the modulator configuration (180 for FIG. 3A, 90 for FIGS. 3B and 3C, and 0 for FIG. 3D). In theory, one of the currents (Ib2) may be zero. In practice, the two currents are non-zero, so that each has a margin of adjustment. Current Ib2 is selected, for example, to introduce a phase delay of 5. Then, the current Ib1 is selected to introduce a phase delay of 185 in FIG. 3A, 95 in FIGS. 3B and 3C, and 5 in FIG. 3D.

[0052] When the phase difference between the input waves of coupler/comparator DC0 is 180, each of the photodiodes PD1 and PD2 receives the same optical power, 50% of the power received by the coupler/comparator DC0. If the photodiodes are matched, which is easier to achieve than for diodes PINPM, their cathode voltages stand at identical values. Thus, the amplifier 20 sees a zero input voltage and does not influence the bias currents of the diodes PINPM.

[0053] If the phase difference between the input waves of coupler/comparator DC0 drops below 180, it means that the delay introduced by the diode PINPM1 decreases or the delay introduced by the diode PINPM2 increases. The optical power received by photodiode PD1 increases, and the optical power received by the photodiode PD2 decreases. The cathode voltage of the photodiode PD1 increases and that of the photodiode PD2 decreases. The amplifier 20 sees its differential input become positiveit injects a proportional current in the diode PINPM1 and subtracts a proportional current from the diode PINPM2. The diode PINPM1 increases its phase delay while the diode PINPM2 decreases its phase delay.

[0054] A symmetrical behavior is obtained when the phase shift between the waves becomes greater than 180.

[0055] An automatic correction is thus obtained for the quiescent phase errors in the modulator. This correction is independent of the nature of the errorthe error may be due to a temperature drift, a poor matching between the diodes PINPM, a poor initial choice of the bias currents, or any other cause. The accuracy of the correction depends on the open loop gain of the control loop, which may be easily adjusted by way of amplifier 20.

[0056] The accuracy also depends on the parasitic offset referred to the input of the amplifier, caused for instance by a mismatch between the photodiodes or a lack of precision in the coupling coefficient of each of couplers DC0, DC1 and DC2. Such an offset may be compensated electrically by techniques known in the field of differential amplifiers.