The invention generally relates to photonic integrated circuits, and more particularly relates to an apparatus and method for an automated bias monitoring and control of an optical quadrature modulator.
Optical waveguide modulators used in high-speed optical communications, such as those based on waveguide Mach-Zehnder (MZ) interferometric structures, may require active control of their operating conditions, and in particular of their bias voltage that sets the relative phase of interfering light waves in the modulator in the absence of the modulation signal. The waveguides of the modulator are typically formed in an electro-optic material, for example a suitable semiconductor or LiNbOx, where optical properties of the waveguide may be controlled by applying a voltage. Such a waveguide modulator may be a part of an optical integrated circuit (PIC) implemented in an opto-electronic chip.
Very high speed optical systems may benefit from Quadrature Amplitude Modulation (QAM), which may be realized using a quadrature modulator (QM) that may be implemented using nested MZ interferometric structures. Such structures typically require controlling several bias voltages. For example, a QAM optical signal may be generated by splitting light from a suitable light source between two MZ modulators (MZM) driven by an in-phase (I) and a quadrature (Q) complements of an electrical QAM signal carrying data, and then combining the resulting I and Q modulated light signals in quadrature, i.e., with a 90°, or π/2 radians (rad), relative phase shift ϕIQ. For example the two MZMs of such QM may each be modulated by a BPSK (binary phase shift keying) signal while being biased at their respective null transmission points for push-pull modulation. When their outputs are added together in quadrature, i.e. with the relative phase shift ϕIQ=π/2, a QPSK signal (Quaternary phase shift keying) results. While the bias voltages of the two MZMz for the push-pull modulations may be controlled by monitoring the time-averaged optical power at the output of the modulator, the output averaged optical power is insensitive to the IQ phase shift ϕIQ, so that a drift of the bias voltage VIQ away from a bias point needed to maintain the desired IQ phase shift may be more difficult to monitor and correct for. Known techniques for monitoring the IQ phase shift ϕIQ in the modulator typically require high-bandwidth processing of the control signal, which is difficult to implement in practice.
Furthermore, existing feedback schemes that are used to control a set point of an optical MZ modulator typically require tapping off a small portion of the modulator output power to analyze for bias drifts. The tapped-off portion of the output power, although relatively small, should still be large enough in the conventional bias control techniques so that relatively small bias drifts may still be detected, which may measurably reduce the useful optical power from the modulator.
Accordingly, it may be understood that there may be significant problems and shortcomings associated with current solutions and technologies for controlling a bias point of an optical waveguide modulator suitable for use in high-speed optical systems.
Accordingly, one aspect of the present disclosure relates to an optical modulator device comprising:
(a) an optical modulator circuit (OMC) configured to modulate signal light at a target data rate and to produce modulated light, the OMC comprising a bias electrode configured to receive an electrical bias signal for controlling a modulator set point, and an optical tap port configured to provide tapped light indicative of the modulator set point;
(b) an optical mixer (OM) comprising a first optical port optically connected to the optical tap port of the OMC for receiving the tapped light and a second optical port for receiving reference light, the optical mixer configured to mix the reference light with the tapped light and to produce one or more mixed light signals each combining the reference and tapped light; and
(c) a photodetector (PD) circuit comprising one or more photodetectors (PDs) and configured to convert the one or more mixed light signals into one or more electrical feedback signals responsive to changes in the modulator set point.
One aspect of the present disclosure provides an optical waveguide modulator system comprising an optical waveguide modulator comprising a) an optical modulator circuit (OMC) configured to modulate signal light at a target data rate and to produce modulated light, the OMC comprising a bias electrode configured to receive an electrical bias signal for controlling a modulator set point, and an optical tap port configured to provide tapped light indicative of the modulator set point, b) an optical mixer (OM) comprising a first optical port optically connected to the optical tap port of the OMC for receiving the tapped light and a second optical port for receiving reference light, the optical mixer configured to mix the reference light with the tapped light and to produce one or more mixed light signals each combining the reference and tapped light; and c) a photodetector (PD) circuit comprising one or more photodetectors (PDs) and configured to convert the one or more mixed light signals into one or more electrical feedback signals responsive to changes in the modulator set point, the optical waveguide modulator system further including an electrical feedback circuit (EFC) connecting the PD circuit with the bias electrode and configured to generate the electrical bias signal in dependence on the one or more electrical feedback signals.
An aspect of the present disclosure provides a method to operate an optical modulator circuit (OMC) comprising an input port for receiving signal light, an output port for transmitting modulated light, a bias control port for receiving an electrical bias signal controlling a modulator set point, and a tap port for providing tapped light indicative of the modulator set point, the method comprising: a) mixing the tapped light with reference light of a greater power in an optical mixer to obtain one or more mixed light signals wherein the tapped light is combined with the reference light; and, b) using a PD circuit comprising one or more PDs to convert the one or more mixed light signals into one or more electrical feedback signals comprising information about the modulator bias.
In accordance with an aspect of the present disclosure, the method further includes c) generating the electrical bias signal in dependence on the one or more electrical feedback signals so as to maintain the modulator bias at a desired set point.
In accordance with one aspect of the disclosure, the method may be applied to the OMC that comprises a quadrature modulator configured to combine two modulated optical signals in quadrature, the quadrature modulator comprising a first optical phase shifter electrically coupled to the bias control port for varying an optical phase shift between the two modulated optical signals for setting the modulator bias. Step (a) of the method may then comprise obtaining first and second mixed light signals wherein the tapped light is added to the reference light with a phase shift that differs by 180□ between the first and second mixed signals, and step b) comprises differentially detecting the first and second mixed light signals to obtain a first differential PD signal, and rectifying the first differential PD signal to obtain the first electrical feedback signal.
Embodiments disclosed herein will be described in greater detail with reference to the accompanying drawings, which may be not to scale and in which like elements are indicated with like reference numerals, and wherein:
In the following description, for purposes of explanation and not limitation, specific details are set forth, such as particular optical circuits, circuit components, techniques, etc. in order to provide a thorough understanding of the present invention. However, it will be apparent to one skilled in the art that the present invention may be practiced in other embodiments that depart from these specific details. In other instances, detailed descriptions of well-known methods, devices, and circuits are omitted so as not to obscure the description of the present invention. All statements herein reciting principles, aspects, and embodiments of the invention, as well as specific examples thereof, are intended to encompass both structural and functional equivalents thereof. Additionally, it is intended that such equivalents include both currently known equivalents as well as equivalents developed in the future, i.e., any elements developed that perform the same function, regardless of structure.
Furthermore, the following abbreviations and acronyms may be used in the present document:
Note that as used herein, the terms “first,” “second” and so forth are not intended to imply sequential ordering, but rather are intended to distinguish one element from another, unless explicitly stated. Similarly, sequential ordering of method steps does not imply a sequential order of their execution, unless explicitly stated. The word ‘using’, when used in a description of a method or process performed by an optical device such as a polarizer or a waveguide, is to be understood as referring to an action performed by the optical device itself or by a component thereof rather than by an external agent.
The term “180° optical mixer” refers to an optical device that combines two input optical signals to produce two mixed optical signals wherein one of the two input optical signals is added to another of the two input optical signals with a phase offset of 180°, or in radian, therebetween. It will be appreciated that a 90° optical hybrid (OH) that is conventionally used in coherent optical detection schemes may be viewed as an example of a 180° optical mixer (OM) that produces two pairs of such counter-phase mixed optical signals with a 90° shift in the input signals phase offsets therebetween.
One aspect of the present disclosure relates to an optical waveguide modulator which must be suitably biased, or kept at a desired set point of its transfer characteristic, to have a desired modulation characteristic. The electrical signal that is required to maintain the desired modulator bias or set-point may be referred to herein as the bias electrical signal, and may be typically but not necessarily exclusively, in the form of dc bias voltage, which may be denoted Vb. In operation the modulator may experience changes in some of its properties, for example due to changes in its temperature or due to internal to modulator processes such as aging or impurity drift, which may cause the bias voltage that is required to maintain the desired set point to drift, resulting in a deterioration of one or more aspects of the modulator performance, and therefore necessitating a way to monitor that drift and to adjust the bias voltage accordingly. One way to accomplish that is to monitor the output optical signal from the modulator to detect the drift.
With reference to
The OMC 110 may conveniently be embodied using optical waveguides formed in or upon a support substrate of an electro-optic material, and may also be referred to herein as the optical waveguide modulator 110 or simply as the modulator 110. The OMC 110 is configured to modulate signal light 101 received by the OMC 110 at the input optical port 111 and to produce modulated light 121, which is transmitted from the main modulator output port 117. In some embodiments the modulated light 121 may carry useful data and be directed along a data path 128 of an optical communication system to an optical receiver at another end of an optical communication link. The bias control port 114 of the OMC 110 is configured to receive an electrical bias signal 143 for controlling the modulator set point. The output tap port 118 is configured to provide tapped light 123 indicative of the modulator set point. The tapped light 123 may be obtained, for example, by tapping off a small portion of the modulated light 121 at an output of the MOC 110. It may also be obtained by using an optical mixer at the output of the MOC 110 to produce both the modulated and tapped optical signals 121, 123. In some embodiments, the tapped light 123 may be tapped off at an intermediate location in the OMC 110.
in one embodiment the optical tap (not shown in
The OMR 130 has two optical ports, a first optical port 131 optically connected to the output tap port 118 of the OMC 110 for receiving the tapped light 123, and a second optical port 132 for receiving reference light 103, which may be also be referred to as the local oscillator (LO) light 103 or the amplifying light 103. The OMR 130 may include an optical mixer (OM) 133 configured to mix the reference light 103 with the tapped light 123 and to produce one or more mixed light signals each combining the reference and tapped light, and a photodetector (PD) circuit (PDC) 140 including one or more photodetectors (PDs) and configured to convert the one or more mixed light signals into one or more electrical feedback signals 141 responsive to changes in the modulator set point.
One advantage of mixing the tapped light 123 with the reference light 103 to obtain the electrical feedback signal or signals 141 is the ability to amplify the feedback signal when the optical power Pr of the reference light 103 received by the OMR at the reference input port 132 is greater than the tapped optical power Ps, i.e., the optical power of the tapped light 123 received by the OMR 130 at the signal input port 131. The OMR 130 may be configured so that the electrical feedback signal or signals 141, denoted herein generally as S, become substantially proportional to the square root of the product Pr·Ps of the tapped optical power Ps and the reference optical power Pr: S˜√(Pr·Ps), or to the power product itself: S˜Pr·Ps, or generally to a rising function of the product: S˜F{Pr·Ps}, where F{x} denotes a function of ‘x’ which value increases when ‘x’ increases.
Thus, by using a higher-power reference light 103, the electrical feedback signal or signals 141 at the output of the OMR 130 may be amplified relative to a direct detection scheme in the absence of a reference signal.
With reference to
With reference to
Advantageously, in embodiments wherein the insertion loss of the OMC 110 is not insignificant, tapping off a small portion of the input light 151 prior to the OMC 110 and mixing it with the tapped light 123 provides the ability to substantially amplify the feedback signal S 141 at the cost of only a small decrease in the useful optical power at the output of the OMC 110, i.e., the optical power of the modulated signal 121. By way of example, in an embodiment wherein the electrical feedback signal S is proportional to the product (Pr·Ps) and the insertion loss of the OMC 110 is 10 dB, tapping off 3% of the input light 151 to produce the reference light 103 and 1% of the modulated light 121 to produce the tapped light 123 would result in almost 10 dB gain in the feedback signal compared to an equivalent non-mixing tapped light detection scheme with a 4% tap at the output of the OMC 110, for the same small increase in the total insertion loss of the modulator system from the output of the optical source 152 to the signal output port 117 of the OMC 110.
With reference to
With reference to
Turning now to
In order to ensure proper operation of the QM 210, the IQ phase shift ϕIQ imposed by the first tunable optical phase shifter 116 should be set to a desired set-point value ϕIQ0. In example embodiments described hereinbelow, the desired set-point value ϕIQ0 of the IQ phase shift ϕIQ is equal substantially to π/2 rad, so as to ensure that the I and Q optical signals in the QM 210 are added in quadrature at the output of the QM 210; however, the particular desired value of the optical phase shift ϕIQ0 may differ in other embodiments, and all such values are within the scope of the present disclosure. The value of the IQ phase shift ϕIQ is controlled by an electric bias signal 199, which is provided at the control port 114 and which may be adjusted in operation in response to a drift in modulator properties so as to maintain the modulator at a desired set point ϕIQ=ϕIQ0.
In one embodiment the QM 210 may be configured as a QPSK modulator, with the optical modulators 112 in cooperation with the tunable optical shifter 116 producing two BPSK modulated I and Q optical signals, resulting in an equidistant QPSK symbol constellation at the QM outputs of when added with the IQ phase shift ϕIQ0=π/2.
Referring to
It will be appreciated that the method 300 illustrated in
Turning now to
J
diff,1
=R√{square root over (PrefPSig(t))}cos(Δϕ(t)) (1)
J
diff,2
=R√{square root over (PrefPSig(t))}sin(Aϕ(t)) (2)
Here Pref is the optical power of the reference light 103, Psig=Psig(t) is the optical power of the tapped light 123, and Δϕ(t) is the optical phase difference between the reference and tapped light at the point of combining, R is a proportionality coefficient that accounts for the PD conversion efficiency and possible gain in the summing circuits 136, and t denotes time. The differential PD signals Jdiff1 and Jdiff2 at the output of the differential summing circuits 136 will also be referred to herein as the I and Q electrical signals, respectively, and denoted as JI and JQ.
Turning now to
Turning now to
Referring now to
In operation input light 151 received into the input optical waveguide 401 is split by the tap 154 into the reference light 103 that is directed towards the second optical port of the OMR 230, and the signal light 101 that is coupled into the QM 210 to be modulated. The QM 210 outputs modulated light 121 and tapped light 123, with the former provided through the output waveguide 404 as the main output of the PIC modulator device 400, and the tapped light 123 guided into the first input optical port of the OMR 230. OMR 230 is configured to mix light 103 tapped off before the QM 210 and light 123 tapped off at the output of the QM 210 and to produce, from the mixed light, one or more electrical feedback signals 141, such as for example two quadrature electrical feedback signals 141a and 141b as described hereinabove with reference to
The EFC 280 may be configured to process the feedback signal or signals 141 and to generate therefrom the bias control signal 199 for controlling the bias voltage Vb that determines the IQ phase shift ϕIQ in the QM 210, and a reference control signal 198 for tuning the optical phase of the reference light 103 by means of the optical phase tuner 158. Accordingly, in one embodiment the EFC 280 may include a reference control circuit (RCC) 286 and a bias control circuit (BCC) 285 that are configured to process the feedback signal or signals 141 and to generate the reference control signal 198 and the bias control signal 199, respectively. The EFC 280 may implement a variety of control algorithms to track changes in the modulator set point and to ensure that the IQ phase shift stays approximately equal to the desired set-point value, such as π/2 rad in a typical embodiment. In one embodiment, the EFC 280 may be configured to vary the optical phase of the reference light 103 by varying the reference control signal 198 to the input optical phase tuner 154 while maximizing or minimizing a first electrical feedback signal 141a, and to tune the bias control signal 199 to vary the voltage Vb that controls the IQ phase shift so as to equalize two electrical feedback signals 141a and 141b. In one embodiment, the EFC 280 may be configured to vary at least one of the optical phase of the reference light 103 and the IQ phase shift in the QM 210 so as to equalize the electrical feedback signals 141a and 141b. Other embodiments of the control algorithm will become clear from the description hereinbelow.
Principles of operation of the EFC 280 may be understood by considering an embodiment wherein the QM 210 is an optical QPSK modulator wherein optical fields EI(t) and EQ(t) are added at the output with the phase shift ϕIQ to produce the tapped light 123, which is then coherently mixed with the reference light 103 in the OH 233, as illustrated in
E
1=(Esig+Eref) (3a)
E
2=(Esig−Eref) (3b)
E
3=(iEsig+Eref) (3c)
E
4=(iEsig−Eref) (3d)
where i=√−1, ESig=|ESig|exp(iϕSig) is the complex amplitude of the tapped light 123 in the OH 233, Eref=|Eref|exp(iϕref) is the complex amplitude of the reference light 123 in the OH 233. Assuming that the optical fields EI(t) and EQ(t) each have a phase that switches between 0 and π and a same real value amplitude, i.e.
|EI(t)|=|EQ(t)|=A, (4)
The complex amplitude ESig of the tapped light 123 may be described by a four-point constellation defined by the following two equations (2) and (3), see
The four values within brackets [ . . . ] in the RHS of equations (5) and (6) denote four possible values of the real-valued amplitude |ESig| (eq.6) and phase ϕSig (eq.5) of the optical field ESig(t) of the tapped light 123 that result from the BPSK modulation of the I and Q optical signals in the QM 210; JEref is the real-valued amplitude of the reference light 103 and ϕref is the optical phase thereof in the OH 133 relative to that of the tapped light 123, |x| denotes absolute value of ‘x’. The constellation described by equations (4) and (5) is illustrated in
The OH 233 combines the tapped light 123 with the reference light 103, and outputs the four different mixed optical signals wherein the tapped light is coherently mixed with the reference light with a phase shift n·π/2, with complex amplitudes defined by equations (3a)-(3d).
The in-phase (I) and quadrature (Q) electrical signals JI and JQ at the output of the differential summers 136 are given by equations (1) and (2) with PSig=|ESig(t)|2, Pref=|Eref(t)|2, and
Δϕ(t)=ϕSig(t)+ϕref, (7)
with ϕSig(t) and |ESig(t)| switching between four values given by equations (5) and (6). Generally, these signals depend on the IQ phase ϕIQ, and therefore are sensitive to its variations from the desired set-point value ϕIQ=π/2. However, it can be seen that these signals cease to depend on the IQ phase ϕIQ after averaging over a time Tavrg that is much greater than the duration Tsym of one BPSK symbol, which is defined by the inverse of the modulation data rate Rmod. By way of example, Rmod may be in the gigabit per second (Gb/s) range, for example 10-100 Gb/s.
Accordingly, the differential PD signals JI and JQ may be first rectified by the rectifying RF circuits 138 that operate at the modulation data rate Rmod if lower-speed electronics is to be used in EFC 280 to detect and track changes in the IQ phase ϕIQ. The OMR 230 therefore may include the rectifying RF circuits 138, for example in the form of high-speed squaring circuits, such as RF power detectors. Indeed, time-averaged power PI=<(JI)2> and PQ=<(JQ)2> of the differential PD signals JI and JQ may be described by the following equations (8) and (9):
P
I
=aP
Sig
P
ref·[1+cos(ϕIQ)·cos(ϕIQ−2ϕref)] (8)
P
Q
=aP
Sig
P
ref·[1−cos(ϕIQ)·cos(ϕIQ−2ϕref)]; (9)
they are sensitive to ϕIQ and therefore can be used as the feedback signals 141a and 141b by a lower-speed electronics in the EFC 280. Here a is a phase-independent multiplier coefficient that depends on the PD conversion efficiency and gain and/or efficiency parameters of the electrical circuitry following the PDs in the OMR 230. Equations (8) and (9) are obtained assuming that all QPSK symbols appear in the tapped signal 123 with equal frequency during the time of averaging.
From equations (8) and (9) it may be observed that the time-averaged signals PI and PQ are equal at the desired quadrature set point for the IQ phase shift in the QM 230, i.e. when
ϕIQ=π/2+π·m, (10)
and also when
ϕIQ=2ϕref+π/2+π·m, (11)
where m is an integer. The same may also hold for alternative embodiments of the rectifying circuits 138, for example when their output signals are proportional to absolute values of their inputs rather than squares thereof. Accordingly, in one embodiment the EFC 280 may be configured to compare outputs of the rectifying circuits 138 at frequencies significantly lower than the modulation data rate, e.g. the time-averaged RF powers PI and PQ of the differential PD signals JI and JQ, and adjust the bias control signal 198 so as to keep a feedback signal difference Δ=|PI−PQ| between them below a suitably small value.
Referring to
In one embodiment, the EFC 280 may further be configured to monitor the signal difference Δ while varying the reference control signal 198 to change the relative optical phase ϕref of the reference light 103, so as to ensure that the signal difference does not depend on the reference control signal and hence is independent on ϕref. A signal difference Δ=|PI−PQ| that stays substantially at zero while the reference control signal applied to the input optical phase shifter varies in a sufficiently wide range indicates that the IQ bias voltage VIQ in the QM 210 is equal substantially to Vπ/2, i.e. corresponds to the desired quadrature set point ϕIQ=π/2+π·m of the QM 210, as defined by equation (10).
Referring now to
In operation, the comparator 283 compares the averaged rectified first and second feedback signals 141a and 141b so as to evaluate a signal difference in the I and Q channels of the OMC 230, and communicates results to the decision module 284, which may signal to the bias control module 285 to adjust the IQ bias Vb in the QM 230 if the inputs to the comparator 283 is found to differ by more than a pre-defined error threshold e0. For example, the comparator 283 may output an error signal e that is proportional to the difference Δ between the average RF powers PI and PQ of the differential PD signals JI and JQ, e˜Δ=(PI−PQ), and the decision module 284 may send a signal to the bias control module 285 to change the IQ bias voltage Vb for adjusting ϕIQ if |e|>e0. If |e|<e0, the decision module 284 may keep the bias voltage Vb unchanged. In one embodiment, the reference control module 198 may be operable to vary the reference optical phase ϕref in a pre-defined range, such as by suitably varying the phase reference control signal 198, so as to ensure that the error signal e from the comparator 283 remains below the error threshold e0 for any reference phase value ϕref. By way of example the reference control module may be configured to vary the reference control signal 198 so that the error signal e is determined for a plurality of values of the reference phase ϕref that spans about 90°, or a fraction thereof. In one embodiment, the reference control module 286 may dither the reference phase ϕref using a suitable dither signal, and the decision module 284 may be configured to detect the dither signal, or a signature thereof, in the error signal e, and to vary the IQ bias voltage Vb so as to minimize the presence of the dither signal or its signature in the error signal at the output of the comparator 283.
Furthermore from equations (8) and (9) follows that the time-averaged signals PI and PQ both cease to dependent on the reference phase ϕref when equation (10) is satisfied, i.e. at the desired quadrature set point for the IQ phase shift in the QM 210. Accordingly, in one embodiment either one of the time-averaged I and Q electrical signals PT and PQ may be monitored while varying the relative optical phase of the reference light ϕref, and changing the bias control signal 199 to adjust the IQ phase shift ϕIQ if the monitored signal PI or PQ changes in dependence on the reference control signal 198 that controls the optical phase ϕref of the reference light 103.
Accordingly, embodiments wherein the rectifying circuits 138 of the OMR 230 are squaring circuits, for example are configured as RF power detectors, the EFC 280 may be configured to vary the optical phase of the reference light ϕref while monitoring a time average of one of the first and second electrical feedback signals from the outputs of the rectifying circuits 138, i.e. one of the average RF powers PT and PQ of the differential PD signals JI and JQ. The EFC 380 may then further be configured to adjust the bias control signal 199 so as to keep either one of the average RF powers PI or PQ substantially independent on the optical phase of the reference light ϕref. This may include for example using the first tunable optical phase shifter 116 to adjust the IQ phase shift ϕIQ in the QM 210 if the first electrical feedback changes in dependence on the optical phase of the reference light.
Referring to
Turning first to
Turning now to
In one embodiment, the bias control signal 199, for example the bias voltage Vb, may be modulated about a dc bias value <Vb> at a suitably low dither frequency fd. The EFC 280 may then be configured to vary a dc component <Vb> of the bias voltage in a predefined range so as to maximize a second harmonic of the dither frequency, i.e. 2fd, in the monitored signal PI or PQ. The second harmonic of the dither frequency, i.e. 2fd, in the monitored signal may be measured by filtering with a narrow-band filter 271 centered at 2fd.
Referring now to
Referring now to
P(t)=PI+PQ=2RPSigPref (9)
Accordingly, the OMR 230b of
The OMRs 130, 230, 230a, and 230b may be embodied in fully or partially in the same PIC chip as the respective OMC 130 or 230, or they may be embodied in a different chip. The EFCs 180 and 280 may be embodied using analogue electrical circuits or they may be embodied using suitably programmed digital processors, or using programmable hardware logic as known in the art. In embodiments using analogue electronics, the comparator 283 may be embodied using a differential amplifier, and the decision module 284 may be embodied using for example a PID control circuit as known in the art. Alternatively, functionalities represented by elements of the EFC shown in
Referring now to
The RF rectifier or rectifiers 138 may be embodied, for example, as one or more silicon or germanium pn-junction diodes, resistive, and capacitive elements. Referring to
Turning back to
The above-described exemplary embodiments are intended to be illustrative in all respects, rather than restrictive, of the present invention. Indeed, various other embodiments and modifications to the present disclosure, in addition to those described herein, will be apparent to those of ordinary skill in the art from the foregoing description and accompanying drawings. Thus, such other embodiments and modifications are intended to fall within the scope of the present disclosure. For example, it will be appreciated that semiconductor materials other than silicon, including but not limited to compound semiconductor materials of groups commonly referred to as A3B5 and A2B4, such as GaAs, InP, and their alloys and compounds, may be used to fabricate the PIC modulator device example embodiments of which are described hereinabove. In another example, although example embodiments described hereinabove may have been described primarily with reference to an optical waveguide QPSK modulator, it will be appreciated that principles and device configurations described hereinabove with reference to specific examples may be adopted to perform an automatic bias control of optical waveguide modulators of other types, including but not limited to multilevel optical QAM modulators. Furthermore, PIC modulator devices example embodiments of which have been described hereinabove, in other embodiments it may include other optical devices, such as for example, but not exclusively, optical amplifiers.
Although the theoretical description given herein is thought to be correct, the operation of the devices described and claimed herein does not depend upon the accuracy or validity of the theoretical description. That is, later theoretical developments that may explain the observed results on a basis different from the theory presented herein will not detract from the inventions described herein.
Any patent, patent application, patent application publication, journal article, book, published paper, or other publicly available material identified in the specification is hereby incorporated by reference herein in its entirety. Any material, or portion thereof, that is said to be incorporated by reference herein, but which conflicts with existing definitions, statements, or other disclosure material explicitly set forth herein is only incorporated to the extent that no conflict arises between that incorporated material and the present disclosure material. In the event of a conflict, the conflict is to be resolved in favor of the present disclosure as the preferred disclosure.
While the present invention has been particularly shown and described with reference to the preferred mode as illustrated in the drawing, it will be understood by one skilled in the art that various changes in detail may be affected therein without departing from the spirit and scope of the invention as defined by the claims.
Number | Date | Country | |
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Parent | 15381388 | Dec 2016 | US |
Child | 16517822 | US |