1. Field of the Invention
The present application relates to a method to drive a Mach-Zehnder modulator (hereafter denoted as MZ-modulator), in particular, the application relates to a method to drive a semiconductor MZ-modulator.
2. Related Background Arts
Many prior arts have disclosed an MZ-modulator that provides an input optical waveguide to guide an input optical beam, a branch to divide the input optical beam into two beams, a pair of phase modulators each coupled with the branch, an optical coupler to couple two beams each divided by the optical branch and propagated in the phase modulators into a composite optical beam, and an output optical waveguide to guide the composite optical beam. These members of the input optical waveguide, the optical branch, the phase modulators, the optical coupler, and the output optical waveguide, are monolithically integrated on a substrate. Each of the phase modulators has an equivalent refractive index different from others. The phase difference between optical beams each propagating in the phase modulators are given by (2n+1)×π, where n is zero or positive integers, under a condition of no modulation signal. That is, two optical beams each output from the phase modulators countervail to each other under such a condition, which results in no optical output from the MZ-modulator.
As the volume to be transmitted by the optical communication system explosively increases, an additional technique fundamentally different from the conventional magnitude modulation has been requested. The optical QPSK (Quadrature Phase Shift Keying) technique is one of the solutions for such requests. A transmitter operable in the QPSK mode includes a laser diode (LD) as an optical source and an optical phase modulator to modulate the optical beam emitted from the LD by the QPSK mode. The QPSK modulator is constituted by a pair of MZ-modulators. However, when the MZ-modulator is made of semiconductor material, various subjects to be solved have been known.
One aspect of the present application relates to a MZ-modulator made of semiconductor material. The MZ-modulator includes an optical branch, a pair of arm waveguides, a phase presetter, and an optical coupler. The optical branch divides an input optical beam into two optical beams each provided to respective arm waveguides. The phase presetter is put in one of arm waveguides, and varies a phase of the optical beam propagating therein by π. The optical coupler couples the optical beam propagating in the arm waveguide without the phase presetter with the other optical beam propagating in the other arm waveguide with the phase presetter. The arm waveguides are driven by modulation signals accompanied with biases. A feature of the MZ-modulator of the invention is that the modulation signals are complementary to each other with a swing range substantially same to each other and the biases are also substantially same to each other
Because the phase presetter shifts the phase of the optical beam propagating therein by π, the arm waveguide without phase presetter modulates the phase of the optical beam in a range from 0 to π responding to the modulation signal from V(0) to V(π); while, the arm waveguide with the phase presetter modulates the phase of the optical beam in a range from 2π to π responding to the other modulation signals with the opposite phase from V(2π) to V(π). Thus, two modulation signals have the swing range and the bias same to each other. According to the MZ-modulator of the present application, even the MZ-modulator is made of semiconductor material that inevitably shows the non-linearity of the phase variation against the bias provided thereto, the driving conditions may be simplified.
The phase pre setter provides an optical waveguide with an electrode, namely, an arrangement same with that of the arm waveguide. Providing a bias V(π), where V(π) means a voltage corresponding to the phase shift of an optical beam propagating therein by π, to the electrode, the equivalent refractive index of the optical waveguide is varied, which means that the optical length thereof varies and the phase of the optical beam passing therethrough is also varied. In an altered example, the phase presetter includes only an optical waveguide whose physical length is varied by a length corresponding to the phase shift of the optical beam propagating therein by π.
The foregoing and other purposes, aspects and advantages will be better understood from the following detailed description of a preferred embodiment of the invention with reference to the drawings, in which:
Next, some preferred embodiments according to the present invention will be described as referring to drawings. In the description of the drawings, numerals or symbols same or similar to each other will refer to elements same or similar to each other without overlapping explanations.
One of the outputs of the optical branch 103 couples with the first MZ-modulator 110 that modulates the optical beam Lin1 by the BPSK (Binary Phase Shift Keying) mode where the optical beam output from the first MZ-modulator 110 has two phase statuses of 0(rad) and π(rad) each corresponding to the bits “0” and “1”. Here, the phase statuses of 0(rad) and π(rad) are relative condition, and merely means that, assuming the phase status corresponding to bit “0” is 0(rad), the phase status for bit “1” is shifted by π(rad).
Specifically, the optical beam Lin1 output from the optical branch 103 is further divided into two optical beams, L11 and L12, by the optical branch 111, where the former optical beam L11 propagates within the optical waveguide 112; while, the latter optical beam L12 propagates in the optical waveguide 113. When the bit status “0” is required, a bias V11 to advance the phase of the optical beam L11 forward while another bias V12 to advance the phase of the other optical beam L12 backward are provided to respective electrodes, 115 and 116; which realizes the phase of 0(rad) in the composite optical beam. On the other hand, when the bit status “1” is required, the signal V11 to advance the phase of the optical beam L11 backward while the other signal V12 to advance the phase of the optical beam L12 forward are provided to respective electrodes, 115 and 116. Thus, the composite optical beam output from the MZ-modulator 110 shows the phase status of π(rad).
In an exemplary condition, when the bit status “0” is required, no biases are provided to the electrodes, 115 and 116, which maintains the phase of the optical beams, L11 and L12, same as that of the optical beam Lin1. While, when the bit status “1” is required, the signal V11 to advance the phase of the optical beam L11 forward by π(rad), while, the other signal V12 to advance the phase of the optical beam L12 backward by π(rad) are provided to respective electrodes, 115 and 116.
The other of the outputs of the optical branch 103 couples with the second MZ-modulator 120. The second MZ-modulator 120 also modulates the second optical beam Lin2 by the BPSK mode. That is, the optical beam Lin2 is further divided into two beams, L21 and L22, each propagating within the optical waveguides, 122 and 123. Two signals, V21 and V22, to advance the phases of two beams, L21 and L22, forward and backward, are provided to the electrodes, 125 and 126, respectively, when the bit status “0” is required. On the other hand, when the bit status “1” is required, signals, V21 and V12, to advance the phase backward and forward are provided to the electrodes, 125 and 126. The optical coupler 124 coupled with the waveguides, 122 and 123, merges two optical beams, L21 and L22, to form the composite optical beam.
The output of optical coupler 114 in the first MZ-modulator 110 directly couples with one of inputs of the optical coupler 130; while, the output of the optical coupler 124 in the second MZ-modulator 120 couples with the other of inputs of the optical coupler 130 via the phase shifter 140. The phase shifter 140, which includes an optical waveguide 141 and an electrode 142 provided on the optical waveguide 141, causes the phase shift by π/2(rad) for the composite optical beam passing therethrough by providing a bias V3 on the electrode 142.
The output of the optical coupler 130 is guided to the output terminal 102. The optical beams, L11 and L12, output from the optical coupler 114, and other two optical beams, L21 and L22, output from the phase shifter 140 are combined by the optical coupler 130 and output from the output terminal 102 as the optical output Lout modulated by the QPSK mode.
Then, the phase measured at the end E of the optical coupler 114, which is a composite of two beams, L11 and L12, shows two phase statuses of 0(rad) and π(rad); also, the phase measured at the end F of the optical couple 124 show two phase statuses of 0(rad) and π(rad), both of them have the configuration of BPSK mode.
The second MZ-modulator 120 accompanies with the phase shifter 140 in downstream thereof. Because the phase shifter 140 shifts the phase of the composite optical beam by π/2(rad), the phase measured at the output G of the phase shifter 140 becomes that shown in
The first and second MZ-modulators, 110 and 120, in particular, the waveguides, 112 to 123, provided therein are sometimes made of semiconductor material such as InP, GaAs, and so on because of large electro-optical effect inherently attributed to those materials. For instance, an optical waveguide including, what is called, the multiple quantum well (MQW) structure show large variation in the refractive index thereof by the quantum confined stark effect, which means that large phase shift may be obtained by applying relatively small bias to the waveguide. However, such large variation of the refractive index accompanies with large optical loss by the optical absorption.
A dielectric material such as lithium niobate (LiNbO3) is first considered, where LiNbO3 shows a linear dependence of the phase shift against the bias, exactly, the electric field applied thereto. When the optical waveguides, 112 and 113, are made of LiNbO3, a relation of the phase status against the biases is shown in
On the other hand, when the optical waveguides, 112 and 113, are made of semiconductor materials, which shows the non-linear dependence of the phase shift against the applied bias, the phase status of the composite beam becomes complicated such as shown in
Next, a first embodiment of an MZ-modulator according to the present invention will be described in detail.
The MZ-modulator 10 of the embodiment further provides the phase presetter 17 in only one of the arm waveguides, where the present embodiment provides the phase presetter 17 in the lower arm waveguide 13. The phase of the optical beam propagating in the arm waveguide 13 is further shifted by the signal applied to the phase presetter 17. In an example, the phase presetter 17 includes an optical waveguide made of semiconductor material, such as GaAs, InP, and so on, and an electrode to provide an electrical signal to the arm waveguide 13. Applying the signal to the electrode of the phase presetter 17; the phase of the optical beam propagating therein shifts by π(rad). In another example, the phase presetter 17 includes an optical waveguide without any electrodes, which is called as the supplemental waveguide. The supplemental waveguide lengthens the optical length of the arm waveguide 13 longer than that of the upper arm waveguide 12 by a length corresponding to a phase of π, which results in a phase shift of π(rad). However, the arrangement of the phase presetter 17 is not restricted to those described above. The phase shift by πbetween two optical beams propagating respective arm waveguides, 12 and 13, is the only one condition requested to the phase presetter 17.
The operation of the MZ-modulator 10 will be described. Entering an input optical beam Lin1 into the MZ-modulator 10, the input optical beam Lin1 is divided into two optical beams, L11 and L12, by the optical branch 11. One of the optical beams L11 enters the one of the arm waveguides 12, while, the other optical beam L12 enters the other arm waveguide 13, propagates therein, and enters the phase presetter 17. The phase presetter 17 causes the phase shift by π only for the optical beam L12. Thus, two optical beams, L11 and L12, are caused in the phase difference therebetween by π (rad) at the output of the phase presetter 17.
The optical beam L12 output from the phase presetter 17 further propagates in the arm waveguide 13 as shifting the phase thereof by the signal V12 provided to the electrode 16. On the hand, the other optical beam L11 propagates in the other arm waveguide 12 as shifting the phases thereof. When the composite optical beam output from the MZ-modulator 10 corresponds to the bit status “0”; two signals, V11 and V12, causing the phase difference of 0(rad) between two beams, L11 and L12, are provided to respective electrodes, 15 and 16. While, when the bit status “1” is required, two signals, V11 and V12, causing the phase shift by π (rad) relative to the phase status of 0(rad) above described are provided to the electrodes, 15 and 16.
As shown in
The MZ-modulator 10 of the present embodiment provides the phase presetter 17 to shift the phase of the optical beam passing therethrough by π, then, the optical beam L12 propagating in the lower arm waveguide 13 varies the phase thereof between π and 2π responding to the signal V12 swinging between V(π) and 0. On the other hand, the phase shift of the other optical beam L11 propagating in the upper arm 12 is between 0 and π for the signal V11 swinging between 0 and V(π). When two signals, V11 and V12, are complementary to each other, that is, when the signal V11 is in 0, then, the other signal V12 becomes V(π), the phase status of 0(rad) may be obtained for the composite optical beam. On the other hand, when the signal V11 becomes V(π), then, the other signal is set to be 0, the phase status of π(rad) may be realized in the composite optical beam.
The second MZ-modulator 30 is coupled with the other output of the optical branch 4. The second MZ-modulator 30 also provides the arrangement same with that shown in
The first MZ-modulator 20 couples directly with the optical coupler 5; while, the second MZ-modulator 30 couples indirectly with the optical coupler 5 via the phase shifter 40. The phase shifter 40 includes an optical waveguide 41 with an electrode 42. Providing a bias V3 to the waveguide 41 via the electrode 42, the optical beam passing therethrough shifts the phase thereof by π/2. Then, the optical beams, L21 and L22, modulated by the second MZ-modulator 30 further shifts the phase thereof by π/2 with respect to the phases of the optical beams, L11 and L12, modulated by the first MZ-modulator 20. The composite optical beam Lout merged by the optical coupler 5 and output from the optical output terminal 3 becomes the QPSK signal attributed with four phases of π/4, 3π/4, 5π/4, and 7π/4.
The QPSK modulator 1A shown in
The phase presetter 29 provides an optical waveguide 29a whose optical length is substantially equal to the phase shift of π. That is, the optical beam L12 propagating in the lower arm waveguide 23 and the phase presetter 29 always runs within the waveguide longer than the other waveguide 22 by a length corresponding to the phase shift of π, which also causes the phase shift by n between optical beams, L11 and L12, each propagating in the upper arm waveguide 22 and the lower arm waveguide 23. Similarly, the phase presetter 39 in the other MZ-modulator 30 shows the function same with that of the phase presetter 29. Accordingly, the optical beams, L21 and L22, each propagating within respective arm waveguides, 32 and 33, inevitably attribute the phase difference of π.
The QPSK modulator 1B of the present embodiment is also distinguishable from the aforementioned QPSK modulator 1A by the phase shifter 50. This phase shifter 50 includes an optical waveguide 50a to lengthen the optical length of the waveguide, which extends from the output of the optical coupler 34 to the input of the optical coupler 5, by a length corresponding to the phase shift of π/2. Then, the composite optical beam reaching the optical coupler 5 is shifted in the phase thereof by π/2 with respect to the composite optical beam reaching the optical coupler 5.
The QPSK modulator 1B includes the first and second MZ-modulators, 20 and 30, each having the configuration same with that of the MZ-modulator 10 shown in
The phase presetters, 29 and 39, and the phase shifter 30 of the present embodiment have an advantage that the increment of the optical loss by the application of the biases or the signals becomes avoidable. Thus, the degradation of the transmission quality due to the optical loss may be suppressed. The embodiment shown in
The phase presetter 60 includes an optical waveguide 60a to lengthen the optical length of the lower arm waveguide 33 between the optical branch 31 and the optical coupler 34 by a length corresponding to the phase shift of 3π/2. On the other hand, the phase presetter 61 provided in the upper arm waveguide 32 lengthens the optical length between the optical branch 31 and the optical coupler 34 by a length corresponding to the phase shift of π/2. Then, the composite optical beam output from the optical coupler 34 cause a phase shift by π/2 with respect to the composite optical beam output from the optical coupler 24. Moreover, the optical beam L22 propagating in the lower arm waveguide 33 causes the phase shift of π with respect to the optical beam L21 propagating in the upper arm 32.
Thus, the phase presetters, 29, 60, and 61, causes the phase offset of π/2, 2π/2, and 3π/2, between optical beams, L11 to L22. Accordingly, the composite optical beam output from the optical coupler 5 has the QPSK mode with the phase statuses of π/4, 3π/4, 5π/4, and 7π/4. The phase presetters, 29, 60, and 61, of the present embodiment have the arrangement to include the optical waveguides, 29a, 60a, and 61a, but some of them may include an electrode to modify the refractive index of the optical waveguide.
The optical length of the optical waveguides, 29a, 39a, 60a, and 61a, appeared in aforementioned embodiments may be determined as follows. That is, as shown in
Δφ=2×ΔL×neff/λ,
where neff is equivalent refractive index of the base semiconductor material. Assuming that the base semiconductor material is InP, namely, the MZ-modulator is made of InP, the equivalent refractive index neff is 3.3. Further assuming that the wavelength to be considered is 1550 nm, and the inclined angle is 45°, the supplemental length ΔL for the phase shift of π/2, 2π/2, and 3π/2 are given by 180 nm, 370nm, and 550 m, respectively.
While particular embodiments of the present invention have been described herein for purposes of illustration, many modifications and changes will become apparent to those skilled in the art. Accordingly, the appended claims are intended to encompass all such modifications and changes as fall within the true spirit and scope of this invention.
Number | Date | Country | Kind |
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2011-271356 | Dec 2011 | JP | national |