Field of the Invention
The invention relates to a tunable laser and a tuning method using the same.
Description of the Related Art
A typical Distributed Bragg Reflector (DBR) tunable laser, as shown in
In view of the above-described problems, it is one objective of the invention to provide a tunable laser and a tuning method using the same. The laser of the invention has wide tuning range and good performance The fabrication of the laser is easy to practice and the production cost of the laser is low.
To achieve the above objective, in accordance with one embodiment of the invention, there is provided a tunable laser. The tunable laser comprises: a gain section; a multi-channel splitter section; and a multi-channel reflection section, the multi-channel reflection section comprising multiple arms of unequal lengths. The gain section, the multi-channel splitter section, and the multi-channel reflection section are sequentially connected in that order. The gain section is configured to provide an optical gain for lasing. A facet of the gain section away from the multi-channel splitter section is an optical output facet of the laser. The multi-channel splitter section is configured to split an input signal into multiple outputs. The multi-channel reflection section is configured to provide an optical feedback and a mode selection function for the laser to work. When arranging the multiple arms of the multi-channel reflection section in an order according to their lengths, length difference between adjacent arms are unequal. Facets of the multiple arms away from the multi-channel splitter section are coated with reflection films. Arm phase sections are disposed on each of the multiple arms of unequal lengths for adjusting phases of the arms individually. A number of the multiple arms is equal to or greater than 3.
In a class of this embodiment, the laser further comprises a common phase section. The common phase section is configured to change a wavelength of a longitudinal mode of the laser and is connected between the gain section and the multi-channel splitter section.
In a class of this embodiment, the multi-channel splitter section adopts multi-mode interferometers (MMI), Y branches, or a star coupler.
In a class of this embodiment, a reflection spectrum dominated by a single main reflection peak is generated by aggregated reflections from the multi-channel reflection section to achieve single mode working.
In a class of this embodiment, in use, the length difference between adjacent arms are determined as follows: adjusting the length difference ΔLi between adjacent arms according to that when an average value of the length difference ΔLi tends to enlarge, a full width half maximum (FWHM) of the main reflection peak reduces thus suppression of the adjacent longitudinal modes is enhanced, while suppression of the other minor random reflection peaks is weakened, and that when the average value of the length difference ΔLi tends to reduce, suppression of the other minor random reflection peaks is enhanced, while the full width half maximum of the main reflection peak enlarges thus weakening suppression of the adjacent longitudinal modes; and optimizing the length difference between adjacent arms so as to suppress both the adjacent longitudinal modes and the other minor random reflection peaks to an appropriate level.
In a class of this embodiment, the lengths of the multiple arms are determined as follows: choosing one arm as a reference arm and setting an appropriate length for the reference arm; and setting lengths of other arms according to the length difference.
In accordance with another embodiment of the invention, there is provided a tuning method using the laser. The tuning method comprises coarse tuning of a working wavelength of the laser, the coarse tuning comprising: choosing one arm as the reference arm; and adjusting phases of other arms and enabling the phases of the other arms to be the same as a phase of the reference arm at a selected wavelength to locate the main reflection peak of the reflection spectrum at the selected wavelength and allow the laser to work in the vicinity of the selected wavelength.
In a class of this embodiment, the method further comprises fine tuning of the working wavelength of the laser, the fine tuning comprising: adjusting the phase of the reference arm; and readjusting the phases of other arms and enabling the phases of the other arms to be the same as the phase of the reference arm at the same selected wavelength to maintain a position of the main reflection peak of the reflection spectrum and align a position of the longitudinal mode position with the main reflection peak and to allow the laser to work at the wavelength selected.
In a class of this embodiment, the method further comprises: adjusting a phase of the common phase section to align the position of the longitudinal mode with the reflection peak at the selected wavelength to achieve the fine tuning of working wavelength of the laser.
In a class of this embodiment, adjustments of phases of the arm phase sections and the phase of the common phase section are fulfilled by injecting currents into corresponding phase sections.
Advantages of the tunable laser and the tuning method using the same according to embodiments of the invention are summarized as follows:
1. The laser of the invention does not use gratings to achieve mode selection. Moreover, when using arm phase sections, the laser is insensitive to the initial phases of the arms, which reduces the demands on high precision fabrication. Therefore, the fabrication of the laser only needs standard photolithography, thus potentially lowers the cost.
2. The reflection spectrum of the device is generated by the addition of the reflections from the multiple arms, so the loss of each arm suffered from current injection into the arm phase section is independent from each other. Moreover, currents injected into each arm are not always the highest. Therefore, when compared with using gratings, using the multi-channel reflection section of the laser of the invention to achieve mode selection has less influence from the losses induced by current injection into the arm phase sections for wavelength tuning.
3. When tuning wavelength of the present tunable laser, the phase change of each arm only needs to be adjusted to it at most. Moreover, the lengths of the arm phase sections can be made relatively long, which reduces the requirement on the capability of the phase sections for phase shift generations. Besides, using relatively long arm phase sections is able to reduce current density in the arm phase sections so as to reduce thermal effect due to current injection, which is beneficial to improve the speed of wavelength tuning.
4. The mode section filter of the present invention is on the same side of the gain section and the light outputs from the other side of the gain section, so the output light does not suffer from free carrier absorption caused by current injection, which makes the output light power keep stable across a large range of wavelength. Stable output power of the laser reduces the difficulty to control in the end.
The invention is described hereinbelow with reference to the accompanying drawings, in which:
In the drawings, the following reference numbers are used: 1. Gain section; 2. Common phase section; 3. Multi-channel splitter section; 4. Multi-channel reflection section; 5. Arm phase section; 6. High-reflection coating film; 7. Output facet of the laser; 8. 1×2 MMI; 9. S bends; 10. Electrode contact layer; 11. Cladding layer; 12. Upper optical confinement layer; 13. Active layer; 14. Lower optical confinement layer; 15. Optical waveguide layer; and 16. Electrode.
For further illustrating the invention, examples detailing a tunable laser and a tuning method using the same are described below. It should be noted that the following examples are intended to describe and not to limit the invention.
The working principle of the MCI laser of the invention is as follows:
A complex reflection coefficient calculated at a right side of the gain section is
where N is a number of the channels, λ represents a wavelength, j is an imaginary unit, r3 is a reflection coefficient of the rear facets of the N arms (assuming that the N HR-coated facets have the same reflection coefficients), Lp is a length of the common phase section, Lm is a propagation length in the multi-channel splitter section, Li (i=1,2,3 . . . N) is a length of the i-th arm, {tilde over (β)} is a complex propagation constant of a guided mode.
{tilde over (β)}=β−½jα (2)
where α is an intrinsic loss of passive waveguides, β is a propagation constant of the guided mode. For simplicity, it is assumed in equation (1) that the multi-channel splitter section splits the optical field into N equal fields, which is not necessary in reality and is decided by the components used to achieve the multi-channel splitter section. In order to attain a narrow strong reflection peak at the desired wavelength λ0, the round trip phases from the start of the common phase section to the end of each arm should be the same at wavelength λ0, which means that the phase difference between any two arms should be integral multiples of 2π. So the reflections of the N arms can achieve constructive interference at wavelength λ0, which generates a narrow strong reflection peak at wavelength λ0.
Although making the N arms in phase can generate a narrow strong reflection peak at λ0, the shape of the whole reflection spectrum, especially the suppression of the other relatively weak reflection peaks, is decided by the N−1 length difference of the N arms. Supposing that the lengths of the N arms are arranged increasingly, the length increase ΔLi between the i-th and (i+1)-th arm is
ΔLi=Li+1−Li, i=1,2,3 . . . N−1 (3)
So equation (1) is expressed by ΔLi as below:
As shown in equation (4), the common phase section, the N-channel splitter section and the length of the first arm can be treated as a part of the resonant cavity, which is reflected in the common phase tem e−2j{tilde over (β)}(L
After attaining an ideal reflection spectrum through optimizing the arm length difference, the lengths of the N arms are certain. The length differences between the other N−1 arms and the first arm which is selected to be the reference arm, can be calculated by the length difference.
Li+1−L1=ΔL1+ΔL2+ . . . +ΔLi, i=1,2,3 . . . N−1 (5)
Correspondingly the initial round trip phase differences can be written as
ΔΦi(λ)=2β(Li+1−L1)=2mi(λ)π+φ0i(λ)i=1,2,3 . . . N−1 (6)
As already mentioned, to attain a narrow main reflection peak at wavelength λ0, the N channels should be in phase at wavelength λ0. In reality, there are always phase errors expressed by φ0i(λ0) in equation (6), which makes the No. 2 to N channels out-of-phase with that of the first channel. Thus an independent arm phase section is included on each arm to adjust the phases of the No. 2 to N channels. By injecting currents into these arm phase sections, these phase errors can be eliminated so that the N channels can be in phase. Thus a narrow main reflection peak at wavelength λ0 is attained, which makes the longitudinal mode around λ0 lase. To make the longitudinal mode around λ1 lase, the phases of the No. 2 to N channels are required to be readjusted to make them in phase with the first channel at wavelength λ1. Therefore, the center wavelength of the main reflection peak moves from wavelength λ0 to wavelength λ1, which tunes the lasing wavelength from the longitudinal mode around λ0 to the longitudinal mode around λ1. For the MCI laser, the generation of the narrow main reflection peak and coarse tuning of the laser is achieved by adjusting the phases of the N−1 channels.
As mentioned above, the MCI laser of the invention uses multiple channels with unequal lengths to interfere with each other so as to generate a reflection spectrum dominated by a narrow reflection peak which therefore ensures the laser single mode working. Adjusting the phases of the N−1 arm phase sections can change the peak wavelength of the reflection spectrum so as to achieve coarse tuning of the MCI laser.
After coarse tuning, the position of the cavity longitudinal mode selected by the main reflection peak is adjusted so as to achieve fine tuning of the MCI laser.
Fine tuning of the MCI laser is realized in two ways: one way is to adjust the position of the selected longitudinal mode by adjusting the phase of the common phase section, which is similar to the fine tuning of the DBR type tunable lasers; another way is to control the total N arm phase sections at the same time. The second way is feasible because the first arm is actually a part of the resonant cavity. This means that if the first arm phase is now changed, the cavity longitudinal mode position can be adjusted, the same as adjusting the common phase section. The other N−1 channels have to be adjusted accordingly because they all have to be in phase with the first arm at the selected wavelength. So by adjusting the phases of the total N arms, both the cavity longitudinal mode position and the peak wavelength of the reflection spectrum are possibly adjusted. However, the second way of fine tuning causes the whole tuning strategy more complex because the fine tuning involves the adjustment of all N channels.
To demonstrate the feasibility of the MCI laser, the invention also presents design and simulation results of an eight-channel interference laser.
Tuning the eight-channel interference laser is through adjusting the eight arm phase sections simultaneously. Through solving the multi-mode rate equations, lasing spectra, SMSRs, threshold currents and L-I curves of the eight-channel interference laser are obtained.
The calculated L-I curve at 1550 nm is presented in
Unless otherwise indicated, the numerical ranges involved in the invention include the end values. While particular embodiments of the invention have been shown and described, it will be obvious to those skilled in the art that changes and modifications may be made without departing from the invention in its broader aspects, and therefore, the aim in the appended claims is to cover all such changes and modifications as fall within the true spirit and scope of the invention.
Number | Date | Country | Kind |
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2014 1 0704739 | Nov 2014 | CN | national |
This application is a continuation-in-part of International Patent Application No. PCT/CN2015/082342 with an international filing date of Jun. 25, 2015, designating the United States, now pending, and further claims foreign priority benefits to Chinese Patent Application No. 201410704739.0 filed Nov. 27, 2014. The contents of all of the aforementioned applications, including any intervening amendments thereto, are incorporated herein by reference. Inquiries from the public to applicants or assignees concerning this document or the related applications should be directed to: Matthias Scholl P.C., Attn.: Dr. Matthias Scholl Esq., 245 First Street, 18th Floor, Cambridge, Mass. 02142.
Number | Name | Date | Kind |
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5457760 | Mizrahi | Oct 1995 | A |
6614951 | Lin | Sep 2003 | B2 |
20060050747 | Trutna, Jr. | Mar 2006 | A1 |
Number | Date | Country | |
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20170163008 A1 | Jun 2017 | US |
Number | Date | Country | |
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Parent | PCT/CN2015/082342 | Jun 2015 | US |
Child | 15439907 | US |