The present invention relates to the field of integrated photonic waveguides, and more particularly concerns a polarization rotator assembly for rotating a polarization mode of an electromagnetic signal propagating therealong.
Over the past decade, integrated photonics has made important progress in implementing optical and electro-optical devices in silicon for use in various technological applications in fields such as telecommunications, sensing and signal processing. Integrated photonic relies on optical waveguides to implement devices such as optical couplers and switches, wavelength multiplexers and demultiplexers, and polarization splitters and rotators. In particular, integrated photonics based on silicon is a promising candidate for compact integrated circuits due to its compatibility with silicon electronics and standard complementary metal-oxide-semiconductor (CMOS) fabrication methods. The high refractive index contrast between the silicon core and silicon dioxide enables the propagation of highly confined optical modes, which allows scaling integrated photonic waveguides down to submicron level.
One consequence of this high refractive index contrast is that integrated silicon photonic waveguides experience large modal structural birefringence between the two orthogonal transverse electric (TE) and transverse magnetic (TM) fundamental modes of the guided light. Because of this birefringence, integrated photonic waveguides typically exhibit a polarization-dependent behavior. Moreover, since silicon photonic waveguides generally have submicron dimensions and very stringent fabrication tolerance requirements, completely eliminating structural birefringence can prove to be an extremely demanding task.
In order to achieve polarization-independent performance, one may implement a polarization diversity scheme. Generally, polarization diversity is accomplished by using polarization splitters and rotators. In this approach, the two orthogonal TE and TM polarization modes are split in two distinct paths of a polarization diversity circuit. By further rotating the polarization state in one of the paths of the polarization diversity circuit to the orthogonal polarization state, the two paths may be operated in parallel on identical high refractive index contrast waveguide structures. For example, in fundamental-mode silicon waveguides having a certain width and height, it is generally desired to convert the TM polarized signal into a TE polarized signal. Then, as a result of this conversion, only optical functions for the TE modes need to be fabricated and polarization dependence may be eliminated or reduced by using a single polarization (i.e. TE) implementation.
In order for the polarization diversity approach to be practical, on-chip polarization splitters and rotators are desired. However, designing and fabricating integrated waveguide-type polarization rotators can be challenging.
U.S. Pat. No. 7,792,403 to Little et al. (hereinafter LITTLE) discloses a waveguide structure that includes a polarization rotator for rotating the polarization of an electromagnetic signal, preferably by about ninety-degrees. In general, the polarization rotation of the electromagnetic signal by the polarization rotator disclosed in LITTLE is achieved via the geometrical parameters of the polarization rotator. In one embodiment (see, e.g.,
Waveguide structures such as the one shown in LITTLE can be subject to stringent fabrication tolerances. In particular, it is desirable for the electromagnetic signal to reach the polarization rotation portion in the TM polarization mode in order to be properly rotated. However, vertical taper shapes used to transition between waveguides of different heights can be particularly sensitive to mask alignment during fabrication, and fabrication errors can lead to an undesired pre-rotation of the polarization mode of the guided electromagnetic signal.
There therefore exists a need in the art for an improved polarization rotator assembly for rotating the polarization of light in silicon-based photonic integrated circuits.
In accordance with one aspect of the invention there is provided a polarization rotator assembly for rotating a polarization mode of an electromagnetic signal.
The polarization rotator assembly includes a waveguiding structure having co-extensive first and second layers. The waveguiding structure has a first height corresponding to the first layer and a second height corresponding to a superposition of the first and second layers. The waveguiding structure has a waveguiding axis and includes successively therealong:
Embodiments of the invention may be particularly well adapted for use in submicron silicon-based, fundamental-mode waveguide structures exhibiting polarization-dependent characteristics arising from the large structural modal birefringence between the TE and TM fundamental modes.
Other features and advantages of the invention will be better understood upon reading of preferred embodiments thereof with reference to the appended drawings.
In accordance with an aspect of the invention, there is provided a polarization rotator assembly. The polarization rotator assembly allows rotating a polarization state or mode of an electromagnetic signal as the electromagnetic signal propagates therethrough.
Polarization rotator assemblies according to embodiments of the invention can be generally useful in silicon-based integrated photonics or other high index contrast photonics applications, preferably as part of on-chip polarization-diversity circuits implemented for eliminating the polarization dependence in devices based on photonic waveguides. In particular, embodiments of the invention may be particularly well adapted for use in submicron silicon-based, fundamental-mode waveguide structures exhibiting polarization-dependent characteristics arising from the large structural modal birefringence between the TE and TM fundamental modes. In such embodiments, the polarization rotator assembly is preferably operatively configured to rotate the polarization of an electromagnetic signal by ninety degrees. More precisely, to convert a TM polarized signal to its orthogonal counterpart, namely a TE polarized signal or vice versa. The electromagnetic signal may be a telecommunication signal encoded with information according to one of many known modulation schemes or may be embodied by any other optical beam whose polarization is to be rotated. It will be readily understood that polarization rotator assemblies as described herein may be used in different contexts than those mentioned above without departing from the scope of the present invention.
Referring to
The polarization rotator assembly 20 first includes a waveguiding structure 21, which is substantially planar and includes two co-extensive layers 22 and 24. The waveguiding structure 21 allows guiding of an electromagnetic signal along a waveguiding axis 36. The thickness profile of the waveguiding structure is characterized by a first height h1, corresponding to the first layer 22, and a second height and h2, which correspond to the superposition of the first and second layers 22 and 24. The first and second layers 22 and 24 therefore define a level difference Δh=h2−h1 therebetween. The heights h1 and h2 may be selected so that the ratio of h2 and h1 is of the order of two. Additionally or alternatively, the heights h1 and h2 may be selected so as to achieve substantially fundamental-mode (e.g. TE and TM) operation for a given waveguide width.
It will be understood that the first and second layers 22 and 24 form the core of the waveguiding structure 21, inside which the electromagnetic signal is guided. In the illustrated embodiment, the waveguiding structure 21 is a strip waveguide, but other appropriate structures could be used in other embodiments including a ridge waveguide and a rib waveguide. The core material forming the first and second layers 22 and 24 is preferably silicon having a refractive index of about 3.5 at a wavelength of 1.55 μm, but other core materials could be envisioned including silicon nitride, silicon carbide, indium phosphide, gallium arsenide, high-index polymers and the like. In some embodiments both the first and second layers may be made of a same material, whereas in other embodiments they may each be made of different ones of the materials listed above.
The first and second layers 22 and 24 of the polarization rotator assembly 20 may be defined using any common, preferably CMOS-compatible, photolithographic processes. As known in the art, such processes may involve thin-layer deposition, selective photoresist mask etching and patterning, and oxidation. For example, the polarization rotator assembly 20 may be formed using two masks and two etching steps. Optionally, a cladding material (not shown) may be deposited over the polarization rotator assembly 20. The cladding material is preferably silicon dioxide (silica) having a refractive index of 1.45 at a wavelength of 1.55 μm, but other appropriate materials could alternatively or additionally be used.
Broadly described, the waveguiding structure 21 of the polarization rotator assembly 20 illustrated in
In operation, an electromagnetic signal propagating along the propagation axis 36 preferably enters the polarization rotator assembly 20 via the input waveguide portion 26, which defines section A of the polarization rotator assembly 20. Preferably, the electromagnetic signal is already polarized into one of the TM and TE polarized modes upon entering the input waveguide portion 26. As known in the art, in a polarization diversity scheme, the TE and TM polarization may first be spatially separated in two different waveguides. One of the TE and TM polarized signals may then be rotated through ninety degrees to yield two parallel circuits propagating in the same polarization mode. For example, the polarization rotator assembly 20 shown in
The geometrical parameters of the input waveguide portion 26 (e.g. height and width) may be selected to ensure substantially single-mode propagation along the polarization rotator assembly 20 and to facilitate matching between the polarization rotator assembly 20 and other connecting waveguide elements disposed on the upstream side thereof. In the example of
With continued reference to
As used herein, the term “subwavelength” refers to the fact that the size of the characteristic features or inhomogeneities (typically, corrugation periodicity) of the subwavelength pattern are markedly smaller than half of the wavelength of the electromagnetic signal propagating thereinside. When the wavelength of the electromagnetic signal propagating within the subwavelength composite portion is large compared to the characteristic feature size thereof, the structure can be treated as an effective homogeneous material. This condition is generally met when the characteristic feature size of the subwavelength pattern (typically the periodicity of the corrugations) is less than half the wavelength of the electromagnetic signal propagating therein.
In the illustrated embodiment of
It will be understood that, in this embodiment, the characteristic feature size of the subwavelength pattern corresponds to the length of one corrugation 38a and one adjacent gap 38b, the sum of which represents the period of the pattern. Hence, in order for the pattern to be considered “subwavelength”, the transverse size and separation of corrugations should be on a subwavelength scale along the length of the subwavelength composite portion 28, to ensure that resonance and filtering effects typically observed with Bragg gratings or other periodic structures are suppressed. The subwavelength composite portion 28 therefore acts as a homogeneous medium with an effective refractive index whose value is between those of the corrugations (e.g. core material) and the separation between them (e.g. air or cladding material).
The subwavelength pattern may be formed by selective etching or deposition of the second layer 24. In the illustrated embodiment of
It is to be noted, however, that the subwavelength pattern of the subwavelength composite portion 28 need not be periodic, as long as the characteristic feature size thereof remains below the diffraction limit. By way of example,
Additionally, the subwavelength pattern may be defined by features differing from the transversally disposed series of gaps and corrugations illustrated in
Referring back to
Optionally, the subwavelength pattern may include a wedge-shaped section 29 forming a longitudinally widening taper along the waveguiding axis 36, shown in section B of the illustrated embodiment of
It will thus be understood that the subwavelength composite portion 28 advantageously acts as a vertical mode converter between two waveguide elements defining a level difference Δh therebetween. In addition, the polarization of the electromagnetic signal propagating in the subwavelength composite portion 28 remains substantially unaffected by fabrication tolerance issues since the polarization rotation is negligible therealong.
Still referring to
Referring to
Referring back to
The polarization rotator portion may have any configuration which allows the rotation of at least one polarisation mode of the electromagnetic signal propagating in the waveguiding structure 21. In the illustrated embodiment of
Preferably, the polarization rotation portion 32 is configured to rotate the polarization of the electromagnetic signal by ninety degrees. Further preferably, the polarization rotation portion 32 is configured to convert a TM polarized signal to TE polarized signal which is its orthogonal counterpart or vice versa.
In the embodiment shown in
Referring to
Of course, numerous examples of polarization rotating structures based on similar principles can be found in the art.
Finally, waveguiding structure 21 of the polarization rotator assembly 20 preferably includes the output portion 34 for receiving the electromagnetic signal exiting the polarization rotating portion. The output portion 34 defines the section F of the illustrated polarization rotator assembly 20. As with the input portion 26, the geometrical parameters of the output waveguide portion 34 (e.g. height and width) may be selected to ensure substantially single-mode propagation along the polarization rotator assembly 20 and to facilitate matching between the polarization rotator assembly 20 and other connecting waveguide elements disposed on the downstream side thereof. In the embodiment of
One skilled in the art will understand that the enclosed drawings are not drawn to the typical scale of such devices. The polarization rotator assembly may have dimensions and proportions according to requirements and limitations of a particular application. For example, polarization rotators assembly having a configuration similar to the one shown in
It will be understood that the polarization rotator assembly 20 according to embodiments of the invention is generally reciprocal, that is, the electromagnetic signal could alternatively enter and exit the polarization rotator assembly 20 via the output and input waveguide portions 34 and 26, respectively, thus going through a reverse polarization rotation. Similarly, the polarization rotator assembly 20 may also be used to convert a TE polarized signal to a TM polarized signal.
By combining a subwavelength composite portion acting a vertical mode converter with a two-level adiabatic polarization rotating portion, embodiments of the present invention may provide a polarization rotator assembly 20 exhibiting a reduced sensitivity to mask misalignment and other fabrication tolerance issues.
Of course, numerous modifications could be made to the embodiments described above without departing from the scope of the present invention.
Number | Name | Date | Kind |
---|---|---|---|
7075722 | Nakai | Jul 2006 | B2 |
7792403 | Little et al. | Sep 2010 | B1 |
8750651 | Chen | Jun 2014 | B2 |
20120183250 | Cheben et al. | Jul 2012 | A1 |
Entry |
---|
Bock et al., Sub-wavelength grating mode transformers in silicon slab waveguides, Optical Society of America, Oct. 12, 2009 / vol. 17, No. 21 / Optics Express p. 19120-19133. |
Cheben et al., Subwavelength waveguide grating for mode conversion and light coupling in integrated optics, Optical Society of America, May 29, 2006 / vol. 14, No. 11 / Optics Express, p. 4695-4702. |
Dai et al., Novel concept for ultracompact polarization splitter-rotator based on silicon nanowires, Optical Society of America, May 23, 2011 / vol. 19, No, 11 / Optics Express, p. 10940-10949. |
Dai et al., Mode conversion in tapered submicron silicon ridge optical waveguides, Optical Society of America, Jun. 4, 2012 / vol. 20, No. 12 / Optics Express, p. 13425-13439. |
Ding et al., Fabrication tolerant polarization splitter and rotator based on a tapered directional coupler, Optical Society of America, Aug. 27, 2012 / vol. 20, No. 18 / Optics Express, p. 20021-20027. |
Liu et al., Silicon-on-insulator polarization splitting and rotating device for polarization diversity circuits, Optical Society of America, Jun. 20, 2011 / Vol, 19, No. 13 / Optics Express, p. 12646-12651. |
Watts et al., Integrated mode-evolution-based polarization splitter, Optical Society of America, May 1, 2005 / vol. 30, No. 9 / Optics Letters, p. 967-969. |
Watts et al., Integrated mode-evolution-based polarization rotators, Optical Society of America, Jan. 15, 2005 / vol. 30, No. 2 / Optics Letters, p. 138-140. |
Zhang et al., Silicon waveguide based mode-evolution polarization rotator, Silicon Photonics and Photonic Integrated Circuits II, Proc. of SPIE vol. 7719, 2010, p. 77190C-1-77190C-8. |
Zhang et al., Silicon waveguide based TE mode converter, Optical Society of America, Nov. 22, 2010 / vol. 18, No. 24 / Optics Express, p. 25264-25270. |
Shiraishi et al., A two-port polarization-insensitive coupler module between single-mode fiber and silicon wire waveguide, Optical Society of America, Oct. 22, 2012 / vol. 20, No. 22/ Optics Express, p. 24370-24375. |
Number | Date | Country | |
---|---|---|---|
20140153862 A1 | Jun 2014 | US |
Number | Date | Country | |
---|---|---|---|
61730253 | Nov 2012 | US |