This application claims priority to Chinese Patent Application No. 201310719812.7, filed on Dec. 24, 2013, which is hereby incorporated by reference in its entirety.
The present invention relates to the field of optics communications, and in particular, to an optical multiplexer and a transmitter optical subassembly.
Currently, a 40 gigabit (G) Quad Small Form-factor Pluggable Plus (QSFP+), 100 G Centum (C) Form-Factor Pluggable 2 (CFP2), and CFP4 optical modules all require a Photonic Integrated Device Transmitter Optical Subassembly (PID TOSA) that collects 4 beams of light emitted by a laser from 4 ports and outputs the light through 1 port. This type of component requires a small size and high density, especially for a 100 G CFP2/CFP4 or a 400 G module. Because a light source needs to meet the local area network (LAN) Emulation Wavelength Division Multiplexing (LANE WDM) or even the Dense Wavelength Division Multiplexing (DWDM) standard, a wavelength interval is small and light combination is especially difficult.
Currently, there are mainly two implementation manners of PID TOSA, which are respectively as follows.
(1) ZigZag Filter optical multiplexor (OMUX) (an optical multiplexer formed by a zigzag optical path filter) light combination solution: as shown in
(2) Arrayed Waveguide Grating (AWG) light combination solution: as shown in
It can be learned that current optical multiplexers all have such disadvantages as a large package size, large packaging loss, or a complex manufacturing process.
Embodiments of the present invention provide an optical multiplexer and a transmitter optical subassembly, so as to reduce a package size and packaging loss, and reduce the complexity of a manufacturing process.
According to a first aspect, an optical multiplexer includes at least two levels of light-combining parts, where each level of light-combining parts includes light combiners whose number is ½ the number of beams of input light of this level, each light combiner is configured to combine two beams of light into one beam, and the optical multiplexer includes at least two different types of light combiners; collimation lenses, where the number of the collimation lenses is the same as the number of light sources and which are disposed between a light source and the first level of light-combining parts; and a focusing lens, disposed behind a light outlet of the last level of light-combining parts.
With reference to the first aspect, in a first possible implementation manner, the light combiner is a polarization beam combiner (PBC) light combiner or a light-splitting prism light combiner.
With reference to the first aspect, in a second possible implementation manner, light combiners in one level of light-combining parts are the same.
With reference to the first possible implementation manner of the first aspect, in a third possible implementation manner, the PBC light combiner includes a PBC configured to combine light input through a first light inlet and light input through a second light inlet into one beam, where the first light inlet directly faces first incident light of the PBC light combiner; a half wave plate, whose optical axis is disposed at a 45-degree angle to a polarization direction of second incident light of the PBC light combiner; and a reflector configured to reflect light output by the half wave plate to the second light inlet of the PBC.
With reference to the first possible implementation manner of the first aspect, in a fourth possible implementation manner, the light-splitting prism light combiner includes a light-splitting prism configured to combine light input through a first light inlet and light input through a second light inlet into one beam, where the first light inlet directly faces first incident light of the light-splitting prism light combiner; a reflector configured to reflect second incident light of the light-splitting prism light combiner to the second light inlet of the light-splitting prism; and a beam absorber, disposed on an opposite side of the second light inlet of the light-splitting prism and configured to absorb light obtained after the light input through the second light inlet is transmitted by the light-splitting prism and light obtained after the light input through the first light inlet is reflected by the light-splitting prism.
With reference to the fourth possible implementation manner of the first aspect, in a fifth possible implementation manner, the light-splitting prism is a 3 decibel (dB) light-splitting prism.
With reference to the first aspect, in a sixth possible implementation manner, the optical multiplexer further includes at least one isolator, disposed between two levels of light-combining parts and configured to isolate light that is reflected from a light output direction.
With reference to the sixth possible implementation manner of the first aspect, in a seventh possible implementation manner, when a next level of light-combining parts includes a PBC light combiner, the isolator is a polarization-related isolator.
According to a second aspect, a transmitter optical subassembly includes the foregoing optical multiplexer, and a laser chip that is used as a light source, where the laser chip is connected to an input end of the optical multiplexer; and a ceramic ferrule that is used for coupling output, where the ceramic ferrule is connected to an output end of the optical multiplexer.
With reference to the second aspect, in a first possible implementation manner, the transmitter optical subassembly further includes a photoelectric detector, connected to the laser chip and configured to monitor power of a light source that is emitted by the laser chip.
Embodiments of the present invention provide an optical multiplexer and a transmitter optical subassembly. A light-combining part is formed by using at least one light combiner that can combine two beams of light into one beam, and at least two levels of light-combining parts are used to constitute an optical multiplexer, so that 2N beams of light are combined into one beam by using N level of light-combining parts, thereby reducing the package size and packaging loss, and reducing the complexity of a manufacturing process.
Embodiments of the present invention provide an optical multiplexer and a transmitter optical subassembly. A light-combining part is formed by using at least one light combiner that can combine two beams of light into one beam of light, and at least two levels of light-combining parts are used to constitute the optical multiplexer, so that 2N beams of light are combined into one beam by using N level of light-combining parts, thereby reducing a package size and packaging loss, and reducing the complexity of a manufacturing process.
An embodiment of the present invention provides an optical multiplexer. As shown in
For an optical multiplexer that includes N level of light-combining parts, light combination of a maximum of 2N beams of light may be implemented, and a difference between optical distances of light in all paths is small, thereby reducing a package size and packaging loss, and reducing the complexity of a manufacturing process of the optical multiplexer.
A light combiner may be as follows a PBC light combiner or a light-splitting prism light combiner.
Certainly, a person skilled in the art may also use another light combiner with a similar function to perform light combination as long as combination of two beams of light into one beam can be implemented.
One optical multiplexer may include multiple light combiners. It is preferable that the optical multiplexer includes at least two different types of light combiners. In this case, a light-combining effect of the optical multiplexer is relatively balanced, and is not easily subjected to influence of an advantage or a disadvantage of one type of light combiners.
Preferably, to facilitate the ease of optimization settings, or to facilitate the ease of inserting another optical component between two levels of light-combining parts, it is preferable that light combiners in one level of light-combining parts are the same.
Further, as shown in
When the PBC 401 is used to perform light combination, it is required that a polarization direction of the light input through the first light inlet 410 and a polarization direction of the light input by the second light inlet 420 are mutually perpendicular. Therefore, rotation of a polarization direction may be performed on one beam of the light by using the half wave plate 402. An optical axis of the half wave plate 402 is disposed at a 45-degree angle to the polarization direction of the second incident light 421, so that after the second incident light 421 passes through the half wave plate 402, the polarization direction is rotated by 90 degrees and is exactly perpendicular to a polarization direction of the first incident light 411. The light output by the half wave plate 402 is reflected to the second light inlet 420 of the PBC by using the reflector 403, and then light combination may be performed by the PBC.
Further, as shown in
The light-splitting prism can reflect a part of incident light and transmit a part of incident light. If a first beam of light transmitted by the light-splitting prism and a second beam of light reflected by the light-splitting prism are emitted from a same angle, light combination by using the light-splitting prism is implemented.
During specific settings, the first light inlet 510 may directly face the first incident light 511 of the light-splitting prism light combiner, and then the second incident light 521 of the light-splitting prism light combiner is reflected to the second light inlet 520 of the light-splitting prism by using the reflector 502, and light obtained after the first incident light 511 is transmitted by the light-splitting prism 501 and light obtained after the second incident light 521 is reflected by the light-splitting prism 501 are exactly combined into one beam. To prevent diffuse reflectance of light obtained after the light input through the second light inlet 520 is transmitted by the light-splitting prism and light obtained after the light input through the first light inlet 510 is reflected by the light-splitting prism, which causes interference to a light source, a beam absorber 503 may be disposed on an opposite side of the second light inlet 520 of the light-splitting prism, so as to absorb the light obtained after the light input through the second light inlet 520 is transmitted by the light-splitting prism and the light obtained after the light input through the first light inlet 510 is reflected by the light-splitting prism.
Further, to obtain a better light combination effect, a 3 dB light-splitting prism may be used as the light-splitting prism. In this case, a ratio of transmitted energy to reflected energy of the incident light of the light-splitting prism is 50:50, that is, 50% energy is transmitted, 50% energy is reflected, and energy of the two beams of light is similar after the two beams of light are combined by the 3 dB light-splitting prism. Certainly, a person skilled in the art may also use a light-splitting prism of another light-splitting ratio according to an actual situation.
Some light-splitting prism light combiners may not include a beam absorber, but share a beam absorber of a neighboring light-splitting prism light combiner.
Preferably, to prevent that light input from a light output direction causes interference to a light source, or to prevent that diffuse reflectance is formed by using an optical element, the optical multiplexer further includes at least one isolator, disposed between two levels of light-combining parts and configured to isolate light that is reflected from a light output direction.
Further, because the PBC light combiner has a polarization direction requirement for incident light, to obtain a better light combination effect, when a next level of light-combining parts includes a PBC light combiner, the isolator is a polarization-related isolator; and when a next level of light-combining parts includes a light-splitting prism, the isolator is a polarization-related isolator or a polarization-unrelated isolator.
In the following, the optical multiplexer provided in the embodiment of the present invention is described in detail by using two specific embodiments.
Four beams of light in combination are used as an example for description. In this embodiment, first, 2 PBC light combiners are used as the first level of light-combining parts to combine 4 beams of light into 2 beams of light. Then, one light-splitting prism light combiner is used as the second level of light-combining parts to further combine the 2 beams of light into 1 beam for output.
As shown in
Four beams of light in combination are used as an example for description. In this embodiment, first, 2 light-splitting prism light combiners are used as the first level of light-combining parts to combine 4 beams into 2 beams of light. Then, one PBC light combiner is used as the second level of light-combining parts to further combine the 2 beams of light into 1 beam for output.
As shown in
As shown in
Further, the transmitter optical subassembly 800 of the light-emitting device further includes a photoelectric detector 804 connected to the laser chip 801 and configured to monitor power of a light source that is emitted by the laser chip 801.
Further, the light-emitting device further includes a photoelectric detector connected to the laser chip and configured to monitor power of a light source that is emitted by the laser chip.
Further, the transmitter optical subassembly further includes an enclosure that is used for packaging. Preferably, the enclosure is a metal enclosure.
Embodiments of the present invention provide an optical multiplexer and a transmitter optical subassembly. A light-combining part is formed by using at least one light combiner that can combine two beams of light into one beam, and a light-combining part of at least one level constitutes the optical multiplexer, so that 2N beams of light are combined into one beam by using N level of light-combining parts, thereby reducing a package size and packaging loss, and reducing the complexity of a manufacturing process.
Obviously, a person skilled in the art may make various modifications and variations to the present invention without departing from the spirit and scope of the present invention. The present invention is intended to cover these modifications and variations provided that they fall within the scope of protection defined by the following claims and their equivalent technologies.
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