An optical waveguide splitter with a symmetric splitting power ratio having one input port and two output ports, includes a substrate and one or more vertical waveguide layers deposited thereon or diffused thereinto, and optionally one or more cladding layers deposited upon the waveguide layer(s). T
An optical waveguide splitter with a symmetric splitting power ratio having one input port and two output ports, includes a substrate and one or more vertical waveguide layers deposited thereon or diffused thereinto, and optionally one or more cladding layers deposited upon the waveguide layer(s). The waveguide layers and optionally one or more cladding layer together and optionally with the substrate form a profile of the refractive index that supports the propagation of light in a plane substantially parallel to the substrate. On both sides of the input port, the waveguide sidewalls terminate at a depth deeper than the location of the peak intensity of the beam transporting propagating light energy within the input port, and the sidewalls on both sides of each output port terminate at a depth shallower than the location of the peak intensity of the beam transporting the majority light energy within each output port.
대표청구항▼
1. An optical waveguide splitter (1) with a symmetric splitting power ratio having one input port (2) and two output ports (3,4), which waveguide splitter is a rectangular Multi Mode Interference (MMI) type splitter, comprising: a substrate (5); andone or more vertical waveguide layers or materials
1. An optical waveguide splitter (1) with a symmetric splitting power ratio having one input port (2) and two output ports (3,4), which waveguide splitter is a rectangular Multi Mode Interference (MMI) type splitter, comprising: a substrate (5); andone or more vertical waveguide layers or materials that have been deposited upon or diffused into the substrate (6), said layers or materials forming a profile of the refractive index that supports the propagation of light in a plane that is substantially parallel to the substrate (parallel to the X and Z directions),wherein said waveguide splitter contains one input waveguide and two output wave guides only,wherein, on both sides of the input port (2), waveguide sidewalls terminate at a depth (Y-direction) that is deeper than a location of a peak intensity of the optical beam or guided mode that transports most or all of the propagating light energy within the input port,wherein waveguide sidewalls on both sides of each output port (3, 4) terminate at a depth that is shallower than the location of the peak intensity of the mode or optical beam that transports the majority of the light energy within each given output port, andwherein the optical waveguide splitter (1) is monolithically integrated with a semiconductor laser. 2. The optical waveguide splitter (1) according to claim 1, wherein, on both sides of the input port (2) the waveguide splitter (1) has been etched down at least through a top layer (7) and at least half of the vertical waveguide layer (6), andwherein on both sides of each of the output ports (3,4) the waveguide splitter (1) has been etched down through a portion of, or all of the top layer (7) but through less than half of the vertical waveguide layer (6). 3. The optical waveguide splitter (1) according to claim 2, wherein the splitter (1) is a 1x2 MMI (Multi Mode Interference) type filter. 4. The optical waveguide splitter (1) according to claim 2, wherein output waveguides (3, 4) have no sidewalls, and a lateral extent of each output waveguide are defined by a modification of the profile of the refractive index by a dopant or vacancy diffusion process, or by an ion implantation or quantum well intermixing procedure. 5. The optical waveguide splitter (1) according to claim 2, wherein a MMI region rectangular profile is modifiable in areas that are substantially removed from the areas and interfaces where light propagates and reflects, to facilitate photolithographic mask alignment or other aspects of circuit fabrication, utilization, or appearance. 6. The optical waveguide splitter (1) according to claim 2, wherein the optical waveguide splitter (1) is disposed at the input of a standalone interferometric modulator. 7. The optical waveguide splitter (1) according to claim 2, wherein the optical waveguide splitter (1) is disposed at the input of or within an optical or electro optical integrated circuit. 8. The optical waveguide splitter (1) according to claim 1, wherein the splitter (1) is a 1x2 MMI type filter. 9. The optical waveguide splitter (1) according to claim 8, wherein output waveguides (3, 4) have no sidewalls, and a lateral extent of each output waveguide are defined by a modification of the profile of the refractive index by a dopant or vacancy diffusion process, or by an ion implantation or quantum well intermixing procedure. 10. The optical waveguide splitter (1) according to claim 8, wherein a MMI region rectangular profile is modifiable in areas that are substantially removed from the areas and interfaces where light propagates and reflects, to facilitate photolithographic mask alignment or other aspects of circuit fabrication, utilization, or appearance. 11. The optical waveguide splitter (1) according to claim 1, wherein output waveguides (3, 4) have no sidewalls, and a lateral extent of each output waveguide are defined by a modification of the profile of the refractive index by a dopant or vacancy diffusion process, or by an ion implantation or quantum well intermixing procedure. 12. The optical waveguide splitter (1) according to claim 11, wherein a MMI region rectangular profile is modifiable in areas that are substantially removed from the areas and interfaces where light propagates and reflects, to facilitate photolithographic mask alignment or other aspects of circuit fabrication, utilization, or appearance. 13. The optical waveguide splitter (1) according to claim 1, wherein a MMI region rectangular profile is modifiable in areas that are substantially removed from the areas and interfaces where light propagates and reflects, to facilitate photolithographic mask alignment or other aspects of circuit fabrication, utilization, or appearance. 14. The optical waveguide splitter (1) according to claim 1, wherein the optical waveguide splitter (1) is disposed at the input of a standalone interferometric modulator. 15. The optical waveguide splitter (1) according to claim 1, wherein the optical waveguide splitter (1) is disposed at the input of or within an optical or electro optical integrated circuit. 16. An optical waveguide splitter (1) with a symmetric splitting power ratio having one input port (2) and two output ports (3,4), which waveguide splitter is a rectangular Multi Mode Interference (MMI) type splitter, comprising: a substrate (5); andone or more vertical waveguide layers or materials that have been deposited upon or diffused into the substrate (6), said layers or materials forming a profile of the refractive index that supports the propagation of light in a plane that is substantially parallel to the substrate (parallel to the X and Z directions),wherein said waveguide splitter contains one input waveguide and two output wave guides only,wherein, on both sides of the input port (2), waveguide sidewalls terminate at a depth (Y-direction) that is deeper than a location of a peak intensity of the optical beam or guided mode that transports most or all of the propagating light energy within the input port,wherein waveguide sidewalls on both sides of each output port (3, 4) terminate at a depth that is shallower than the location of the peak intensity of the mode or optical beam that transports the majority of the light energy within each given output port, andwherein output waveguides (3, 4) have no sidewalls, and a lateral extent of each output waveguide are defined by a modification of the profile of the refractive index by a dopant or vacancy diffusion process, or by an ion implantation or quantum well intermixing procedure. 17. The optical waveguide splitter (1) according to claim 16, wherein a MMI region rectangular profile is modifiable in areas that are substantially removed from the areas and interfaces where light propagates and reflects, to facilitate photolithographic mask alignment or other aspects of circuit fabrication, utilization, or appearance. 18. The optical waveguide splitter (1) according to claim 16, wherein, on both sides of the input port (2) the waveguide splitter (1) has been etched down at least through a top layer (7) and at least half of the vertical waveguide layer (6), andwherein on both sides of each of the output ports (3,4) the waveguide splitter (1) has been etched down through a portion of, or all of the top layer (7) but through less than half of the vertical waveguide layer (6). 19. An optical waveguide splitter (1) with a symmetric splitting power ratio having one input port (2) and two output ports (3,4), which waveguide splitter is a rectangular Multi Mode Interference (MMI) type splitter, comprising: a substrate (5); andone or more vertical waveguide layers or materials that have been deposited upon or diffused into the substrate (6), said layers or materials forming a profile of the refractive index that supports the propagation of light in a plane that is substantially parallel to the substrate (parallel to the X and Z directions),wherein said waveguide splitter contains one input waveguide and two output wave guides only,wherein, on both sides of the input port (2), waveguide sidewalls terminate at a depth (Y-direction) that is deeper than a location of a peak intensity of the optical beam or guided mode that transports most or all of the propagating light energy within the input port,wherein waveguide sidewalls on both sides of each output port (3, 4) terminate at a depth that is shallower than the location of the peak intensity of the mode or optical beam that transports the majority of the light energy within each given output port, andwherein a MMI region rectangular profile is modifiable in areas that are substantially removed from the areas and interfaces where light propagates and reflects, to facilitate photolithographic mask alignment or other aspects of circuit fabrication, utilization, or appearance. 20. The optical waveguide splitter (1) according to claim 19, wherein, on both sides of the input port (2) the waveguide splitter (1) has been etched down at least through a top layer (7) and at least half of the vertical waveguide layer (6), andwherein on both sides of each of the output ports (3,4) the waveguide splitter (1) has been etched down through a portion of, or all of the top layer (7) but through less than half of the vertical waveguide layer (6).
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이 특허에 인용된 특허 (3)
Rolland Claude,CAX ; Yu Jun,CAX, Coupling of strongly and weakly guiding waveguides for compact integrated mach zehnder modulators.
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