Self aligned optical component in line connection

A self-aligning connection assembly is provided for aligning a pair of optical components adjacent to one another. The assembly includes a stepped silicon substrate having a first surface vertically offset from a second surface. At least one rib with angled walls extends from the first and second surfaces such that a first supporting portion thereof is substantially parallel to a central plane of the substrate. A first optical component having a channel formed therein engages the first supporting portion of the rib proximate the first surface of the substrate. A second optical component, which is larger than the first optical component and has a channel formed therein, engages the first supporting portion of the rib proximate the second surface of the substrate. Although the first and second optical components have different heights relative to their core waveguides, due to the stepped configuration of the substrate, the core waveguides of the first and second optical components align.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention is directed towards a self-aligning connection assembly for interconnecting at least a pair of optical components along a common substrate. The optical components and substrate of the assembly are configured such that the core waveguides of the optical components are accurately aligned despite any differences between the dimensions of the optical components including the distances between the core waveguide and the mounting surface of each optical device. The substrate is also configured to minimize the effect of any warpage within the optical component on the alignment accuracy. Turning now to FIG. 1, a self-aligning connection assembly incorporating the teachings of the present invention is generally illustrated at 10 . The assembly 10 includes a substrate 12 , a first optical component 14 and a second optical component 16 . The substrate 12 includes a major surface 18 which includes a first surface or section 20 and a second surface or section 22 . The second surface 22 can be vertically offset from the first surface 20 such that the substrate 12 has a stepped configuration. A first rib 24 having tapered or angled side walls 26 extends from the first surface 20 and the second surface 22 of the substrate 12 . The first rib 24 includes a supporting portion, generally indicated at 28 , which extends substantially parallel to a central plane 30 of the substrate 12 . As such, despite the rib 24 having a first axial dimension relative to the first surface 20 and a second, larger, axial dimension relative to the second surface 22 , the supporting portion 28 has a constant axial dimension relative to the central plane 30 . Preferably, the supporting portion 28 comprises a pair of co-planar line contacts defined along the side walls 26 . The substrate 12 also includes a second rib 32 with tapered or angled side walls 34 extending from the first surface 20 and the second surface 22 . The second rib 32 includes a second supporting portion, generally indicated at 36 , which extends substantially parallel to the central plane 30 of the substrate 12 . As such, despite the second rib 32 having a first axial dimension relative to the first surface 20 and a second, larger, axial dimension relative to the second surface 22 , the second supporting portion 36 has a constant axial dimension relative to the central plane 30 . Preferably, the second supporting portion 36 comprises a pair of co-planar line contacts defined along the side walls 34 . Referring now also to FIG. 2 , the first optical component 14 includes a first rectangular channel 38 and a second rectangular channel 40 formed therein. The first waveguide 14 also includes a core waveguide, generally indicated at 42 , inboard of channels 38 and 40 . The first rib 24 of the substrate 12 engages the first optical component 14 along the supporting portion 28 adjacent the first rectangular channel 38 . The second rib 32 of the substrate 12 engages the optical component 14 along the second supporting surface 36 adjacent the second rectangular channel 40 . The height to which the optical component 14 is supported above the substrate 12 depends upon the height and taper of the ribs 24 and 32 and the width of the channels 38 and 40 . Preferably, the dimensions of the ribs 24 and 32 and of the channels 38 and 40 are selected to position the core waveguide 42 at a preselected position relative to the second optical component 16 , the first and second supporting portions 28 and 36 , or the central plane 30 of the substrate 12 . Referring now also to FIG. 3 , the second optical component 16 includes a first rectangular channel 44 and a second rectangular channel 46 formed therein. The optical component 16 also includes a core waveguide, generally indicated at 48 , formed therein inboard of channels 44 and 46 . The first rib 24 engages the second optical component 16 along the supporting portion 28 adjacent the first channel 44 . The second rib 32 engages the second optical component 16 along the second supporting portion 36 adjacent the second channel 46 . The height to which the second optical component 16 is supported above the substrate 12 depends upon the taper and height of ribs 24 and 32 and the width of channels 44 and 46 . Preferably, the dimensions of the ribs 24 and 32 and of channels 44 and 46 are selected to position the core waveguide 48 at a preselected position relative to the first optical component 14 , the first and second supporting portions 28 and 36 , or the central plane 30 of the substrate 12 . Even more preferably, the dimensions of the ribs 24 and 32 , the channels 44 and 46 , and the channels 38 and 40 are selected to align the core waveguide 48 with the core waveguide 42 . Referring now to FIGS. 4 A- 4 F, the sequential steps for interconnecting the first optical component 14 with the substrate 12 are illustrated. In this exemplary embodiment, the first optical component is illustrated as an active optical component although a passive component could substitute therefore. Referring first to FIG. 4A, a wafer or body 50 is provided. The body 50 preferably comprises InP. Next, a waveguide layer 52 such as an InGaAsP active layer, is deposited on the body 50 . The waveguide layer 52 is then patterned in a single lithographic step to define a pair of channel etching regions 54 A and 54 B and a core waveguide forming region 56 . Referring now to FIG. 4B, a contact layer 58 such as a p-doped InP layer is deposited over the waveguide layer 52 and exposed portions of the body 50 . If desired, epitaxial regrowth may also be used to form the contact layer 58 . In FIG. 4 C, the processing steps for the formation of the active optical component 14 are performed. These may include the lateral electrical confinement by proton implantation and metalization. Further, a plurality of electrical pads 60 are formed on the contact layer 58 . If desired, solder may also be deposited on the pads 60 for later establishing an electrical connection between the optical component 14 and the substrate 12 . In FIG. 4 D, the channels 38 and 40 are formed in the body 50 by selective chemical etching. By using a specific etching solution, vertical side walls 62 can be formed along the channels 38 and 40 . The dimensions of the channels 38 and 40 are selected to correspond to the distance between the core waveguide 42 and the pads 60 . In FIG. 4 E, the optical component 14 is placed on the substrate 12 such that the rib 32 is adjacent the channel 40 . Although only half of the assembly is shown, the other half would be the same. The initial placement of the optical component 14 on the substrate 12 should situate the rib 32 within at least one half of the width of the channel 40 . Subsequent to the initial placement of the optical component 14 , an adhesive such as epoxy or glue 64 can be applied to the optical component 14 and substrate 12 . During gluing (or soldering) a tool maintains the component 14 on the rib 32 by pressing. Turning now to FIGS. 5 A- 5 E, the sequential steps for forming the second optical component 16 are illustrated. In this exemplary embodiment, the second optical component 16 is illustrated as a passive component although an active component may substitute therefore. Referring initially to FIG. 5A, a wafer or body 66 is initially provided. The body 66 preferably comprises Si or SiO 2 . A SiO 2 buffer layer and waveguide layer 68 preferably made of SiO 2 is then deposited on the body 66 . A mask 70 , preferably made of Si, is next deposited on the waveguide layer 68 . Thereafter, the mask 70 and waveguide layer 68 are patterned in a single lithographic step to define channel forming regions 72 A and 72 B and a core waveguide forming region 74 . In FIG. 5 B, the mask layer 70 is removed from the core waveguide forming region 74 . In FIG. 5 C, overclad 76 , made of SiO 2 , is deposited over the remaining portions of the mask layer 70 , exposed portions of the body 66 , and the waveguide forming region 74 . In FIG. 5 D, select portions of the contact layer 76 adjacent the channel forming regions 72 A and 72 B are removed by etching. Thereafter, the channels 44 and 46 are etched into the body 66 . It should be noted that the etching of the SiO 2 overclad layer 76 in the area of the channel forming regions 72 A and 72 B is blocked by the buried mask 70 . This enables the channels 44 and 46 to be positioned at the desired distance relative to the core waveguide 48 . If desired, after the channels 44 and 46 are formed, the remainder of the mask 70 can be removed. Referring to FIG. 5 E, the optical chip 16 is positioned on the substrate 12 such that the rib 32 engages the optical component 16 adjacent the channel 46 . Although only one half of the assembly is illustrated, the other half would be the same. Thereafter, an adhesive such as an epoxy or glue 78 is applied to the optical component 16 and substrate 12 . The resilient nature of the glue 78 urges the optical component 16 and substrate 12 towards one another. The interaction of the channel 46 and rib 32 controls the final positioning of the optical component 16 relative to the substrate 12 . FIGS. 6 A- 6 E depict an alternative method to achieve the optical component 16 , where the overclad layer 76 is made of polymer with a refractive index matching that of silica. In the drawings, like components have been identified with like reference numbers. This polymer overclad enables use of a standard photoresist as a first mask layer 70 . This first photoresist is completely removed after the core layer 68 patterning ( FIG. 6B ). It is no longer used as an etching blocking layer during the etching of the overclad in the area of the channel forming regions 72 A and 72 B. The silica core layer 68 can be directly used for blocking polymer etching as depicted in FIG. 6D . Referring now to FIGS. 7 A- 7 H, the sequential steps for forming the substrate 12 of the present invention are illustrate. Referring to FIGS. 7 A- 7 E collectively, a silicon wafer 80 is initially provided. A dielectric mask 82 is then deposited on the wafer 80 . The dielectric mask 82 is then patterned so as to overly a rib forming region 84 of the wafer 80 . Thereafter, the wafer 80 is chemically etched to yield a preliminary rib 86 under the dielectric mask 82 . In FIG. 7 E, the dielectric mask 82 is removed to provide rib 84 which is thereafter tapered to a desired angle using a lithographic process. If two different heights are desired along the same rib relative to the wafer 80 , the above process is skips from that illustrate in FIG. 7D to that illustrated in FIG. 7F . More particularly, after forming the preliminary rib 86 at FIG. 7D, a second dielectric layer 88 is placed over a first section 90 of the wafer 80 . A second section 92 of the wafer 80 remains exposed. In FIG. 7 G, etching is continued on the second section 92 of the wafer 80 . This further heightens the preliminary rib 86 thereover. In FIG. 7 H, both the first and second dielectric layers 82 and 88 are removed. This yields rib 84 which has a first height relative to the first section 90 of the wafer 80 and a second height relative to a second section 92 of the wafer 80 . However, rib 84 has a planar top surface 94 which has a constant height relative to a central plane 30 of wafer 80 . Turning now to FIGS. 8 and 9 , a second aspect of the present invention is illustrated. According to this aspect, the effect of optical component warpage on alignment accuracy is minimized. More particularly, the assembly 10 includes substrate 12 , first optical component 14 and second optical component 16 coupled thereto. The second optical component 16 in this exemplary embodiment comprises a 1 by 8 splitter having a 250 micrometer pitch. The second optical component 16 is illustrated as being greater than 20 to 30 millimeters long and having a warpage of approximately 10 microns. To eliminate the effect of this warpage on positioning accuracy, the second portion 92 of the substrate 12 has a length which is approximately 5 to 10 millimeters or, more preferably, which is less than 34 percent, or even more preferably less than 25 percent, of the length of the optical component 16 . Turning now to FIG. 10 A- 10 C, an automated process for positioning the optical component 14 on the substrate 12 is illustrated. Although optical component 14 is illustrated, optical component 16 could substitute therefore. In FIG. 10A, a handling tool 96 of a flip chip machine initially positions the optical component 14 on the substrate 12 . Any positioning misalignment of the optical component 14 relative to the substrate 12 is preferably less than half of the difference between the width of the channels 38 and 40 and the top width of the ribs 24 and 32 . In FIG. 10 B, the optical component 14 is released by the handling tool 96 after initial positioning. The interaction of the angled walls 26 and 34 with the optical component 14 adjacent the channels 38 and 40 start to align the optical component 24 and substrate 12 relative to one another. In FIG. 10 C, the handling tool 96 presses the optical component 14 in order to encourage its self-alignment and to maintain such alignment during bonding. Turning now to FIGS. 11A and 11B , a method to bond and electrically connect the optical component 14 on the substrate 12 is illustrated. Although optical component 14 is illustrated, optical component 16 could substitute therefor. In this embodiment, the optical component 14 is an active component where electrical contact is to be made between the optical component 14 and the substrate 12 . A conductor 98 such as a conductive epoxy or a solder film is applied to a pad 100 on the substrate 12 . The pad 100 is preferably quite large relative to the gap between the optical component 14 and the substrate 12 . For example, the pad 100 may be greater than 80 micrometers while the gap is less than four micrometers. When the conductor 98 is made of a solder film, it reacts during reflow to fill the gap between the pad 100 and the opposite pad 60 on the optical component 14 . The reflow of the conductor 98 serves to urge the optical component 14 and substrate relative to each other such that the rib 32 interacts with the optical component 14 adjacent the channel 40 . The tapered side wall 34 laterally and vertically orients the optical component 14 relative to the substrate 12 . When the conductor 98 is made of a conductive epoxy, the glue bump with an initial height higher than the final gap between the optical component 14 on opposite pad 60 is simply pressed during positioning. It is then followed by epoxy consolidation by thermal or UV curing. Turning now to FIGS. 12 - 16 various embodiments of substrate 12 are illustrated. In FIG. 12 , substrate 12 A is employed to interconnect a first passive optical component 102 , an active optical component 104 and a second passive optical component 106 . Since the active component 104 is much thinner than the passive components 102 and 106 , it must be elevated relative thereto to ensure proper alignment of the adjacent core waveguides. Accordingly and as best seen in FIG. 13 , substrate 12 A is provided with a stepped configuration including a raised central portion 108 . Substrate 12 A also includes ribs 24 and 32 extending therefrom. Ribs 24 and 32 include first and second supporting portions 28 and 36 which are spaced apart from the central plane 30 of the substrate 12 A by a constant amount. As such, the first passive optical component 102 , active optical component 104 , and second passive optical component 106 are properly aligned relative to one another. In FIG. 14, a first substrate 12 B is employed to interconnect an active component 110 with a first passive component 112 , a second substrate 12 C is employed to interconnect the first passive component 112 with a second passive component 114 , and a third substrate 12 D is employed to interconnect the second passive component 114 with optical fibers 116 . As best seen in FIG. 15 , since the active waveguide 110 is thinner than the passive component 112 , the first substrate 12 B includes a stepped configuration with an elevated portion 118 to properly align the two components relative to one another. As best seen in FIG. 16 , since the first passive component 112 and the second passive component 114 have approximately equal widths, the second substrate 12 C is essentially planar. As best seen in FIG. 17 , since the second passive component 114 is to be coupled with optical fibers 116 , the third substrate 12 D includes V-shaped grooves 120 . Thus, the present invention provides a self-aligning connection assembly for interconnecting optical components having varying widths such that adjacent core waveguides are properly aligned. The self-aligning connection assembly also minimizes the effect of optical component warpage on positioning accuracy. Those skilled in the art can now appreciate from the foregoing description that the broad teachings of the present invention can be implemented in a variety of forms. Therefore, while this invention has been described in connection with particular examples thereof, the true scope of the invention should not be so limited since other modifications will become apparent to the skilled practitioner upon a study of the drawings, specification, and following claims.