The present disclosure relates to a bonding method and an alignment method, more particularly to a method of bonding a focusing lens with a fiber array, and a method of aligning the focusing lens with the fiber array during bonding process.
Optical transceivers are generally installed in electronic communication facilities in modern high-speed communication networks. In order to make flexible the design of an electronic communication facility and less burdensome the maintenance of the same, an optical transceiver is inserted into a corresponding cage that is disposed in the communication facility in a pluggable manner. In order to define the electrical-to-mechanical interface of the optical transceiver and the corresponding cage, different specifications such as XFP (10 Gigabit Small Form Factor Pluggable) used in 10 GB/s communication rate, QSFP (Quad Small Form-factor Pluggable), or other form factors at different communication rates have been made available.
With the development of technology, a high-speed optical transceiver, such as 400 G, has been utilized to meet the demand of higher communication speed. The communication speed of the optical transceiver is usually determined by the bandwidth for signal transmission, where a spot size of light may correlate to any achievable bandwidth.
According to one aspect of the present disclosure, a method of bonding a focusing lens with a fiber array is disclosed. Such disclosed method in one embodiment includes: recognizing a core end facet of a first optical fiber disposed on the fiber array by a camera, specifying a projection of the core end facet of the first optical fiber on a bonding surface of the fiber array by a processing unit to obtain a core end facet information, performing an alignment procedure by a pickup component according to the core end facet information to make an optical axis of the focusing lens overlap with the projection of the core end facet of the first optical fiber, and attaching the focusing lens to the bonding surface of the fiber array.
According to another aspect of the present disclosure, a method of aligning a focusing lens with a fiber array is disclosed. Such disclosed method in one embodiment includes: recognizing a core end facet of an optical fiber disposed on the fiber array by a camera, specifying a projection of the core end facet of the optical fiber on a bonding surface of the fiber array by a processing unit to obtain a core end facet information, and performing an alignment procedure by a pickup component according to the core end facet information to make an optical axis of the focusing lens overlap with the projection of the core end facet of the optical fiber.
The present disclosure will become more fully understood from the detailed description given below and the accompanying drawings which are given by way of illustration only and thus are not intending to limit the present disclosure and wherein:
In the following detailed description, for purposes of explanation, numerous specific details are set forth in order to provide a thorough understanding of the disclosed embodiments. It will be apparent, however, that one or more embodiments may be practiced without these specific details. In other instances, well-known structures and devices are schematically shown in order to simplify the drawings.
The first stage 10 is configured to support a fiber array and includes an alignment mark 100. The second stage 20 is configured to support a focusing lens. The third stage 30 is configured to be a working region for aligning the focusing lens with the fiber array, and the third stage 30 includes an alignment mark 300. The fixture 40 is configured to position the fiber array. The camera 50 is movable between the first stage 10 and the third stage 30 and configured to capture an image of the fiber array or the focusing lens. The pickup component 60 is movable among the first stage 10 through the third stage 30 and configured to physically capture the focusing lens.
Details of the fiber array and the focusing lens are described as follows.
In this embodiment, the optical fibers disposed on the fiber array 110 include a first optical fiber 120a, a second optical fiber 120b and multiple third optical fibers 120c. The first optical fiber 120a is an optical fiber closest to the left edge 114 of the fiber array 110, and the second optical fiber 120b is an optical fiber closest to the right edge 115 of the fiber array 110. The third optical fibers 120c are arranged between the first optical fiber 120a and the second optical fiber 120b. As shown in
A focusing lens 130, for example, is a singlet lens including a bar 131 and a lens 132 attached to each other. A convex surface 1321 of the lens 132 is located opposite to where the bar 131 connects to the bonding surface 113. The refractive index of the focusing lens 130 is larger than the refractive index of the fiber array 110. Specifically, the refractive index of the focusing lens 130 is 3.5 in this embodiment.
In the first embodiment, a method of bonding the focusing lens 130 with the fiber array 110 is disclosed as follows.
In the step S110, a position of an optical axis 133 of the focusing lens 130 is recognized by the camera 50. As shown in
In one embodiment, the pickup component 60 is a suction nozzle which is able to precisely sucks a position on the surface convex surface 1321 corresponding to the optical axis 133 without damaging or tilting the focusing lens 130. In another embodiment, the pickup component 60 is a clamp tool or a tweezer.
In the step S120, a core end facet 122a of the first optical fiber 122, disposed on the fiber array 110, is recognized by the camera 50. As shown in
In the step S130, a projection P1 of the core end facet 122a of the first optical fiber 120 on the bonding surface 113 of the fiber array 110 is specified by a processing unit (not shown in the drawings) to obtain a core end facet information. In one embodiment, the position of the projection P1 on the bonding surface 113 is specified with a first core pair of reference coordinates; that is, the core end facet information includes the first core pair of reference coordinates. The first core pair of reference coordinates can be stored in a storage medium or marked on a display showing an image 51 of the camera 50.
The processing unit is any device in a computer or network that handles intermediate stage. For example, the processing unit may be a central processing unit (CPU), a motherboard or an image processing software. The storage medium is a device or a material used to place, keep and retrieve electronic data. It refers to a physical device or component in a computing system that receives and retains information relating to applications and users, such as hard disk drive or solid-state drive.
In one embodiment, the first core pair of reference coordinates corresponds to a center 1221 of the core end facet 122a of the first optical fiber 120a. In detail, the position of the core end facet 122a is interpreted as the center 1221 of the core end facet 122a of the first optical fiber 120a.
In the step S140, an alignment procedure is performed by the pickup component 60 according to the core end facet information to make the optical axis 133 of the focusing lens 130 overlap with the projection P of the core end facet 122a of the first optical fiber 120a. As shown in
In the step S150, the focusing lens 130 is attached to the bonding surface 113 of the fiber array 110. In detail, ultra violet (UV) glue is dispersed on either the bonding surface 113 of the fiber array 110 or the focusing lens 130, and the focusing lens 130 is firmly attached to the bonding surface 113 by UV curing. It is worth noting that the attachment of the focusing lens 130 to the fiber array 110 by UV curing in the present disclosure is not limited by the above. In some other embodiments, the focusing lens is attached to the fiber array by heating.
The fiber array 110 bonded with the focusing lens 130 is used as an optical component in an optical transceiver. When light in the first optical fiber 120a is reflected by the core end facet 122a and passes through the focusing lens 130, the light converges to a spot to be received by an optical receiver. The focusing lens 130 is for reducing a spot size of light, thereby improving coupling efficiency to meet the demand of high communication speed.
Traditionally, the alignment of the focusing lens 130 with the fiber array 110 is performed according to the corner, the left edge 114 or the right edge 115 of the fiber array 110. For example, the optical axis 133 of the focusing lens 130 is firstly aligned with the left edge 114. Then, the focusing lens 130 is moved again by a calculated distance between the left edge 114 and the core 121a of the first optical fiber 120a on the core end facet 122a.
In the first embodiment, the alignment of the focusing lens 130 with the fiber array 110 is performed according to the projection of the core end facet 122a of the first optical fiber 120a on the bonding surface 113 (the core end facet information; more specifically, the first core pair of reference coordinates). Thus, the alignment is accomplished by executing only one movement of the focusing lens 130, thereby resulting in better accuracy of alignment compared to the traditional approach.
In the second embodiment, a method of bonding the focusing lens 230 with the fiber array 110 is basically similar to the method disclosed in the first embodiment.
Firstly, in the step 210, both a projection P1 of the core end facet 122a of the first optical fiber 120a and a projection P2 of the core end facet 122b of the second optical fiber 120b on the bonding surface 113 of the fiber array 110 is specified by the processing unit to obtain a core end facet information. As shown in
In one embodiment, the first core pair of reference coordinates corresponds to a center 1221 of the core end facet 122a of the first optical fiber 120a, and the second core pair of reference coordinates corresponds to a center 1222 of the core end facet 122b of the second optical fiber 120b.
Next, in the step S220, a first line segment L1 between the two projections P1 and P2 (the first core pair of reference coordinates and the second core pair of reference coordinates) is defined. As shown in
In the step S230, the two optical axes 233 of the focusing lens 230 are recognized by the camera 50. As shown in
In the step S240, a second line segment L2 between the two optical axes 233 of the focusing lens 230 is defined. As shown in
In the step S250, the focusing lens 230 is rotated to make the second line segment L2 between the two optical axes 233 of the focusing lens 230 parallel to the first line segment L1 between the first axis pair of reference coordinates and the second axis pair of reference coordinates. As shown in
In the step S260, an alignment procedure is performed by the pickup component 60 according to the core end facet information to make one optical axis 233 of the focusing lens 230 overlap with the projection P1 of the core end facet 122a of the first optical fiber 120a, and make the other optical axis 233 overlap with the projection P2 of the core end facet 122b of the second optical fiber 120b. As shown in
Finally, the focusing lens 230 is attached to the bonding surface 113 of the fiber array 110. The detail of attachment can be referred to the step S140 in the first embodiment.
According to the present disclosure, the alignment of the focusing lens with the fiber array is performed according to the projection of the core end facet of the optical fiber on the bonding surface of the fiber array. Thus, the alignment is accomplished by executing only one movement of the focusing lens, thereby resulting in better accuracy of alignment.
The fiber array bonded with the focusing lens is used as an optical component in an optical transceiver. When light in the optical fiber is reflected by the core end facet and passes through the focusing lens, the light converges to a spot to be received by an optical receiver. The focusing lens is favorable for reducing a spot size of light so as to improve coupling efficiency to meet the demand of high communication speed.
The embodiments are chosen and described in order to best explain the principles of the present disclosure and its practical applications, to thereby enable others skilled in the art to best utilize the present disclosure and various embodiments with various modifications as are suited to the particular use being contemplated. It is intended that the scope of the present disclosure is defined by the following claims and their equivalents.