A mounting frame system is disclosed that facilitates the mounting of optical connector modules to printed circuit boards. The mounting frame system can include a mounting frame that is configured to attach to a printed circuit board, and is adapted to attach to a connector module. Thus, the mounting frame system can further allow releasable mounting of optical connector modules to the printed circuit board, such that the mounting is achieved in a safe and reliable manner.

An opto-electric hybrid board includes: an electric circuit board including electrical interconnect lines formed on the front surface of an insulation layer; a metal reinforcement layer formed partially on the back surface of the electric circuit board; an optical waveguide W configured to partially overlap the back surface of the electric circuit board E; and an second reinforcement layer formed on the back surface of the electric circuit board E. The second reinforcement layer allows the opto-electric hybrid board to have improved rigidity in a specific region and excellent handleability without incurring optical losses during optical coupling.

Disclosed are transceivers using a pluggable optical body. In one embodiment the transceiver comprises a transceiver receptacle body and a substrate assembly. The transceiver receptacle body comprises a front side, a rear side and at least one optical channel at the optical interface with the front side having at least one alignment pin and the rear side having at least one cavity. The substrate assembly comprises a substrate supporting at least one active electronic component and the substrate comprising at least one alignment feature for cooperating with the at least one alignment pin of the transceiver receptacle body. In one variation, one or more alignment pins may extend from the front side into the cavity of the transceiver receptacle body.

An optical device for implementing passive alignment of parts and a method therefor, more particularly an optical device and a method therefor that utilize an alignment reference part arranged on the substrate to passively align an optical element part with a lens-optical fiber connection part. For the passive alignment of parts, connection pillars of an alignment reference part are coupled to substrate holes, one or more light-emitting elements and one or more light-receiving elements are aligned in a row in a particular interval with respect to alignment holes arranged opposite each other in the alignment reference part, a lens-optical fiber connection part is aligned with respect to the alignment holes, and an optical fiber is aligned with the optical alignment point at a surface of a prism forming a portion of the lens-optical fiber connection part.

Optical communication apparatus includes a printed circuit board (PCB), a photoelectric unit electrically connected to the PCB, a supporting member positioned on the PCB, a coupler supported on the supporting member, and an optical fiber unit. The coupler optically couples the photoelectric unit to the optical fiber unit. The supporting member defines a through stepped hole having a larger first hole and a smaller second hole. The supporting member includes a step portion between the first hole and the second hole. The second hole is closer to the PCB than the first hole. The supporting member defines a number of positioning holes, and the coupler comprises a number of positioning poles corresponding to the positioning holes. The coupler is connected to the supporting member by inserting the positioning poles into the corresponding positioning holes.

An apparatus includes a first and second VCSEL, each with an integrated lens. The VCSELs emit a first light beam having first optical modes at first wavelengths and a second light beam having second optical modes at second wavelengths. The apparatus also has an optical block with a first and second surface, a mirror coupled to the second surface, and a wavelength-selective filter coupled to the first surface. The first integrated lens mode matches the first beam to the optical block, and the second integrated lens mode matches the second beam to the optical block such that the first beam and second beam each have substantially a beam waist with a beam waist dimension at the first and second input region, respectively. An exit beam that includes light from the first beam and the second beam is output from the second surface of the optical block.

An optical fiber securing device may include a passage, an optical fiber seat, and a boundary portion. The passage may have an entrance and an exit, the passage configured to receive therein an optical fiber inserted through the entrance, as well as an epoxy. An epoxy path may be provided as a pathway between an epoxy well and the passage. The optical fiber seat may be configured to receive at least a portion of the optical fiber, the optical fiber seat configured to position an end of the optical fiber in optical alignment with a lens. The boundary portion may define an upper boundary of the passage at the exit of the passage, and is configured to restrain epoxy received within the passage such that the epoxy does not become interposed between the end of the optical fiber and the lens.

Embodiments herein include an optical system, an optical component, and an associated method of passive alignment in which complementary magnetic patterns are used to provide passive alignment between optical elements. The magnetic coupling between the magnetic patterns operates to align optical elements in at least two dimensions. The magnetic coupling provides a temporary holding force on the optical elements until the optical elements are secured using epoxy or other adhesive.

An interposer for coupling an optical conduit to an optical component, said interposer comprising: (a) an optical component; (b) a first lens component having a first lens; (c) a second lens component having a second lens, said first and second lenses being configured to define an expanded-beam coupling therebetween; (d) at least one reflective surface optically coupled with said second lens; (e) a first optical path at least partially defined between said optical component and said first lens to accommodate a diverging light beam from said optical component to said first lens; (f) a second optical path at least partially defined between said second lens and said at least one reflective surface to accommodate a converging light beam from said second lens and said at least one reflective surface; and (g) a separable interface along said second optical path or at said expanded-beam coupling.

An optical fiber mounting mechanism includes an optical fiber, a signal circuit, and a mounting structure. The optical fiber extends along a first direction. The signal circuit extends along the first direction. The mounting structure is disposed at ends of the optical fiber and the signal circuit. The mounting structure surrounds the optical fiber and the signal circuit. The mounting structure has an installation portion. The installation portion extends radially relative to the first direction as the axis direction. The installation portion has a plurality of elements. The elements are exposed from a surface of the installation portion. The surface has a normal direction parallel with the first direction.