An optical path change element includes a first facet that receives incidence of light beams outgoing from outgoing portions of a first optical element, a second facet that has a predetermined radius of curvature and is provided with a reflection face to reflect the incident light beams from the first facet, and a third facet causing the light beams reflected on the reflection face to outgo to the incident portions of a second optical element. The second facet has protruded faces spaced from the reflection faces. Virtual planes tangent to the protruded faces are defined. At least one of the virtual planes covers the reflection face without being tangent to the reflection face and being parallel with a tangent plane at an arbitrary point of the reflection face.

A coaxial transmitter optical subassembly (TOSA) including a ball lens may be used in an optical transceiver for transmitting an optical signal at a channel wavelength. The coaxial TOSA includes a laser package with a ball lens holder section defining a lens holder cavity that receives the ball lens. The lens holder cavity is dimensioned such that the ball lens is positioned in substantial alignment with the laser diode for optically coupling a laser output from the laser diode into an optical waveguide at an optical coupling end of the TOSA. The coaxial TOSA is thus configured to allow the less expensive ball lens to be used in a relatively small package when a lower coupling efficiency and power is desired and without substantial redesign of the TOSA.

There are provided a lens member, a method of manufacturing the lens member, a communication module, a lens array, and a light-source module, the lens member including a ready-made glass lens added with a mounting portion having a reference face as a plane for reference when the glass lens is mounted on a substrate. A lens member includes a glass ball lens to which sphericity processing has been previously performed, and a resin mounting portion 13 disposed on the glass ball lens. The mounting portion is molded by flowing the resin in a flowable state into a die including the glass ball lens disposed therein. The mounting portion includes a reference face that abuts on a mounting face in a case where the glass ball lens is surface-mounted, provided thereto.

There is provided an optical module, which includes a substrate; one or more optical devices disposed on the substrate; an integrated circuit (IC) device disposed on the substrate for driving the one or more optical devices; one or more optical fibers in optical communications with the one or more optical devices, respectively; an optical bench that attaches to the substrate and concentrates a direction of the light transmitted between the one or more optical devices and the one or more optical fibers; and a cover that attaches to the optical bench with the one or more optical fibers fixed therebetween. The optical bench changes a direction of the concentrated light.

A bi-directional optical module that provides an Rx unit and a Tx unit, where optical axes are perpendicular to each other, is disclosed. The optical module provides a housing that installs a WDM filter therein and assembles the coupling unit in a surface through the front alignment unit, the Tx unit in another surface opposite to the former surface, and the Rx unit in still another surface connecting the former two surfaces through the rear alignment unit. The axes of the Tx unit and the coupling unit are in parallel to each other, but the axis of the Rx unit is in perpendicular to the former two axes. The Rx unit installs a photodiode (PD) with an optically sensitive surface leveled with the surface of the rear alignment unit to which the Rx unit is attached.

An optical connection module includes a substrate, a light source, an optical detector, at least one first optical channel, at least one second optical channel, an oblique surface and a light guide device. The light source is disposed on the substrate and is configured to emit a first light. The first optical channel is configured to transmit the first light, and the light guide device is configured to guide the first light propagating from the light source into the first optical channel in a manner of light transmission. The optical detector is disposed on the substrate and is configured to receive a second light. The second optical channel is configured to transmit the second light, and the oblique surface is configured to guide the second light propagating from the second optical channel into the optical detector in a manner of reflection.

An optical assembly includes a base plate, a light transmitting component arranged on the base plate, a lens component arranged on the base plate along an optical path of light transmitted from the light transmitting component, a supporting member, and an auxiliary member. The supporting member includes a bottom surface that bonds to the base plate and a side surface that connects to the auxiliary member. The auxiliary member includes a side surface on which the lens component is disposed and a bonding surface that bonds to the side surface of the supporting member. The lens component is configured to focus and couple, or collimate, an optical signal transmitted from the light transmitting component. A bottom surface of the auxiliary member and a bottom surface of the lens component are both higher than the top surface of the base plate.

The present disclosure generally relates to devices, which may be used in communication or optoelectronic modules for example, suitable for arrayed positioning of a plurality of fiber optical components. In one form, an optoelectronic module includes a printed circuit board (PCB) and at least one optical component array device including an array of laterally or radially spaced receptacles configured to receive an optical component. One or more of the receptacles includes a fused fiber optical component positioned therein. A recursive fiber may extend between an output of a first fused fiber optical component and an input of a second fused fiber optical component, and an optical fiber routing member may be coupled to the PCB and include a plurality of guides extending away from the PCB and defining a pathway for routing optical fibers relative to the PCB.

A receptacle with lens can be mounted to an optimum position without monitoring an optical power. In an optical module constructed by a photonic device, a photonic device pedestal mounting the photonic device thereto, a TO-CAN stem, a cap with window glass, and a receptacle with lens, the TO-CAN stem is fitted to the receptacle with lens, the receptacle with lens is provided with a lens which can obtain a predetermined coupling efficiency between the photonic device and an optical fiber mounted to the receptacle with lens, and the TO-CAN stem is fitted with no alignment and bonded and fixed to the receptacle with lens. Therefore, the optimum mounting position of the receptacle with lens is achieved only by the mounting accuracy of the photonic device and the parts dimensional tolerances of the TO-CAN stem and the receptacle with lens without directly monitoring the optical power from the photonic device.

Pluggable optical transceiver modules are described herein that are specifically configured to preclude use of fiber jumpers inside of the module. The pluggable optical transceiver modules include an on-board application-specific integrated circuit (ASIC), optical transceiver, and an optical socket allowing a fiber to connect to the optical transceiver. Pluggable optical transceiver modules implement an opto-mechanical interface between an external fiber cable (attached to the pluggable optical transceiver module) and the optical transceiver in manner that does not require the fiber jumper, while ensuring tight alignment tolerances. In some embodiments, optical transceiver modules are designed to achieve a direct opt-mechanical coupling between the external fiber cable and on-board opto-electrical components (e.g., optical transceiver). For example, an adaptor is distinctly designed, directly connecting an external cable to the optical socket (eliminating the use of fiber jumper and faceplate connector in the module). In some embodiments, a rigid body opto-mechanical interface is used.