Optical connectors for connecting optical fiber to a light source are disclosed. In one embodiment, an optical connector includes a housing with a first end having an open aperture and a second end having a blind aperture. A chamber is disposed in the housing such that the optical axis of the housing passes through the chamber. The chamber includes a first material. A light collecting region formed from a second material is disposed in the housing between the second end of the housing and the chamber. A blind aperture is positioned in the light collecting region such that a termination of the blind aperture is spaced apart from the chamber by at least a portion of the second material. A refracting surface is disposed in the housing between the open aperture and the light collecting region such that the optical axis of the housing passes through the refracting surface.

An optical connector includes a housing in which a counterpart optical connector connected to a pair of optical fibers having a first optical fiber and a second optical fiber is fitted, a light emitting side lens portion accommodated in the housing, and in which a first end surface of the first optical fiber in the counterpart optical connector is disposed on one end side, a light receiving side lens portion accommodated in the housing, and in which a second end surface of the second optical fiber in the counterpart optical connector is disposed on one end side, a light emitting element disposed on the other end side of the light emitting side lens portion, and a light receiving element disposed on the other end side of the light receiving side lens portion.

The present invention relates to an optical device package in which a deterioration in performance of an optical device is suppressed which deterioration may be caused by dust on a light path. An optical device package (10) including a case (13, 14) in which an optical device (11) is sealed includes a lid (13) having an optical window (13a) which transmits light, and the optical device (11) is connected to the lid (13) such that at least part of an effective region (Ae) of the optical device (11) overlaps with the optical window (13a).

To provide an optical module and a method for aligning the optical module with which alignment can be easily performed. An optical module includes first optical element sections and a second optical element section optically joined to the first optical element sections. Each first optical element section includes an optical conversion element, a ferrule having a distal end being in contact with and optically joined to the second optical element section, and a first optical system disposed in a position where the ferrule and the optical conversion element are optically adjusted. The second optical element section includes joining sections in contact with and joined to, in joining parts, the distal ends of the ferrules, a wavelength multiplexing optical element optically joined to the optical conversion elements, and second optical systems respectively disposed in positions where the wavelength multiplexing optical elements and the joining parts are optically adjusted.

A fiber optic cable sub-assembly comprises a fiber optic cable including at least one optical fiber, a cable jacket that houses the optical fiber and at least one metal strength member. A collar is attached to an end portion of the metal strength member, wherein the optical fiber extends beyond an outer axial end of the collar. In another example a fiber optic cable assembly is fabricated from the fiber optic cable sub-assembly wherein a connector housing is attached to the collar, and an interface operably connects an end portion of the optical fiber to an active optical component within the connector housing. In further examples, methods of assembly for a fiber optic cable sub-assembly are provided along with using the sub-assembly for making a fiber optic cable assembly.

Embodiments described herein may be related to apparatuses, processes, and techniques related to active optical plugs used to cover optical connectors of a photonics package to protect the connectors. The active optical plugs may also be used to perform testing of the photonics package, including generating light to be sent to the photonics package and to detect light received from the photonics package as part of the test protocol. This allows testing the optical connection and the photonics package, without exposing the optical connections of the package to damage from dust or physical contact. Other embodiments may be described and/or claimed.

A connector includes an optical fiber and a case, and converts an optical signal input from the optical fiber into an electrical signal and outputs the electrical signal, or converts an input electrical signal into an optical signal and outputs the optical signal to the optical fiber. The case has a wall into which the optical fiber is inserted. The rear wall has an upper end and a lower end facing each other with a space therebetween so that the optical fiber intervenes in the space. The case includes an upper protruding wall protruding in the front-rear direction and a lower protruding wall protruding in the front-rear direction. Between the upper free end of the upper protruding wall and the lower free end of the lower protruding wall, a first space is defined so the optical fiber can freely move in the width direction.

An optoelectronic module may include a housing enclosing at least one optical transmitter or receiver, a release mechanism configured to engage with a cage sized and shaped to receive the housing, and a retainer including at least one occlusion member sized and shaped to be positioned inside a port of the optoelectronic module and a sleeve member configured to slide with respect to the occlusion member.

An optical functional device includes a package case accommodating an optical functional element, an input optical fiber, and an output optical fiber. The optical functional device includes a first reflecting surface that reflects input light output from the input optical fiber to an optical path of output light, a second reflecting surface that reflects the input light to the optical functional element, and a third reflecting surface that reflects the output light in a direction in which the output light becomes further away from an optical axis of the input optical fiber. An optical axis of a leaked light beam transmitted through the second reflecting surface after being reflected by the first reflecting surface or an extension line of the optical axis in an optical propagation medium does not include a portion that is aligned with an optical axis of the output light reflected by the third reflecting surface.

An optical transceiver includes a groove-shaped accommodating portion that extends in a longitudinal direction, the housing being configured to be inserted and removed from a cage of an external device. The optical transceiver includes a movable member attached to the housing and a leaf spring member accommodated in the accommodating portion. The spring member includes a first pressing portion pressing a protrusion toward a first surface of the accommodating portion. The spring member includes and a second pressing portion pressing, in the longitudinal direction, a second surface of the accommodating portion. An end of the spring member toward the first pressing portion is configured to curve away from the first surface of the accommodating portion in the longitudinal direction as a distance from first pressing portion increases.