An optical module according to the present invention includes: an optical device including an optical waveguide chip; an optical fiber block bonded to and arranged on an end face of the optical waveguide chip; an optical fiber that has one end optically connected to the optical waveguide chip via the optical fiber block; an optical fiber holding mechanism for holding the other end of the optical fiber; and an optical fiber carrier. The optical fiber is arranged while being curved from the optical fiber carrier toward the optical fiber block in a U-shape, and a wall structure is formed on the surface of the carrier while being adjacent to the optical fiber at, for example, a position on the outer side of the U-shaped curve of the optical fiber position at which the wall structure reduces a normal force of the optical fiber.

An optical ferrule has a different thermal expansion coefficient than a substrate to which a optical device is mounted, the ferrule optically coupling the device to one or more optical fibers. The optical ferrule includes and/or a cradle in which the ferrule is mounted include lateral and longitudinal engagement feature that ensure alignment with the optical device at an operating temperature, the ferrule expanding relative to the substrate when transitioning to the operating temperature.

There is provided a highly convenient package for an optical module in which a device can be mounted as it is even when the number and mounting position thereof are different according to the device to be mounted. The package includes a base plate having a top surface on which devices are assembled, an optical fiber mounting component mounted on the top surface of the base plate, a direct current electrical interface component and a high frequency electrical interface component mounted on the top surface of the base plate. The optical fiber mounting component and the electrical interface components are separately manufactured, separately assembled on the top surface of the base plate, and fixed in different modes. The optical fiber mounting component is fixed by fastening with screws and fixed by soldering, and the electrical interface components are fixed by fastening with the screws.

The present disclosure provides a smart watch and a method for measuring heart rate information. The smart watch includes a dial, a watchband, and a processing device disposed on the dial or inside the watchband. The processing device includes an optical emitter configured to emit light; an optical receiver configured to receive reflected light, the reflected light being generated by the light emitted by the optical emitter irradiating a skin for conversion into an electrical signal; and a processor configured to process the electrical signal to obtain heart rate information of a user.

Embodiments herein describe an optical system that includes a photonic integrated circuit (PIC) bonded to a package containing an electrical integrated circuit (EIC). However, this bond can prevent an edge coupler from optically aligning an optical fiber to an edge of the PIC in order to transfer optical signals. To provide room for the edge coupler, the PIC is arranged to overhang the package containing the EIC so that the package does not interfere with the ability of the edge coupler to align with the side or edge of the PIC. In this manner, an optical fiber can be optically aligned (e.g., butt coupled) to the edge of the PIC rather than having to use a grating coupler or some other less efficient optical coupling in order to transfer optical signals between the PIC and the optical fiber.

Disclosed herein are safety devices that are positioned on the end of a fiberoptic cable, such as those used in surgical procedures, to prevent patients and other objects from the risk of burn from light or heat emitted from the end of the cable when not connected to an optical instrument. The disclosed safety devices can be added to the ends of existing cables and/or can be included at the end of cables during manufacture. In some embodiments, the safety device replaces an existing connector at the end of a cable, and in some embodiments the safety device is added in addition to a connector at the end of the cable. In some embodiments, a slit end cover is included over an open end of an adaptor that is mounted on a distal connector of a fiberoptic cable.

An apparatus for coupling a laser and an optical fiber and an optical signal transmission system and transmission method where the coupling apparatus is disposed between a laser and an optical fiber, where the coupling apparatus includes an optical signal transmission part whose inner refractive index changes gradually, where a refractive index becomes higher at a position closer to a principal axis of the optical signal transmission part; and the optical signal transmission part may be configured to shape an optical signal incident from the laser (including optical signal convergence or divergence), so that a mode field radius of the adjusted optical signal matches a core radius of the optical fiber, and the adjusted optical signal can be coupled into the optical fiber in high efficiency.

A micro optical engine assembly including a printed circuit board, a frame mounted on the printed circuit board, a micro optical engine mounted on the printed circuit board within a central space of the frame, a jumper having a lens-carrying end placed on top of the micro optical engine and aligned therewith by alignment members to thereby limit horizontal movement of the jumper, and a latch having a snap mechanism releasably snapped onto the frame, and at least one spring plate resiliently pressing against an upper surface of the jumper when the latch is snapped onto the frame to thereby limit vertical movement of the jumper.

An optical transceiver that includes a housing, an inner ceiling, and an outer ceiling. The housing includes sides and a bottom. The inner ceiling is assembled with the housing; while, the outer ceiling is fit with the housing. The outer ceiling, which forms a cavity accompanied with the housing, is fastened with the inner ceiling by a screw inserted into a screw hole.

The present disclosure is generally directed to a holder that can be used to couple to and optically align an optical component with, for instance, an associated light path to launch or receive optical channel wavelengths along the same. The holder preferably includes a receptacle to couple to the optical component and a mounting section enables the holder to be securely coupled to a substrate in a manner that minimizes or otherwise reduces introducing component shift and resulting optical misalignment.