Disclosed is a method and system for passively aligning optical fibers (4), a first waveguide array (62), and a second waveguide array (42) using chip-to-chip vertical evanescent optical waveguides (44) and (64), that can be used with fully automated die bonding equipment. The assembled system (2, 30, 60) can achieve high optical coupling and high process throughput for needs of high volume manufacturing of photonics, silicon photonics, and other applications that would benefit from aligning optical fibers to lasers efficiently.

The present invention relates to a guiding set for radio-electric waves comprising a pair of waveguides made up of a first waveguide and a second waveguide forming successive segments of a same transmission way for the radio-electric waves.

The set is characterized in that it further comprises a connecting piece comprising two plates arranged opposite one another while defining an inner space between them, and delimiting means delimiting, in the inner space, a radio-electric wave transmission channel, the transmission channel emerging on the one hand on the first waveguide and on the other hand on the second waveguide.

A system for monitoring a signal on an optical fiber includes a fiber optic connector having a housing couplable to a receptacle. An optical fiber that transmits a first optical signal has first fiber core at least partially surrounded by a cladding and has a first end terminating proximate the housing. The first optical signal is transmitted along the first fiber core. An optical tap has a first tap waveguide arranged and is configured to receive at least part of the first optical signal as a first tap signal. The first tap waveguide comprises an output port for the first tap signal for directing the tap signal to a detector unit. In other embodiments, a detector unit detects light from the optical signal that is propagating along the fiber cladding. The system is intended to permit a technician to easily and quickly, without having to remove a connector, determine whether an optical signal is propagating along a fiber cable.

Disclosed is a method and system for passively aligning optical fibers (4), a first waveguide array (62), and a second waveguide array (42) using chip-to-chip vertical evanescent optical waveguides (44) and (64), that can be used with fully automated die bonding equipment. The assembled system (2, 30, 60) can achieve high optical coupling and high process throughput for needs of high volume manufacturing of photonics, silicon photonics, and other applications that would benefit from aligning optical fibers to lasers efficiently.

An optical coupler that provides evanescent optical coupling includes an optical fiber and a waveguide. The optical fiber has a glass core, a glass inner cladding surrounding the glass core, and a polymeric outer cladding surrounding the glass inner cladding. The glass core and glass inner cladding define for the fiber a glass portion, which can be exposed at one end of the fiber by removing a portion of the polymeric outer cladding. The glass portion has a glass-portion surface. The waveguide has a waveguide core and a surface, and can be part of a photonic device. The glass portion of the fiber is interfaced with the waveguide to establish evanescent coupling between the fiber and the waveguide. Alignment features are used to facilitate aligning the fiber core to the waveguide core during the interfacing process to ensure suitable efficiency of the evanescent coupling.

An imaging apparatus comprises: (i) an illumination waveguide configured to propagate light by total internal reflection, wherein an evanescent field illuminates an object in close relation to the illumination waveguide; an array of light-sensitive areas arranged on a common substrate with the illumination waveguide for detecting light from the object; and (iii) a controller configured to control forming of an interference pattern in the illumination waveguide, wherein the interference pattern comprises at least one element of constructive interference for selectively illuminating a portion of the object, the at least one element having a dimension with a size in a range of 100 nm-10 m; wherein the controller is configured to sequentially change the interference pattern in relation to the object such that different portions are illuminated and light from different portions is sequentially detected.

Waveguide substrate connection systems and methods are provided herein. An example waveguide assembly comprises a first substrate having a first waveguide, a second substrate having a second waveguide, an adhesive, and one or more spacers. A height for the one or more spacers is less than 10 m. The adhesive and the one or more spacers provide a composite material configured to assist in securing the first substrate and the second substrate together to align the first waveguide and the second waveguide. When the first substrate and the second substrate are attached together via the adhesive, the one or more spacers are configured to maintain a desired gap spacing therebetween so as to optimize coupling efficiency between the first waveguide and the second waveguide. The desired gap spacing corresponds to the height for the one or more spacers.

Embodiments herein describe a photonic chip which includes a coupling interface for evanescently coupling the chip to a waveguide on an external substrate. In one embodiment, the photonic chip includes a tapered waveguide that aligns with a tapered waveguide on the external substrate. The respective tapers of the two waveguides are inverted such that as the width of the waveguide in the photonic chip decreases, the width of the waveguide on the external substrate increases. In one embodiment, these two waveguides form an adiabatic structure where the optical signal transfers between the waveguides with minimal or no coupling of the optical signal to other non-intended modes. Using the two waveguides, optical signals can be transmitted between the photonic chip and the external substrate.

A method of processing an optical fiber for coupling an external optical signal. The optical fiber has a longitudinal axis, an optical core, and an optical cladding. The method includes processing the optical cladding with a laser beam at a coupling point of the optical fiber along the longitudinal axis between a start and an end region. During the processing, an effective axis of the laser beam is arranged skew with respect to the longitudinal axis of the optical fiber so that the optical cladding is processed via an edge region of the laser beam, and the effective axis of the laser beam is guided along a movement axis which is parallel to or substantially parallel to the longitudinal axis of the optical fiber.

Systems and methods for the controlled delivery of laser light to target tissue using an improved waveguide. A waveguide controls transmission of wave energy to a target based on direct contact with the target. The waveguide comprises a propagation medium, a cladding causing the electromagnetic wave to be internally reflected in the medium, and an interface formed in the cladding and configured for direct contact with the target. A portion of the laser light penetrates through the cladding at the interface and propagates into the target while a portion internally reflects within the propagation medium.