A multi-port aggregated cable includes: a plurality of duplex optical fibers, each duplex optical fiber having a first end and a second end; a first optical interface attached to each of the duplex optical fibers at the first end thereof and defining multiple ports, one for each of the duplex optical fibers, the first optical interface aggregating the duplex optical fibers at the first end thereof; and a second optical interface attached to each of the duplex optical fibers at the second end thereof and defining multiple ports, one for each of the duplex optical fibers, the second optical interface aggregating the duplex optical fibers at the second end thereof.

An all-fiber optical beam switch mechanism includes a first length of fiber through which an incident optical beam having beam characteristics propagates along a first propagation path and which has a first refractive index profile (RIP). The first RIP enables, in response to an applied perturbation, modification of the optical beam to form an adjusted optical beam that is movable to propagate along a second propagation path. A second length of fiber is coupled to the first length of fiber and formed with multiple spaced-apart, non-coaxial confinement cores. A selected state of applied perturbation moves the second propagation path of the adjusted optical beam to a position of a selected corresponding one of the multiple confinement cores to confine and thereby direct the adjusted optical beam to a corresponding beam output location at the output of the second length of fiber.

An opto-mechanical fuse is provided. The opto-mechanical fuse includes a chassis component, an extrusion disposed on a monitored component proximate to the chassis component and a sensor. The sensor includes an optical conductor mounted to the chassis component to assume one of an optically transmitting state and an optically non-transmitting state in both power-on and power-off conditions. An assumption of the optically non-transmitting state by the optical conductor occurs due to an interaction of the optical conductor and the extrusion resulting from a predefined magnitude of deflection of the monitored component.

An optical membrane switch device includes a first membrane layer, a second membrane layer, and a spacer layer. The first membrane layer includes a first surface and light input lines. The light input lines are disposed on the first surface. Each light input line is slantingly extended with first branch lines. The second membrane layer includes a second surface and light output lines. The light output lines are disposed on the second surface. Each light output line is slantingly extended with second branch lines. The second branch lines respectively extend to the corresponding first branch lines to form contact regions. The spacer layer is clamped between the first membrane layer and the second membrane layer and includes through holes respectively corresponding to the contact regions. The first and second branch lines corresponding to the through holes at least partially overlap each other and keep a preset interval from each other.

An optical membrane switch device includes a first membrane layer, a second membrane layer, and a spacer layer. The first membrane layer includes a first surface and light input lines. The light input lines are disposed on the first surface. Each light input line is slantingly extended with first branch lines. The second membrane layer includes a second surface and light output lines. The light output lines are disposed on the second surface. Each light output line is slantingly extended with second branch lines. The second branch lines respectively extend to the corresponding first branch lines to form contact regions. The spacer layer is clamped between the first membrane layer and the second membrane layer and includes through holes respectively corresponding to the contact regions. The first and second branch lines corresponding to the through holes at least partially overlap each other and keep a preset interval from each other.

A variable optical attenuator (VOA) may include an input collimator with an input fiber connected on one side and an output collimator with an output fiber connected on one side, where the collimators are on a same surface of a VOA enclosure. A retroreflector may receive a light beam from the input collimator and reflect the light beam to the output collimator. The VOA may include an attenuation element positioned between the input collimator and the retroreflector and/or another attenuation element positioned between the retroreflector and the output collimator to provide variable attenuation to the light beam. The attenuation elements may be moved to set an attenuation level by one or more adjustment elements such as a miniature motor. The attenuation element may include a gradient index (GRIN) element, a polarizer, a neutral density filter, or a wavelength tunable filter.

A remote indicator system comprising a housing and a display unit located remotely from the housing. The housing comprises a first light source and a first end of an end-emitting fibre optic cable. The display unit comprises a second end of the fibre optic cable. The housing includes manual switching means configurable to allow light from the first light source to pass into the first end of the optical fibre cable and further configurable to prevent light from the first light source from passing into the first end of the optical fibre cable.

A lighting apparatus is composed of optical fibers that are grouped at one end thereof in a bundle so as to optically couple to a common light source. A set of the optical fibers are configured to emit light transversely to the optical axis thereof to form an illumination region in a fiber optic panel. At least one sensor is coupled to at least one of the optical fibers in the bundle and generates an electrical signal in response to a physical phenomenon.

Safety systems for operating equipment have a source of visible light, a first signal light transmitter, a first signal light receiver, preferably a second signal light transmitter and second signal light receiver. A fiber optic bundle with at least one section of illuminated cable emits the visible light and carries the signal light. The signal light follows an optical circuit through the fiber optic bundle from the signal light transmitters to the signal light receivers. The signal light receivers are connected to suitable controls of the system such that if a predetermined light signal is not received by the signal light receiver(s), the operating equipment will stop and/or alarms will be generated. The fiber optic bundle is connected to optical pull switches which interrupt the light circuit if a person applies a predetermined pull force to the optical fiber bundle.

A rotating or tilting MEMS structure, such as a tilt mirror for an optical device, includes a damping mechanism, provided by locating an inlay block structure underneath the MEMS rotating surface. Damping is created by the temporary squeezing or compression of the air, atmosphere, or gas(es) surrounding the MEMS structure, between the underside of the MEMS tilting surface and the top surface of the block. Movement of the MEMS surface away from the top surface of the block will also be damped by the temporary reduction in pressure. The block structure is fabricated separately from the MEMS tilt-mirror structure and located under the MEMS tilt-mirror structure, either before or during the die-attach or die-bonding process. The damping effect serves to minimize and limit the amplitude and duration of oscillatory motion of the MEMS tilt-mirror, following intentional movement of the mirror, or, in response to external shock and vibrational forces.