A light source assembly having N outputs is disclosed. The assembly comprising: a light source arrangement arranged for supplying light to M inputs, where M an N independently of each other are integers and where M≥2 and M≤N; at least one optical couplers, each having at least one input arm and a plurality of output arms; and an integer number, P, of mode scramblers; The light source arrangement may comprise a broadband light source and a multimode coupler configured for receiving one or more light beams from the light source arrangement, wherein the one or more light beams being derived from the broadband light source and wherein a mode scrambler is arranged for mode scrambling one of said light beams before it enters the multimode coupler.

The present disclosure relates to a polarity detector for detecting polarity of a patch cord, that is capable of sequentially inputting an optical signal into channels of a connector of the patch cord, receiving the optical signal being output, and thereby discerning the polarity of the patch cord quickly and precisely. Particularly, the present disclosure is characterized to spectrally output the optical signal from the light source as a plurality of unit optical signals, and to selectively block or pass the spectrally output plurality of unit optical signals, by heat, and thereby effectively inputting the optical signal into each channel of the connector.

Embodiments herein describe a fiber array unit (FAU) configured to optically couple a photonic chip with a plurality of optical fibers. Epoxy can be used to bond the FAU to the photonic chip. However, curing the epoxy between the FAU and the photonic chip is difficult. As such, the FAU can include one or more optical windows etched into or completely through a non-transparent layer that overlap the epoxy disposed on the photonic chip. UV radiation can be emitted through the optical windows to cure the underlying epoxy. In one example, the windows can also be used for dispensing epoxy. In addition to the optical windows, the FAU can include alignment protrusions (e.g., frustums) which mate or interlock with respective alignment receivers in the photonic chip. Doing so may facilitate passive alignment of the optical fibers in the FAU to an optical interface in the photonic chip.

An optical semiconductor device includes a first optical coupler including a first input port and a second input port, a first optical branching device including a first output port and a second output port, a second optical coupler including a third input port and a fourth input port, a second optical branching device including a third output port and an fourth output port, a first single mode waveguide configured to connect the second input port and the first output port, a second single mode waveguide configured to connect the second output port and the third input port, a third single mode waveguide configured to connect the fourth input port and the third output port, and a fourth single mode waveguide configured to connect the fourth output port and the first input port.

A passive optical network includes a central office providing subscriber signals; a drop terminal; and a wave division multiplexer. A fiber distribution hub may split or separate out dedicated optical signals from subscriber optical signals between the central office and the drop terminal. The wave division multiplexer separates dedicated optical signals pertaining to a specific dedicated subscriber from other optical signals on the line received at the wave division multiplexer. The wave division multiplexer may be part of a cable or part of an intermediate service terminal.

A fiber optic communications arrangement includes a closure with an interior volume; the closure including at least one cable through-port in communication with the interior volume; and an expansion component attached to an exterior portion of the closure and having an interior region in communication with the closure interior volume. The expansion component includes ruggedized fiber optic adapters mounted thereto. Each of the ruggedized fiber optic adapters includes at least one connector port for receiving ruggedized fiber optic connectors.

An optical bus for multi-core processing providing optical data transfer between cores through a single planar waveguide employing a variable-thickness, light-propagation layer having a progressively changing effective refractive index in accordance with lateral position within the light-propagation layer such that light emission from a single light emitter in communication with one core is focused on each of multiple photodetectors in communication with its respective processer core.

A multichannel optical coupler can include an output optical coupler array and a plurality of optical fibers. At least two of the plurality of optical fibers can be connected together at an end opposite the output optical coupler array.

A fiber optic splitter module includes a body including a front wall, a rear wall, and first and second side walls together at least partially defining an interior space. The first side wall includes a tongue extending longitudinally along the first side wall, and the second side wall includes a first groove that is complementary to the tongue. The fiber optic splitter module also includes an optical splitter positioned in the interior space, an input fiber extending through the front wall or the rear wall into the interior space and optically coupled to the optical splitter, and a plurality of output fibers extending through the front wall or the rear wall into the interior space and optically coupled to the optical splitter.

An optical assembly including light sources emitting light beams having multiple wavelengths; fiber combiner(s) arranged to combine light beams into combined beam, light beams enter fiber combiner(s); optical homogenizer(s), combined beam having non-homogenous intensity profile received at third end and combined beam having homogeneous intensity profile exits at fourth end; first optical element(s) second optical element(s), between optical homogenizer(s) and light guide(s), first optical element(s) and second optical(s) element collectively steer combined beam towards light guide(s), when optical assembly in use, second optical element(s) is adjustable to steer combined beam; first actuator(s) coupled to first optical element(s); controller coupled to first actuator(s), controller generate first signal controlling first actuator(s) that combined beam is steered by first optical element(s) also causing vibration of first optical element(s) at randomized pattern.