One example includes an optical interconnect device. The optical interconnect device includes a plurality of optical fiber ports coupled to a body portion. The optical interconnect device also includes a plurality of optical fibers that are secured within the body portion. A first portion of the plurality of optical fibers can extend from a first of the plurality of optical fiber ports to a second of the plurality of optical fiber ports, and a second portion of the plurality of optical fibers can extend from the first of the plurality of optical fiber ports to a third of the plurality of optical fiber ports.

A fiber selector includes: a plurality of first reflecting members corresponding to a plurality of focusing optical systems which focus a laser beam from a collimating optical system, and equipped with a reflecting surface capable of reflecting the laser beam towards the focusing optical system; a rotary motor that rotationally moves the first reflecting member between a first position at which the laser beam reflects and a second position which does not block the laser beam, in which the fiber selector rotationally moves the plurality of first reflecting members between the first position and second position so as to selectively switch the propagating direction of the laser beam to any of the plurality of focusing optical systems, in which the reflecting surface of the first reflecting member is a plane perpendicular to the rotation axis of the shaft to which this first reflecting member is fixed, and is arranged so as to face the direction of the rotary motor that causes the shaft to which this first reflecting member is fixed to rotate.

An optical branch module including a glass block, an input/output gradient index lens, an output gradient index lens, a beam splitter film, a mirror film, an input optical fiber, a first output optical fiber that extracts input light from the input optical fiber reflected by the beam splitter film as first output light, and a second output optical fiber that extracts light passed through the beam splitter film passed through the glass block, reflected by the mirror film, passed through the glass block again, and input from the other end of the output gradient index lens as second output light.

A DEVICE FOR MULTI-PLANE CONVERSION OF A FIRST LIGHT RADIATION, HAVING A CONVERSION BLOCK COMPRISING A PLURALITY OF OPTICAL PARTS AND IMPLEMENTING A PLURALITY OF PHASE MASKS TO APPLY A SPATIOFREQUENTIAL PHASE SHIFT FOR PRODUCING A SECOND LIGHT RADIATIONA PREDETERMINED TRANSFORMATION, KNOWN AS A TRANSFORMATION WITH SEPARABLE VARIABLES. THE PREDETERMINED TRANSFORMATION MAY LINK N MODES OF INDEX {I, J}.sub.K, 1<=K<=N, OF A FIRST USED MODE FAMILY WITH SEPARABLE SPATIAL VARIABLES (X,Y) DESCRIBING THE FIRST LIGHT RADIATION IN A FIRST TRANSVERSE PLANE WITH N MODES OF THE SAME INDEX {I, J}.sub.K 1<=K<=N, OF A SECOND USED MODE FAMILY WITH SEPARABLE SPATIAL VARIABLES (X,Y) DESCRIBING THE SECOND LIGHT RADIATION AT A SECOND TRANSVERSE PLANE. THE N MODES OF THE SECOND MODE FAMILY ARE NOT BE HERMITE-GAUSSIAN MODES. THE N MODES OF THE FIRST MODE FAMILY ARE NOT ARRANGED ON THE FIRST TRANSVERSE PLANE IN THE FORM OF A TRIANGLE.

Configurations for an optical splitter that includes a continuous curved reflector and methods thereof are disclosed. The optical splitter includes an input waveguide, one or more continuous curved reflector, and multiple output waveguides. The one or more continuous curved reflector may direct light toward the output waveguides. The optical splitter may include a single continuous curved reflector, or may include multiple continuous curved reflectors. In other instances, an optical splitter may include a lensed reflector that includes a plurality of continuous curved segments.

A waveguide may include a substrate and an array of beam splitters embedded within the substrate, where each beam splitter within the array of beam splitters does not fully transect the substrate. Various other devices, systems, and methods of manufacture are also disclosed.

A sensing method for in-situ non-perturbing measurement of characteristics of laser beams at the exit of the laser beam delivery fiber tips include measuring power of a laser beam transmitted through delivery fiber tip in fiber-optics systems. A sensing devices for in-situ non-perturbing sensing and control of multiple characteristics of laser light transmitted through light delivery fiber tips includes a fiber-tip coupler comprised of a shell with enclosed delivery fiber having a specially designed angle-cleaved endcap and one or several tap fibers that are specially arranged and assembled at back side of the endcap and other variations. Methods and system architectures for in-situ non-perturbing control of characteristics of laser beams at the exit of the laser beam delivery fiber tips include fiber-tip couplers and sensing modules that receive laser light from tap fibers, and systems for optical processing to enhance light characteristics suitable for in-situ measurement.

An optical module according to an embodiment includes a first optical component and a second optical component including a multicore fiber (MCF) and a spatial joining part. The first optical component includes a first uncoupled MCF having small optical coupling between cores and a first coupled MCF having a mode field diameter (MFD) larger than a MFD of the first uncoupled MCF. The second optical component includes a second uncoupled MCF having small optical coupling between cores and a second coupled MCF having a MFD larger than a MFD of the second uncoupled MCF. In the first coupled MCF and the second coupled MCF, crosstalk is periodically produced along the length direction of an MCF, and the total of the length of the first coupled MCF and the length of the second coupled MCF is a length L in which crosstalk is suppressed.

An optoelectronic device (20, 50) includes a planar substrate (30), an optical bus (40, 82, 84, 96, 140, 150, 180, 182, 224) disposed on the substrate and configured to convey coherent radiation through the bus, and an array (32, 72) of sensing cells (34, 74, 90, 160, 170, 200, 212, 380) disposed on the substrate. Each sensing cell includes at least one tap (92, 94, 144, 146, 226, 228) coupled to extract a portion of the coherent radiation propagating through the optical bus, an optical transducer (36, 108, 162, 172, 202, 204, 214) configured to couple optical radiation between the sensing cell and a target external to the substrate, and a receiver (114, 174, 178, 216, 218), which is coupled to mix the coherent radiation extracted by the tap with the optical radiation received by the optical transducer and to output an electrical signal responsively to the mixed radiation.

A luminaire for use in lighting a large open space such as a parking lot or deck of a parking garage includes a plurality of optical waveguides disposed in side-by-side relationship and together defining a closed path and at least one LED associated with each optical waveguide and disposed at a first end of the associated optical waveguide.