A cable management system including a plurality of separably interconnectable clips. Each clip has a plurality of longitudinally extending cells, the cells forming cable channels having open longitudinal ends and an open bottom side, the cable channels arranged side-by-side in a one-dimensional array. Each cell is adapted and configured to receive and retain a corresponding cable of a slightly smaller diameter than that of its cable channel. The clips interconnect in a vertically stacked series to form a clip stack, the one-dimensional cable channel arrays of the clips in the clip stack thus being arrayed vertically to form a two-dimensional cable channel array. Cells without a clip connected below retain corresponding cables with a clearance to permit longitudinal sliding. Cables retained in a clip with a clip connected below are clamped between the cells that retain them and impinging contact regions of a top side of the below clip.

A vehicle lighting device including a light source configured to emit diverging light a fiber bundle including a plurality of optical fibers bundled into a cross sectional shape configured to be optically coupled to the light source; and a coupling device configured to optically couple the light source to the fiber bundle, the coupling device including a reflecting portion configured to reflect the diverging light toward the optical fiber bundle and a blocking portion configured to block light from bleeding from the assembly.

A fiber optic imaging element includes medium-expansion and a fabrication method including: (1) matching a core glass rod with a cladding glass tube to perform mono fiber drawing; (2) arranging the mono fibers into a mono fiber bundle rod, and then drawing the mono fiber bundle rod into a multi fiber; (3) arranging the multi fiber into a multi fiber bundle rod, and then drawing the multi fiber bundle rod into a multi-multi fiber; (4) cutting the multi-multi fiber, and then arranging the multi-multi fiber into a fiber assembly buddle, then putting the fiber assembly buddle into a mold of heat press fusion process, and performing the heat press fusion process to prepare a block of the fiber optic imaging element with medium-expansion; and (5) edged rounding, cutting and slicing,

A fiber optic imaging element includes medium-expansion and a fabrication method including: (1) matching a core glass rod with a cladding glass tube to perform mono fiber drawing; (2) arranging the mono fibers into a mono fiber bundle rod, and then drawing the mono fiber bundle rod into a multi fiber; (3) arranging the multi fiber into a multi fiber bundle rod, and then drawing the multi fiber bundle rod into a multi-multi fiber; (4) cutting the multi-multi fiber, and then arranging the multi-multi fiber into a fiber assembly buddle, then putting the fiber assembly buddle into a mold of heat press fusion process, and performing the heat press fusion process to prepare a block of the fiber optic imaging element with medium-expansion; and (5) edged rounding, cutting and slicing,

An apparatus for detecting an emission signal from each of a plurality of emission signal sources includes one or more excitation sources configured to generate an excitation light of an excitation wavelength and one or more associated emission detectors configured to detect light of an emission wavelength. A transmission fiber is associated with each of the emission signal sources. A carrier is configured to move the one or more excitation sources and the one or more emission detectors relative to the transmission fibers to sequentially place each emission detector and associated excitation source in an operative position with respect to each transmission fiber. Each transmission fiber transmits both the excitation light from the excitation source and the corresponding emission light to the associated emission detector.

An apparatus for detecting an emission signal from each of a plurality of emission signal sources includes one or more excitation sources configured to generate an excitation light of an excitation wavelength and one or more associated emission detectors configured to detect light of an emission wavelength. A transmission fiber is associated with each of the emission signal sources. A carrier is configured to move the one or more excitation sources and the one or more emission detectors relative to the transmission fibers to sequentially place each emission detector and associated excitation source in an operative position with respect to each transmission fiber. Each transmission fiber transmits both the excitation light from the excitation source and the corresponding emission light to the associated emission detector.

Exemplary optical scanner apparatus, method and computer-accessible medium for obtaining information regarding the sample can be provided. In certain exemplary embodiments of the present disclosure, the optical scanner, method and computer-accessible medium can utilize a container configured to hold the sample which is provided in a fluid. A light source can be provided which is configured to emit a light radiation to the container and the sample. Further, with an optic taper, it is possible to receive, taper and combine substantially parallel beams of an output radiation exiting the sample. The output radiation can be provided in response to an irradiation of the sample by the light radiation. Further, using a light detector, it is possible to receive and detect the combined tapered parallel beams so as to obtain the information regarding the sample.

Exemplary optical scanner apparatus, method and computer-accessible medium for obtaining information regarding the sample can be provided. In certain exemplary embodiments of the present disclosure, the optical scanner, method and computer-accessible medium can utilize a container configured to hold the sample which is provided in a fluid. A light source can be provided which is configured to emit a light radiation to the container and the sample. Further, with an optic taper, it is possible to receive, taper and combine substantially parallel beams of an output radiation exiting the sample. The output radiation can be provided in response to an irradiation of the sample by the light radiation. Further, using a light detector, it is possible to receive and detect the combined tapered parallel beams so as to obtain the information regarding the sample.

An aspect relates to a system with an optical faceplate for use with a two dimensional display. The optical faceplate comprises a contact surface at a bottom side of the optical faceplate for contacting the two dimensional display. The optical faceplate further comprises a three dimensional display surface at a top side of the optical faceplate, and an optic light guide material provided between the contact surface and the three dimensional display surface.

An aspect relates to a system with an optical faceplate for use with a two dimensional display. The optical faceplate comprises a contact surface at a bottom side of the optical faceplate for contacting the two dimensional display. The optical faceplate further comprises a three dimensional display surface at a top side of the optical faceplate, and an optic light guide material provided between the contact surface and the three dimensional display surface.