Disclosed herein are safety devices that are positioned on the end of a fiberoptic cable, such as those used in surgical procedures, to prevent patients and other objects from the risk of burn from light or heat emitted from the end of the cable when not connected to an optical instrument. The disclosed safety devices can be added to the ends of existing cables and/or can be included at the end of cables during manufacture. In some embodiments, the safety device replaces an existing connector at the end of a cable, and in some embodiments the safety device is added in addition to a connector at the end of the cable. In some embodiments, a slit end cover is included over an open end of an adaptor that is mounted on a distal connector of a fiberoptic cable.

Disclosed herein are safety devices that are positioned on the end of a fiberoptic cable, such as those used in surgical procedures, to prevent patients and other objects from the risk of burn from light or heat emitted from the end of the cable when not connected to an optical instrument. The disclosed safety devices can be added to the ends of existing cables and/or can be included at the end of cables during manufacture. In some embodiments, the safety device replaces an existing connector at the end of a cable, and in some embodiments the safety device is added in addition to a connector at the end of the cable. In some embodiments, a slit end cover is included over an open end of an adaptor that is mounted on a distal connector of a fiberoptic cable.

An opto-electric hybrid board connector includes an opto-electric hybrid board, a connector, and an adhesive member. The board has a bottom surface, a first side surface, and a second side surface. The connector has an inner bottom surface, a first inner side surface, and a second inner side surface. The adhesive member includes a first adhesive member having contact with the inner bottom surface, first inner side surface, and first side surface facing a first gap, and a second adhesive member filled in the first gap and having contact with the inner bottom surface, second inner side surface, and second side surface facing a second gap. A ratio (L1/L0) of a width L1 of the first gap to a width L0 of the inner bottom surface, and a ratio (L2/L0) of a width L2 of the second gap to the width L0 of the inner bottom surface are 0.01 or more.

An opto-electric hybrid board connector includes an opto-electric hybrid board, a connector, and an adhesive member. The board has a bottom surface, a first side surface, and a second side surface. The connector has an inner bottom surface, a first inner side surface, and a second inner side surface. The adhesive member includes a first adhesive member having contact with the inner bottom surface, first inner side surface, and first side surface facing a first gap, and a second adhesive member filled in the first gap and having contact with the inner bottom surface, second inner side surface, and second side surface facing a second gap. A ratio (L1/L0) of a width L1 of the first gap to a width L0 of the inner bottom surface, and a ratio (L2/L0) of a width L2 of the second gap to the width L0 of the inner bottom surface are 0.01 or more.

A cable assembly for optical monitoring is assembled by laying optical fibers into an adhesive layer on a substrate to form an optical circuit. First ends of the fibers are arranged in various groups and second ends of the fibers are arranged in various groups. Groups at a first end of the circuit are spliced to coupler input fibers and coupler output fibers. Groups at the second end of the circuit are terminated at one or more input connectors, one or more output connectors, and one or more monitoring connectors. Some cable assemblies monitor signals received at the input connectors. Other cable assemblies monitor signals received at both the input connectors and the output connectors.

Structures for an edge coupler and methods of fabricating a structure for an edge coupler. A first waveguide core has a first section that has a tapered shape and a second section that is adjoined to the first section. Multiple segments are positioned with a spaced arrangement adjacent to an end surface of the second section of the first waveguide core. A slab layer is adjoined to the first section of the first waveguide core. A second waveguide core has a section that overlaps with the first section of the first waveguide core to define a layer stack. The section of the second waveguide core has a tapered shape, and the first and second waveguide cores are comprised of different materials. The first section of the first waveguide core has a first thickness, and the slab layer has a second thickness that is less than the first thickness.

Cable fixation assemblies for telecommunications systems. A cable support body of a cable fixation assembly defines a tie wrap passage. The tie wrap passage includes features that can improve tie wrap tightening control and/or a preferred tie wrap advancement direction when securing a cable to the cable support with the tie wrap.

An optical assembly includes stacked planar lightwave circuit (PLC) members each having a plurality of waveguides in a respective plane, to provide optical connections to two-dimensional arrays of external optical waveguides (e.g., optical fiber cores), with one array including non-coplanar groups of waveguides having group members that are alternately arranged in a lateral direction. An optical assembly may provide optical connections between array of cores having a different pitch and/or orientation to serve as a fanout interface. Methods for fabricating an optical assembly are further provided.

An optical connection identification assembly includes first and second connectors for conveying optical signals within and away from the optical connection identification assembly, first and second optical filters configured for conveying optical signals to and from the respective first and second connectors and between each other, and first and second photodiodes. The first photodiode is configured for receiving optical signals from the first optical filter to confirm the optical connection identification assembly is receiving optical signals. The second photodiode is configured for receiving optical signals from the second optical filter to confirm the optical connection identification assembly is receiving optical signals. The first and the second connectors are on opposite sides of each of the first and the second optical filters and each of the first and the second photodiodes. Multiple optical connection identification assemblies are used in a system to prepare a connectivity map of a fiber optic system.

An incorrect insertion and removal prevention system that can prevent an operator from incorrectly selecting a port to be operated without sacrificing the port mounting density is described. An optical transmission device 100 of the incorrect insertion and removal prevention system includes a plurality of ports 101 for transmitting and receiving an external signal, a touch sensor 102 installed in each of the ports 101 to detect a contact of the human body, a control unit 110 for causing a display unit 130 to display information about the port 101 corresponding to the touch sensor 102 detecting the contact of the human body, a storage unit 120 for storing information for distinguishing each port 101, and the display unit 130 for displaying the information for distinguishing each port 101.