A clip is provided. The clip includes first and second shells shaped to mate around a band. An inward facing surface of the first shell has a lateral groove shaped to accommodate the fiber optic filament of the band and at least one protrusion. When the first and second shells are mated around the band the at least one protrusion passes through one of the holes in the band and engages a matching groove in an inward facing surface of the second shell. The first and second shells have a shape such that, when the first shell and the second shell mate around the band and lock into the connector, the first shell and the second shell collectively block any exterior light from reaching the light detection circuitry of the connector along the path of the band other than light through the fiber optic filament.

An optical fiber sensing system according to the present disclosure includes an optical fiber (10) that detects vibration, a detection unit (21) that detects occurrence of a predetermined event, based on an optical signal on which vibration detected by the optical fiber (10) is superimposed, an identification unit (22) that identifies an occurrence location of the predetermined event, based on the optical signal, and identifies a movement destination area serving as a moving destination of an unmanned aerial vehicle that monitors an occurrence location of the predetermined event, based on an occurrence location of the predetermined event, and a control unit (23) that controls the unmanned aerial vehicle to move to the movement destination area.

Apparatus for monitoring a building having a plurality of rooms. A plurality of beacons is each arranged to transmit a light output signal. The apparatus also comprises a plurality of waveguides suitable for deployment in the building so that each of the plurality of rooms has at least one of the waveguides arranged to receive the light output signal from one or more of the beacons when said one or more of the beacons is active in that room. There is at least one signal capture unit arranged to receive, via the waveguides, the light output signals resulting from the beacons in the rooms. A signal processor is arranged to distinguish, in use, the light output signal from a first beacon in a first room from the light output signal from a second beacon in a second, different, room.

Systems and techniques are provided for sensor device. A sensor device may include a housing, a lens inserted into a first opening of the housing, a metal mask covering a portion of the interior of the lens, a passive infrared (PIR) sensor underneath the lens and the metal mask, and a light pipe around the PIR sensor, the lens, and the metal mask. Part of the light pipe may be positioned above an activation mechanism for a button. An airflow gasket may be around the PIR sensor. A filter circuit board may be under the PIR sensor and connected to leads of the PIR sensor. A control circuit board may include the activation mechanism for the button. A backplate may include a slot for attachment to a snap of a magazine in the housing of the sensor device.

Systems and techniques are provided for sensor device. A sensor device may include a housing, a lens inserted into a first opening of the housing, a metal mask covering a portion of the interior of the lens, a passive infrared (PIR) sensor underneath the lens and the metal mask, and a light pipe around the PIR sensor, the lens, and the metal mask. Part of the light pipe may be positioned above an activation mechanism for a button. An airflow gasket may be around the PIR sensor. A filter circuit board may be under the PIR sensor and connected to leads of the PIR sensor. A control circuit board may include the activation mechanism for the button. A backplate may include a slot for attachment to a snap of a magazine in the housing of the sensor device.

In an optical fiber monitoring system which detects physical disturbance or other parameters such as temperature or strain of a fiber where a monitor signal is transmitted along the optical fiber and analyzed to detect changes which are indicative of an event, a method is provided for periodically checking proper operation of the optical fiber monitoring system. A fiber disturbance actuator periodically causes a pattern of disturbances of a portion of the fiber at a predetermined location thereon where the disturbance is characteristic of the event to be monitored. The monitor signal is analyzed to detect the pattern of changes and in the event that expected changes are not detected, a warning is issued that the intrusion detection system is not properly operating.

In an optical fiber monitoring system which detects physical disturbance or other parameters such as temperature or strain of a fiber where a monitor signal is transmitted along the optical fiber and analyzed to detect changes which are indicative of an event, a method is provided for periodically checking proper operation of the optical fiber monitoring system. A fiber disturbance actuator periodically causes a pattern of disturbances of a portion of the fiber at a predetermined location thereon where the disturbance is characteristic of the event to be monitored. The monitor signal is analyzed to detect the pattern of changes and in the event that expected changes are not detected, a warning is issued that the intrusion detection system is not properly operating.

In an optical fiber monitoring system which detects physical disturbance or other parameters such as temperature or strain of a fiber where a monitor signal is transmitted along the optical fiber and analyzed to detect changes which are indicative of an event, a method is provided for periodically checking proper operation of the optical fiber monitoring system. A fiber disturbance actuator periodically causes a pattern of disturbances of a portion of the fiber at a predetermined location thereon where the disturbance is characteristic of the event to be monitored. The monitor signal is analyzed to detect the pattern of changes and in the event that expected changes are not detected, a warning is issued that the intrusion detection system is not properly operating.

The present invention relates to an optoelectronic sensor used with light curtains for monitoring a sensing field. The optoelectronic sensor includes at least one optical unit having at least one radiation emitting element and at least one radiation receiving element and a control unit for processing an output signal generated by said radiation receiving element and for generating a defined sensor signal based on the output signal. The optical unit has a diagnostic unit including a monitoring unit operable to monitor at least one parameter indicative of an operational status of the optical unit. The diagnostic unit includes a processing unit operable to generate a communication signal indicative of said operational status, and the diagnostic unit is arranged in a separately housed, detachable plug-in module. The processing unit comprises a wireless communication interface for wirelessly receiving and transmitting communication signals.

The present invention relates to an optoelectronic sensor used with light curtains for monitoring a sensing field. The optoelectronic sensor includes at least one optical unit having at least one radiation emitting element and at least one radiation receiving element and a control unit for processing an output signal generated by said radiation receiving element and for generating a defined sensor signal based on the output signal. The optical unit has a diagnostic unit including a monitoring unit operable to monitor at least one parameter indicative of an operational status of the optical unit. The diagnostic unit includes a processing unit operable to generate a communication signal indicative of said operational status, and the diagnostic unit is arranged in a separately housed, detachable plug-in module. The processing unit comprises a wireless communication interface for wirelessly receiving and transmitting communication signals.