A marker system includes an enclosure with a controller therewithin. Emitters are electrically interfaced to the controller and include visible wavelength emitters and infrared wavelength emitters. The controller is configured to selectively initiate a flow of electric current though the visible wavelength emitters or through the infrared wavelength emitters causing the visible wavelength emitters or the infrared wavelength emitters to emit light and the light passes through the enclosure. There is at least one infrared detector, each of which is electrically interfaced to the controller and each of which is configured to detect infrared light that enters the enclosure. When the controller receives an electrical signal from any of the at least one infrared detector indicating reception of infrared light, the controller emits a signal to warn of the reception of infrared light (e.g., an audible signal, a vibration, a wireless signal, a wired signal).
A method of synchronizing flashing between a plurality of marker system components mounted on a helmet includes receiving a signal from at least one global positioning satellite receiver, the signal comprising a time value. When the time value indicates illumination is needed, initiating illumination of at least one light emitting device of each the marker system components, thereby, synchronizing of the initiating of illumination to the time value for all marker system components.
A safety switch includes an actuator that has a first possible actuator position and a second possible actuator position and a blocker that has a first possible blocker position and a second possible blocker position. The first possible blocker position overlaps with the second possible actuator position. The safety switch includes a device for generating an electrical signal representative of a current position of the actuator. When the actuator is in the first possible actuator position and the blocker is in the first possible blocker position, the blocker prevents movement of the actuator from the first possible actuator position to the second possible actuator position without first moving the blocker from the first possible blocker position to the second possible blocker position.
H01H 36/00 - Switches actuated by change of magnetic field or of electric field, e.g. by change of relative position of magnet and switch, by shielding
G08B 5/36 - Visible signalling systems, e.g. personal calling systems, remote indication of seats occupied using electromagnetic transmission using visible light sources
A42B 3/04 - Parts, details or accessories of helmets
4.
System, method, and apparatus for synchronizing local flashing in a marker system
A method of synchronizing flashing between a plurality of marker system components mounted on a helmet includes receiving a signal from at least one global positioning satellite receiver, the signal comprising a time value. When the time value indicates illumination is needed, initiating illumination of at least one light emitting device of each the marker system components, thereby, synchronizing of the initiating of illumination to the time value for all marker system components.
F21V 23/04 - Arrangement of electric circuit elements in or on lighting devices the elements being switches
F21V 23/00 - Arrangement of electric circuit elements in or on lighting devices
G08B 5/38 - Visible signalling systems, e.g. personal calling systems, remote indication of seats occupied using electromagnetic transmission using visible light sources using flashing light
5.
System, method, and apparatus for synchronizing flashing in a marker system
A method of synchronizing flashing of a plurality of marker systems includes within each marker system of the plurality of marker systems, receiving a signal from at least one global positioning satellite, the signal comprising a time value. Then, when initiating illumination of at least one light emitting device of the marker systems, synchronizing of the initiating illumination to the time value.
A helmet-mounted marker system includes one or more coordinates of one or more danger zones in digital format and a mechanism for periodically determining a location of the helmet-mounted marker system. From the location, another mechanism determines if the location of the helmet-mounted marker system is within any of the one or more danger zones. If the location of the helmet-mounted marker system is within any of the one or more danger zones, there is a mechanism to notify a wearer of the helmet-mounted marker system.
A drop zone marker includes a parachute, a first light module connected to the parachute by a first length of cord and a second light module connected to the first light module by a second length of the cord. A ballast is connected to the second light module by a third length of the cord is provided for pulling downwardly the drop zone marker. The parachute is configured to include an integral packing/deployment bag within which all components of the drop zone marker are contained up until deployment.
G08B 5/38 - Visible signalling systems, e.g. personal calling systems, remote indication of seats occupied using electromagnetic transmission using visible light sources using flashing light
B64D 47/02 - Arrangements or adaptations of signal or lighting devices
F21W 111/06 - Use or application of lighting devices or systems for signalling, marking or indicating, not provided for in groups for aircraft runways or the like
A marker system includes at least one emitter. The emitter(s) emit light responsive to a flow of electrical current there through. The marker system includes a device for acquiring an incoming signal and a circuit for processing the incoming signal. The circuit for processing the incoming signal monitors the device for acquiring the incoming signal to determine if the incoming signal includes any of a plurality of incoming Identification Friend or Foe (IFF) and/or munitions-targeting signals. The circuit emits one of a plurality of responses by sending electrical current selectively through the emitter(s) and/or other feedback devices based upon which of the plurality of incoming Identification Friend or Foe (IFF) and/or munitions-targeting signals is detected by the means for processing.
A marker system includes at least one emitter. The emitter(s) emit light responsive to a flow of electrical current there through. The marker system includes a device for acquiring an incoming signal and a circuit for processing the incoming signal. The circuit for processing the incoming signal monitors the device for acquiring the incoming signal to determine if the incoming signal includes any of a plurality of incoming Identification Friend or Foe (IFF) and/or munitions-targeting signals. The circuit emits one of a plurality of responses by sending electrical current selectively through the emitter(s) and/or other feedback devices based upon which of the plurality of incoming Identification Friend or Foe (IFF) and/or munitions-targeting signals is detected by the means for processing.
A marker system includes at least one emitter. The emitter(s) emit light responsive to a flow of electrical current there through. The marker system includes a device for acquiring an incoming signal and a circuit for processing the incoming signal. The circuit for processing the incoming signal monitors the device for acquiring the incoming signal to determine if the incoming signal includes any of a plurality of incoming Identification Friend or Foe (IFF) and/or munitions-targeting signals. The circuit emits one of a plurality of responses by sending electrical current selectively through the emitter(s) and/or other feedback devices based upon which of the plurality of incoming Identification Friend or Foe (IFF) and/or munitions-targeting signals is detected by the means for processing.
A helmet-mounted or helmet-integrated combination personnel marker/identification light and active “Identification Friend or Foe” (IFF) includes infrared interrogation and response capabilities. The IFF function provides acquisition and processing of an incoming IR laser IFF interrogation and then sends one or more user-defined responses to the interrogator and/or the user/wearer. A photo sensor array is designed to detect and identify incoming infrared signals. The array is arranged to provide omni-directional, line-of-sight sensing over more than a full hemisphere. A detachable user feedback module comprised of a vibratory pad and cable provides a user/wearer alert when infrared interrogation has been detected. An operating status switch allows the user/wearer to confirm that the device is in an active mode.
A marker system includes a controller with a plurality of emitters electrically interfaced to the controller such that, upon the controller initiating a flow of electric current though one or more of the emitters, the one or more of the emitters emit light. There is also at least one detector electrically interfaced to the controller. The detector(s) are for detecting light in of a specific wavelength and converting the light to an electrical signal that is then received by the controller. Software is stored on a non-transitory storage associated with the controller. The software monitors the at least one detector for an incoming IFF signal and the software initiating the flow of electric current through a selected set of the plurality of emitters responsive to receiving the incoming IFF signal from the at least one detector.
The device is a helmet-mounted or helmet-integrated combination personnel marker/identification light and active “Identification Friend or Foe” (IFF) infrared interrogation and response device. The IFF function provides acquisition and processing of an incoming IR laser IFF interrogation and then sends one or more user-defined responses to the interrogator and/or the user/wearer. A photo sensor array is designed to detect and identify incoming infrared signals. The array is arranged to provide omni-directional, line-of-sight sensing over more than a full hemisphere. A detachable user feedback module comprised of a vibratory pad and cable provides a user/wearer alert when infrared interrogation has been detected. An operating status switch allows the user/wearer to confirm that the device is in an active mode.
A multi-mode, multi-function marker/signaling device, capable of detachably mounting to helmets, has operating switches with positive visual and tactile cues located at opposing ends. A cover is attached to a base to provide a waterproof internal space. An electronic circuit board mounted within the waterproof space includes one or more visible and/or infrared emitters. Built-in programming provides user-defined and selectable modes of operation and multiple functions within those modes by means of serial manipulation of each switching means with a single digit. The emitters are multi-colored and/or infrared devices operating either steady ON, flashing, or coded flash, and are programmed to operate either independently or together. A replaceable battery provides power. A battery compartment is integral to and accessed from the underside (mounting surface) of the base.
An illumination/marker system mounted on a parachute slider is shown for identification, tracking, and collision avoidance in manned and unmanned parachute operations. The system includes a variety of emission/radiation sources (luminaires), and positioned at pre-determined locations on the parachute slider. A battery provides the power source. System activation means are provided automatically upon deployment of a parachute and/or slider, and/or other sensory inputs such as altitude, motion, time, or photometrics, or manual action, on demand, by the parachutist. System deactivation means provide sensory inputs or on demand by the parachutist.