This invention provides impact detection and vehicle cooperation to achieve particular goals and determine particular threat levels. For example, an impact/penetration sensing device may be provided on a soldier's clothing such that when this clothing is impacted/penetrated (e.g., penetrated to a particular extent) a medical unit (e.g., a doctor or medical chopper) may be autonomously, and immediately, provided with the soldiers location (e.g., via a GPS device on the soldier) and status (e.g., right lung may be punctured by small-arms fire).

A remote camera target observation system and method of use, the system generally comprising one or more remote camera/wireless transmitter units comprising a video camera connected to a first wireless transmitter that can wirelessly transmit video signals from the video camera; one or more weather meter/wireless transmitter units comprising at least of a weather meter to continuously measure environmental conditions, weather meter/wireless transmitter units wirelessly transmitting data signals of measured environmental conditions made by the weather meter; a receiver/base unit that comprises a wireless receiver that connects to a computer, the computer connects to a user interface, the wireless receiver capable of receiving video signals from the one or more remote camera/wireless transmitter units and data signals from one or more weather meter/wireless transmitter units.

A field of view detector comprising an orientation sensor for determining an orientation of the field of view detector, a location sensor for determining a location of the field of view detector, and a communication system, the field of view detector configured to communicate the orientation and location of the field of view detector to a central device using the communications system.

A field of view detector comprising an orientation sensor for determining an orientation of the field of view detector, a location sensor for determining a location of the field of view detector, and a communication system, the field of view detector configured to communicate the orientation and location of the field of view detector to a central device using the communications system.

A target marking system includes a light source configured to emit a beam of thermal radiation and to impinge the beam onto a target. The system also includes a detector configured to collect radiation passing from the target to the detector along a path. The radiation passing from the target in response to impingement of the beam onto the target. The system further includes an optics assembly disposed optically upstream of the detector along the path. The optics assembly includes at least one of an afocal power changer, a camera objective, a catadioptric lens, and a zoom system configured to condition the radiation passing from the target to the detector.

Systems, devices, and methods for determining a predicted impact point of a selected weapon and associated round based on stored ballistic information, provided elevation data, provided azimuth data, and provided position data.

A device and method for selectively illuminating and designating multiple targets in the air or on the ground simultaneously. The device comprises a light source, a switching array and a ball lens. Light from the light source is routed through the switching array, which can addressably output multiple light beams simultaneously. The light beams from the switching array illuminate the backside of a low F-number ball lens. The ball lens creates highly collimated output beams independently (and simultaneously) from any of the output source points of the switching array. These output beams can be used to simultaneously designate multiple targets. When the target illuminating device includes an optional detector array, light scattered from targets can be refracted by the balls lens to impinge on the detector array. Signals from the detector array representing the received light beams can be used for target imaging.

In an exemplary embodiment of the present disclosure, a target marker for a firearm may comprise a module having a first portion, and a second portion electrically connected and coupled to the first portion. A light source may be disposed within and electrically connected to the second portion. An optical component may be coupled to the first portion at a first fixed distance from the light source. A circuit board may be electrically connected to the light source via at least one lead, wherein the lead may permit relative movement between the circuit board and the light source and may maintain a second fixed distance between the circuit board and the light source.

A method and fire control system for measuring distance to a burst point of airburst munition including: setting a detonation point distance of airburst munition; firing the weapon with airburst munition at time t.sub.0; setting a time of flight, t.sub.1, of the airburst munitions based on its set detonation point distance, activating and controlling a laser measurement system including a laser transmitter and receiver for sending laser light at a time t.sub.0+t.sub.1 and receiving reflected laser light for measuring distance to cloud of smoke resulting from burst of the airburst munition, processing the reflected laser light and defining a range of distances to the cloud of smoke, and setting a range gate around the set detonation point distance prior to processing received reflected laser light within the range gate for limiting the resulting range of distances and cancelling echoes from surrounding terrain.

A human transported weapon system is comprised of an automated targeting subsystem, a sensing subsystem, a decision subsystem, and, a firing subsystem. The automated targeting subsystem identifies and provides for selection of a selected target in a field of view of a target area of the human transported weapon system. The sensing subsystem tracks location of the selected target. The decision subsystem locates where the selected target is at a firing time, responsive to the sensing subsystem. The firing subsystem fires a munition at the firing time towards the selected target responsive to the decision subsystem. In one embodiment, the human transported weapon system is linked to communicate with at least one external weapon subsystem having separate munitions and ability for firing said separate munitions. The decision subsystem determines which one of the human transported weapon system and the external weapon subsystem has a best shot to strike the selected target if fired, and provides for firing of the munition from whichever one of the human transported weapon system and the external weapons subsystem has the best shot to strike the selected target if fired.