A projectile cartridge that can be removably attached to a flying vehicle is disclosed. A system can include a first flying vehicle, a projectile attachment mechanism configured with the first flying vehicle, a projectile cartridge that contains a projectile, the projectile cartridge being removably attachable to the projectile attachment mechanism, a weight attached to the projectile, the weight being configured in a releasable configuration in the projectile cartridge and a drawstring configured with the projectile. After firing the projectile, when tension is applied to the drawstring as the projectile approaches or envelops a second flying vehicle, the tension can cause the drawstring to close the projectile down to secure the second flying vehicle.

An electric shock round utilized in projectile launching systems suitable for ranged non-lethal applications is presented. The electric shock round contains a projectile housing, a nose cap, an electroshock generation unit, and a plurality of electrodes. The electroshock generation unit is connected within the projectile housing. The plurality of electrodes is connected to the electroshock generation unit, opposite to the projectile housing. The nose cap is connected adjacent to the projectile housing, where the nose cap houses and secures the plurality of electrodes.

Field of the Art:

The invention relates to weapons technology.

Scope is non-lethal and less lethal remote-action weapon with electric means of damaging biological and tangible targets.

The technical effect is creation of a method for organizing a directed wireless conductive channel in air and a device for implementing the method.

The method consists in supplying a damaging electric current voltage to the ionized channel or channels of the streamers of the resonant transformer, preferably with the QCW DRSSTC topology, bypassing the active and reactive resistance of the secondary winding of the resonant transformer with the channel closure to ground or the closure of two channels with the target. The device consists of one or two resonant transformers connected through gas gaps with a source of shock voltage, while the secondary windings of the transformers can have bypass diode columns and be phased, and the source of the damaging voltage is an alternating or pulse voltage generator or a capacitive energy storage.

Described embodiments include a real-time system, method, and apparatus. A system includes an incoming object sensor configured to acquire data indicative of a trajectory of an incoming projectile. The system includes a human tracking circuit configured to acquire data indicative of a location of a human present in a monitored geographic area. The system includes a processing circuit configured to (i) receive the data indicative of the trajectory of the incoming projectile; (ii) predict a spatial relationship of the trajectory of the incoming projectile relative to the location of the human; and (iii) determine a suggested movement by the human to evade the incoming projectile. The system includes a transmitter circuit configured to transmit the suggested movement to evade the incoming projectile.

Described embodiments include a real-time system, method, and apparatus. A system includes an incoming object sensor configured to acquire data indicative of a trajectory of an incoming projectile. The system includes a human tracking circuit configured to acquire data indicative of a location of a human present in a monitored geographic area. The system includes a processing circuit configured to (i) receive the data indicative of the trajectory of the incoming projectile; (ii) predict a spatial relationship of the trajectory of the incoming projectile relative to the location of the human; and (iii) determine a suggested movement by the human to evade the incoming projectile. The system includes a transmitter circuit configured to transmit the suggested movement to evade the incoming projectile.

A system that creates an environment (e.g., ecosystem) for using, transmitting, and storing data from a CEW and other equipment. The information from a CEW includes a log maintained by the CEW. The log may include information related to the operation, maintenance, software, and deployment units used by the CEW. The information may be used alone or in combination with other information received and stored by an evidence management system for managing inventory, generating use-of-force reports, incident reports, and/or providing information related to equipment, such as a CEW, to the supplier of the equipment. Sources of information provided to an evidence management system includes equipment suppliers, CEWs, other cooperating equipment, records management systems of an agency, a dispatch system of an agency, and third parties. A CEW or other equipment may also receive information for storing in the log.

In one embodiment, a safety trailer has semi-tractor hitches at both ends and a safety wall that is fixed to one side of the trailer. That side, however, can be changed to the right or left side of the road, depending on the end to which the truck attaches. A caboose can be attached at the end of the trailer opposite the tractor to provide additional lighting and impact protection. Optionally, the trailer can be equipped with overhead protection, lighting, ventilation, onboard hydraulics, compressors, generators and other equipment, as well as related fuel, water, storage and restroom facilities and other amenities.

In one embodiment, a safety trailer has semi-tractor hitches at both ends and a safety wall that is fixed to one side of the trailer. That side, however, can be changed to the right or left side of the road, depending on the end to which the truck attaches. A caboose can be attached at the end of the trailer opposite the tractor to provide additional lighting and impact protection. Optionally, the trailer can be equipped with overhead protection, lighting, ventilation, onboard hydraulics, compressors, generators and other equipment, as well as related fuel, water, storage and restroom facilities and other amenities.

In some embodiments, the present invention provides an apparatus and process that includes control electronics that generate an electronic control signal; and a plurality of optically or electrically pumped semiconductor lasers, quantum-cascade lasers, optical parametric generators, or optical parametric oscillators, operatively coupled to the control electronics, that output an optical signal having a plurality of wavelengths, each wavelength having an output intensity that each of which is varied over time to simulate a combustion signature of a weapon. In some embodiments, the optical signal includes at least two different infrared wavelengths that are varied differently with time.

The present invention describes an air-burst projectile (100) and a system (200) for deploying the airburst projectile to counter an unmanned aerial vehicle (UAV) 10. Each airburst projectile includes one or more spinners (140, 140a-140d); each spinner has a sleeve or a tube (146), a number of radial partition plates (148, 148a-148d) extending from the sleeve/tube and an annular rear plate (144) connected to the sleeve. Adjacent partition plates thus form a compartment (150). Disposed in each compartment is a streamer or streamers (170,170a,170b), which are formed in a coiled-up state. When the airburst projectile is deployed into a flight path of a target UAV, the spinners (140, 140a-140d) are ejected and the streamers (170,170a,170b) are dispersed in the flight path to create a streamer cloud, so that a streamer may entangle with propellers of the UAV and bring down the UAV, or as a warning or fence marking shot.