A multiple advanced missile and bomb ejector rack carriage system employs a carriage mountable to an air to ground (AG) bomb release unit (BRU) on an aircraft pylon. A single MIL-STD-1760 electrical interface is integral to the carriage and has a first power connection and first signal connection. Onboard carriage avionics are supported within the carriage and connected to the MIL-STD-1760 electrical interface. The onboard carriage avionics are adapted to receive communications from an aircraft central computer through the first power connection and first signal connection and provide store specific communications independent of specific original aircraft wiring to at least one ejector and store.

An apparatus for dispensing incendiary spheres comprising a hopper operable to store discrete unitary unprimed spheres; a feed mechanism cooperating with the hopper to extract unprimed spheres from the hopper; a rotary sphere delivery mechanism rotating in a first direction and having at least one pocket defined therein, the at least one pocket being adapted to capture a sphere, wherein the feed mechanism cooperates with the rotary sphere delivery mechanism to load an unprimed sphere into the at least one pocket; a rotary injector mechanism rotating in an opposing second direction and having at least one injector needle, wherein the rotary injector mechanism and the rotary sphere delivery mechanism are synchronized such that the at least one injector needle pierces an unprimed sphere within the at least one pocket as the at least one pocket and the at least one injector needle rotate past each other; a source of reactant in fluid communication with the at least one injector needle, wherein the rotary injector mechanism delivers an amount of reactant to the at least one injector upon the at least one injector piercing the sphere to start a delayed exothermic reaction within the sphere thereby priming the sphere; and a motor to drive the rotary sphere delivery mechanism and the rotary injector mechanism.

A dispenser for storing and launching countermeasures, where the dispenser is adapted for storing the countermeasures in a magazine, where the dispenser is provided with at least one launch opening and where the dispenser is adapted to be mounted on an aircraft, where the dispenser includes a body, a bracket and a magazine housing, where the bracket is rotatable with respect to the body and where magazine housing is rotatable with respect to the bracket, where the magazine housing includes a storage space adapted to hold the magazine, and where the launch opening is arranged in the magazine housing. The invention also includes a method for rotating the magazine and launching a countermeasure. The advantage of the invention is that a countermeasure can be directed in a desired angle before it is launched.

The present disclosure provides a payload activation device. The payload activation device comprises a camera having a fixed focal length, arranged to capture an image of an object on a platform for carrying a payload having the payload activation device, wherein, when the payload is in a first position relative to the platform, the image of the object is in a first focused state and, when the payload is in a second position relative to the platform, the image of the object is in a second focused state. The payload activation device also comprises a processor configured to determine whether the image of the object is in the first focused state or the second focused state and to cause actuation of an activation mechanism within the payload when the image of object is in the second focused state to activate the payload. The present disclosure also provides a deployable payload having the payload activation device and an aircraft for carrying the deployable payload.

The present disclosure provides a payload activation device. The payload activation device comprises a camera having a fixed focal length, arranged to capture an image of an object on a platform for carrying a payload having the payload activation device, wherein, when the payload is in a first position relative to the platform, the image of the object is in a first focused state and, when the payload is in a second position relative to the platform, the image of the object is in a second focused state. The payload activation device also comprises a processor configured to determine whether the image of the object is in the first focused state or the second focused state and to cause actuation of an activation mechanism within the payload when the image of object is in the second focused state to activate the payload. The present disclosure also provides a deployable payload having the payload activation device and an aircraft for carrying the deployable payload.

A method of targeting, which involves capturing a first video of a scene about a potential targeting coordinate by a first video sensor on a first aircraft; transmitting the first video and associated potential targeting coordinate by the first aircraft; receiving the first video on a first display in communication with a processor, the processor also receiving the potential targeting coordinate; selecting the potential targeting coordinate to be an actual targeting coordinate for a second aircraft in response to viewing the first video on the first display; and guiding a second aircraft toward the actual targeting coordinate; where positive identification of a target corresponding to the actual targeting coordinate is maintained from selection of the actual targeting coordinate.

A method of targeting, which involves capturing a first video of a scene about a potential targeting coordinate by a first video sensor on a first aircraft; transmitting the first video and associated potential targeting coordinate by the first aircraft; receiving the first video on a first display in communication with a processor, the processor also receiving the potential targeting coordinate; selecting the potential targeting coordinate to be an actual targeting coordinate for a second aircraft in response to viewing the first video on the first display; and guiding a second aircraft toward the actual targeting coordinate; where positive identification of a target corresponding to the actual targeting coordinate is maintained from selection of the actual targeting coordinate.

An unmanned vehicle and a method of operating the vehicle are provided. The vehicle includes a fuselage and at least one thrust device coupled to the fuselage. A first payload module having an first attachment plate is fixedly coupled to the fuselage, the first payload module further having a first control module removably coupled to the first attachment plate and a first payload having a first energetic element. A second payload module having an second attachment plate is fixedly coupled to the fuselage adjacent the first payload module, the second payload module further having a second control module removably coupled to the second attachment plate and a second payload having a second energetic element.

An unmanned vehicle and a method of operating the vehicle are provided. The vehicle includes a fuselage and at least one thrust device coupled to the fuselage. A first payload module having an first attachment plate is fixedly coupled to the fuselage, the first payload module further having a first control module removably coupled to the first attachment plate and a first payload having a first energetic element. A second payload module having an second attachment plate is fixedly coupled to the fuselage adjacent the first payload module, the second payload module further having a second control module removably coupled to the second attachment plate and a second payload having a second energetic element.

A munitions rack includes a munitions rack structure that houses multiple compact ejectors. The structure includes a pair of internal longitudinal ribs, inboard of a pair of external longitudinal ribs. A spine of the munitions rack structure links all the ribs, and the munitions rack structure may be formed out of a single piece of material. The ribs define a pair of side recesses on the port and starboard sides of the bomb, which each may be further subdivided into a forward pocket and an aft pocket. Removable ejectors are located in the pockets. The ejectors may receive pressurized gas from pressurized gas source(s) located outside of the ejectors. The ejectors may each have multiple forward pistons and multiple aft pistons. The ejectors may include pitch control valving to control the relative amounts of pressurized gas sent to the forward piston(s) and aft piston(s).