Disclosed is a method for changing operation mode of a weapon that is connected to a maintenance device via an umbilical providing signals and power to the weapon. The method includes transmitting a mode change control signal to electronics in the weapon via a pin on an electrical interface connecting the umbilical to the weapon, and switching the weapon from an operational mode to a non-operational mode and vice versa after receiving the mode change control signal. Also disclosed is a weapon and system including a unit for performing the method.

Systems and methods for testing an Arm and Fire Device (AFD). The system includes an AFD arm controller and a first power supply coupled to the AFD controller to provide arming power to the AFD controller. The system further includes a monitoring module coupled to the AFD controller through a plurality of means of isolation and communication. The monitoring module may include one or more monitor circuits for the AFD to test at least one circuit in the AFD, at least one circuit external to the AFD, or combination. The system further includes at least one output for the AFD to provide data from the monitoring module. The system may further include a first switch to control the monitoring module is powered and a second switch to control power to the AFD arm module. The system can include an input for applying data to the AFD.

Systems and methods for testing an Arm and Fire Device (AFD). The system includes an AFD arm controller and a first power supply coupled to the AFD controller to provide arming power to the AFD controller. The system further includes a monitoring module coupled to the AFD controller through a plurality of means of isolation and communication. The monitoring module may include one or more monitor circuits for the AFD to test at least one circuit in the AFD, at least one circuit external to the AFD, or combination. The system further includes at least one output for the AFD to provide data from the monitoring module. The system may further include a first switch to control the monitoring module is powered and a second switch to control power to the AFD arm module. The system can include an input for applying data to the AFD.

In one embodiment, a squib simulation system includes a processor, sensors, and a firing point. The firing point receives electrical pulse information from a computer. The processor calculates electrical pulse information, including time information and current information. The processor determines a received current and determines whether the current exceeds a predetermined threshold necessary to ignite a squib. Upon a determination that the current exceeds the threshold, the processor determines a firing time that a squib would have fired given the current. The processor records and transfers the information to a user.

In one embodiment, a squib simulation system includes a processor, sensors, and a firing point. The firing point receives electrical pulse information from a computer. The processor calculates electrical pulse information, including time information and current information. The processor determines a received current and determines whether the current exceeds a predetermined threshold necessary to ignite a squib. Upon a determination that the current exceeds the threshold, the processor determines a firing time that a squib would have fired given the current. The processor records and transfers the information to a user.

The invention relates to a test and/or practice ammunition having at least one projectile with a projectile head and a fin which can be found at the end of the projectile for example or a projectile with a projectile base and a projectile ogive. A cartridge shell is used to receive a drive and has a shell base, wherein an interface is attached in or on the shell base. The test and/or practice ammunition is characterized by a programmable fuze which is arranged in the projectile head or the projectile ogive. The projectile head/projectile ogive is equipped with at least one fuze amplifier and an electronic fuze system and optionally a separating charge.

The invention relates to a test and/or practice ammunition having at least one projectile with a projectile head and a fin which can be found at the end of the projectile for example or a projectile with a projectile base and a projectile ogive. A cartridge shell is used to receive a drive and has a shell base, wherein an interface is attached in or on the shell base. The test and/or practice ammunition is characterized by a programmable fuze which is arranged in the projectile head or the projectile ogive. The projectile head/projectile ogive is equipped with at least one fuze amplifier and an electronic fuze system and optionally a separating charge.

Method for the validation of a fuse head in an electronic detonator, wherein said detonator comprises: a reference resistor, a fuse head, at least one capacitor and switching means, wherein in a first position of the switching means, the reference resistor is connected to the at least one capacitor forming a first RC circuit, and in a second position of the switching means, the fuse head is connected to the at least one capacitor forming a second RC circuit; the method comprising the following steps: measuring at least once a first charge time; activating the switching means to the second position to replace the reference resistor in the RC circuit with the fuse head; measuring at least once a second charge time; and determining the deviation of the second charge time from the first charge time.

Embodiments are directed to unpowered railgun field validation for safe-arm fuzing. Embodiments use a wire coil having an induced electromotive force voltage. At least one positive duration circuit measures the positive portion of the induced voltage. At least one positive peak duration circuit measures the peak value of the positive portion of the induced voltage. At least one negative duration circuit measures the duration value of the negative portion of the induced voltage. At least one negative peak detector circuit measures the peak value of the negative portion of the induced voltage.

Embodiments are directed to unpowered railgun field validation for safe-arm fuzing. Embodiments use a wire coil having an induced electromotive force voltage. At least one positive duration circuit measures the positive portion of the induced voltage. At least one positive peak duration circuit measures the peak value of the positive portion of the induced voltage. At least one negative duration circuit measures the duration value of the negative portion of the induced voltage. At least one negative peak detector circuit measures the peak value of the negative portion of the induced voltage.