According to one embodiment an electric shock self-defence cartridge is provided that includes a distal body in which one or more application means is housed, and a proximal body in which a wire is housed. The proximal body includes coupling means and electric connection means for being joined with the electric shock self-defence device. Compression means is arranged between the distal body and the proximal body for keeping the distal body shifted towards a rest position. The application means is housed in the distal body, such that in use, when the distal body is in contact with an assailant, the distal body shifts with respect to the proximal body from the rest position towards an actuation position in which the application means projects from the distal body to be adhered to the assailant's body.

Ballistic shields having a convex configuration including a middle section and forward angled left side and right side wings. The shields may also include at least three manual or electro-mechanical roller units, transparent windows or display devices with cameras or other motions sensors, and spikes, electro-shock devices, or non-lethal incapacitating devices.

A hand-wearable device capable of electro muscular incapacitation is disclosed. The device may comprise a glove portion including a back side and a palm side, a stun hardware component including a charging port, a rechargeable battery, and a capacitor. First and second terminals may be positioned on the back side of the glove portion and electrically connected to the stun hardware component. The glove portion may encompass a traditional five-fingered glove, cycling glove, lifting glove, or gauntlet. In addition, the glove portion may comprise a cuff or bracer. When the hand-wearable device comprises a glove, the glove portion may be an insulated glove. A switch for actuating discharge of an electrical charge from the first and/or second terminal may be activated when contact is made with the switch; an accelerometer may be adapted to prevent the discharge when acceleration of the glove portion has not reached a predetermined rate.

An UAV controller device is provided. In some embodiments, the device may include a control panel having one or more user control inputs, and a processing unit may be in communication with the control inputs. A display screen may also be in communication with the processing unit. Optionally, the display screen may be movable between an open and a closed position. A side wall may be coupled to a proximal wall and to a distal wall, the side wall, proximal wall, and distal wall forming a storage compartment. The storage compartment may have a storage cavity for removably receiving a UAV, and the UAV may be in wireless communication with the processing unit. A camera, for recording video, may be coupled to the UAV. Video recorded by the camera may be displayed on the display screen, and one or more of the control inputs may govern movement of the UAV.

The device for applying an electrical pulse includes at least one glove having a glove body ending in glove fingers, at least three of which are provided with first application contacts, connected to an electrical energy source via a control unit. The glove further includes second application contacts. The control unit includes a selector for applying a differential electrical pulse between the first and second application contacts.

Implementations of conductive energy weapons (CEWs) may include a shock generating circuit configured to couple to a power source, two electrodes operatively coupled to the shock generating circuit, and a safety circuit operatively coupled to the shock generating circuit. The shock generating circuit may be configured to generate a first pulse train and deliver the first pulse train to a target, and may be configured to generate at least a second pulse train and deliver the at least second pulse train to a target. The safety circuit may be configured to prevent the CEW from applying pulse trains to the target after a predetermined number of pulse trains. The first pulse train may include two or more pulses having waveforms substantially identical with each other, each of the waveforms of the two or more pulses having both a positive voltage segment and a negative voltage segment.

A wearable self-defense apparatus having a body portion configured to be worn on or around a body part of a user includes a high voltage generator configured to generate high voltage electricity for disabling an attacker, a high voltage transmitter electrically coupled to the high voltage generator, a controller configured to control one or more operations of the high voltage generator and a gesture detector operationally coupled to the controller. The gesture detector signals the controller to control the operations of the high voltage generator upon detecting one or more gestures of the user using the body part attached with the wearable self-defense apparatus. Upon receiving the signal from the gesture detector, the controller triggers the high voltage generator to generate high voltage electricity. The high voltage electricity thus generated is transmitted to a target using the high voltage transmitter for temporarily disabling the target.

An actuatable bay conducted electrical weapon comprises a plurality of bays. Each of the bays is configured to releasably receive a deployment unit comprising one or more electrodes. At least one of the bays the plurality of bays is coupled to a body of the conducted electrical weapon via a respective movable member. Each respective movable member is coupled to the body of the conducted electrical weapon by a respective kinematic joint. Responsive to an activation of a control interface, each respective movable member is configured to move about each respective kinematic joint to an expanded position, wherein a distance between each of the bays of the plurality of bays is greater in the expanded position than in a collapsed position. The increased distance is configured to provide a greater initial spread between the one or more electrodes to increase a likelihood of causing NMI in a target.

A conducted electrical weapon (CEW) may launch electrodes toward a target to electrically couple to the target. A CEW may include a signal generator, one or more electrodes, and a selector circuit. The signal generator may include a first conductor and a second conductor, wherein the first conductor has a positive potential and the second conductor has a negative potential. The signal generator may be configured to provide a stimulus signal through the first conductor and the second conductor. The selector circuit may be in electrical series between the signal generator and the one or more electrodes. The selector circuit may be configured to selectively electrically couple an electrode from the one or more electrodes to the first conductor or the second conductor of the signal generator.

An exercise device having a bar with a first handle, a grip exerciser having a second handle connected to the bar via a resistance member proximate the first handle and moveable between a first position and a second position by a hand of a user; and an auxiliary device connected to the bar selected from a light assembly, a sound generator, an electrified defensive unit, a pressurized defensive unit, and combinations of the same.