An adjustable sighting and shooting firearm mounting vise receives a firearm to assist shooters with sighting and discharging the firearm. The firearm mounting vise includes a first base support, a second base support, a pair of positional-adjustment tracks, a forend support, a stock support, a trigger actuator, a trigger switch, a controller housing, a wireless receiver, and a microcontroller. The first base support and the second base support the pair of positional-adjustment tracks. The pair of positional-adjustment tracks allows the forend support, the stock support, and the trigger actuator to translate along each positional-adjustment track to accommodate a plurality of firearms to be secured by the firearm mounting vise. The controller housing protects electrical components including the microcontroller and the wireless receiver. The microcontroller receives control signals through the wireless receiver or directly from the trigger switch to activate the trigger actuator and discharging the firearm.

A weapon mount for controlling targeting of a weapon includes a base, an arm that extends from the base, and an attachment component that is rotatably coupled with the arm. The base is attachable to a platform and is rotatable to control a yaw of the weapon relative to the platform. The attachment component is configured to couple with the weapon and is rotatable to control a pitch of the weapon relative to the platform. The arm is positioned relative to the base so that a recoil vector of the weapon is within 0.5 inches radially of an axis of rotation of the base.

New targeting systems, hardware and techniques are provided, in which an auxiliary probe is first launched and deployed at a target. Extremely precise, deliberate targeting for future projectiles, weapons or non-lethal measures is then made relative to the position and orientation of the probe. In one embodiment, a system enables a sniper to plan measures with extreme precision within an environment, evaluate their effectiveness, and execute them extremely rapidly once satisfied. A user may create, set, adjust and execute Impact Point indicators, corresponding with projected points of impact of a projectile on a target subject within a target environment. The system may counteract and otherwise adjust for certain ballistic and environmental factors in a firing mechanism to maintain such an Impact Point fire ready, in real time. Yet the system is unobtrusive, allowing the user to engage ordinary targeting activity.

New targeting systems, hardware and techniques are provided, in which an auxiliary probe is first launched and deployed at a target. Extremely precise, deliberate targeting for future projectiles, weapons or non-lethal measures is then made relative to the position and orientation of the probe. In one embodiment, a system enables a sniper to plan measures with extreme precision within an environment, evaluate their effectiveness, and execute them extremely rapidly once satisfied. A user may create, set, adjust and execute Impact Point indicators, corresponding with projected points of impact of a projectile on a target subject within a target environment. The system may counteract and otherwise adjust for certain ballistic and environmental factors in a firing mechanism to maintain such an Impact Point fire ready, in real time. Yet the system is unobtrusive, allowing the user to engage ordinary targeting activity.

An adjustable sighting and shooting firearm mounting vise receives a firearm to assist shooters with sighting and discharging the firearm. The firearm mounting vise includes a first base support, a second base support, a pair of positional-adjustment tracks, a forend support, a stock support, a trigger actuator, a trigger switch, a controller housing, a wireless receiver, and a microcontroller. The first base support and the second base support the pair of positional-adjustment tracks. The pair of positional-adjustment tracks allows the forend support, the stock support, and the trigger actuator to translate along each positional-adjustment track to accommodate a plurality of firearms to be secured by the firearm mounting vise. The controller housing protects electrical components including the microcontroller and the wireless receiver. The microcontroller receives control signals through the wireless receiver or directly from the trigger switch to activate the trigger actuator and discharging the firearm.

A firearm positioning system and methods of use are provided. The system comprises a first arm segment pivotably engaged to a primary body and a second arm segment pivotably engaged to the first arm segment. The system also comprises a cradle pivotably engaged to the second arm segment. The cradle is configured to support a firearm. The cradle comprises a pair of channels at a first end and a backstop assembly at a second end opposite the first end. The pair of channels are configured to receive a front end of a firearm and the backstop assembly is configured to releasably secure a back end of the firearm to the cradle.

A firearm positioning system and methods of use are provided. The system comprises a first arm segment pivotably engaged to a primary body and a second arm segment pivotably engaged to the first arm segment. The system also comprises a cradle pivotably engaged to the second arm segment. The cradle is configured to support a firearm. The cradle comprises a pair of channels at a first end and a backstop assembly at a second end opposite the first end. The pair of channels are configured to receive a front end of a firearm and the backstop assembly is configured to releasably secure a back end of the firearm to the cradle.

New targeting systems, hardware and techniques are provided. In a preferred embodiment, a system enables a sniper to, in effect, take a projected, trial shot at a subject within an environment, evaluate its effectiveness, and execute it if satisfied. A user may create, set, adjust and execute Impact Point indicators, corresponding with projected points of impact of a projectile on a target subject within a target environment. The system may counteract and otherwise adjust for certain ballistic and environmental factors in a firing mechanism to maintain such an Impact Point fire ready, in real time. Yet the system allows the user to continue to move the sight to engage in further targeting activity. In other aspects, the system may execute multiple impact points, together or in rapid succession, which impact points may surround, lead, cover or otherwise diversify their distribution about a targeting subject and/or its projected path.

New targeting systems, hardware and techniques are provided. In a preferred embodiment, a system enables a sniper to, in effect, take a projected, trial shot at a subject within an environment, evaluate its effectiveness, and execute it if satisfied. A user may create, set, adjust and execute Impact Point indicators, corresponding with projected points of impact of a projectile on a target subject within a target environment. The system may counteract and otherwise adjust for certain ballistic and environmental factors in a firing mechanism to maintain such an Impact Point fire ready, in real time. Yet the system allows the user to continue to move the sight to engage in further targeting activity. In other aspects, the system may execute multiple impact points, together or in rapid succession, which impact points may surround, lead, cover or otherwise diversify their distribution about a targeting subject and/or its projected path.

A gun targeting system (10) comprising a chassis (200). A gun barrel (300) is mounted to the chassis (200) by a pivot mount (304). The system also comprises a chassis suspension system (400) comprising a plurality of wheel arms (402), each wheel arm (402) extending away from a different chassis mount (220) on the chassis (200) to a respective wheel (404), each wheel (404) being rotatably mounted on its respective wheel arm (402), each wheel (404) configured for engagement with a support surface (500). The gun targeting system (10) is operable to position the barrel (300) towards an orientation to target an object by pivoting one or more wheel arms (402) relative to the chassis (200) and/or by pivoting one or more wheels (404) relative to its respective wheel arm (402) and/or by rotating one or more wheels (404) relative to its respective wheel arm (402).