The present invention relates to a sight system incorporating offset optical components. One embodiment is a sight system supporting multiple laser beams that are used simultaneously. As such, an assembly having two clamps is provided. Each clamp can hold a laser on opposite sides of a firearm barrel. The lasers can be diametrically opposed on the barrel wherein the lasers are in plane with a projectile axis. The lasers can project at the same time to bracket the location on the target of where the projectile hit impact. In another embodiment, the assembly, again with two clamps, is adapted for use with a bow, wherein the clamps support lasers that are in plane with the projectile axis. In another embodiment, the optical component is one or more cameras, wherein reticles can be displayed on a screen to bracket a target.

A firearm sight adjustment and installation tool is described. The tool serves to facilitate and expedite the accurate adjustment and/or installation of sights on the slides of a firearm, whenever the sights allow this adjustment. The tool includes a plate, a plate with nuts, tightening screws, a spacer block, at least one adapter, a drift screw, an interchangeable pushing element and quick reference featured on one of the plates. With the tool and little expertise, an individual may manually adjust both the front and rear sights of a firearm to increase the accuracy of the firearm without additional tools.

A target sight for a firearm includes a main body, an elongated, flexible emitter carrier having a first end fixed to the main body and having a movable portion at a second end opposite the first end, and a light emitter mounted to the movable portion of the flexible emitter carrier.

A L-shaped reticle alignment tool includes a vertical adjustment leg; a horizontal adjustment leg; and a sliding hammer. The L-shaped reticle alignment tool includes a vertical adjustment recess located on the vertical adjustment leg. The L-shaped reticle alignment tool includes a horizontal adjustment recess located on the horizontal adjustment leg. The sliding hammer moves in a direction parallel to the horizontal adjustment leg.

A sight adjustment tool includes a surrounding frame and a sight adjustment module. The surrounding frame including two side members and a top member to define an adjustment cavity. The sight adjustment module includes a base platform movably supported within the adjustment cavity in an elevated direction for adjustably supporting a bottom of a pistol slide, two side clampers movably extended from the side members respectively to the adjustment cavity for biasing against two sides of the pistol slide respectively, and a sight adjuster including an adjusting jaw movably supported by a sight adjusting arm and suspendedly supported within the adjustment cavity for engaging with the sight element, wherein when the sight adjusting arm is rotated, the adjusting jaw is driven to slide along the sight adjusting arm for selectively adjusting the position of a sight element with respect to the pistol slide.

A method of aligning a point of aim with a point of impact for a projectile device is disclosed. Using a superposition device coupled to the projectile device, at least three reference points are superposed within a first target area with at least three diverging beams of the superposition device. Positions for at least three of the reference points are noted. A projectile is shot from the projectile device at a second target area, while the positions of the at least three reference points are maintained, to create the point of impact. The point of aim for the projectile device is adjusted to correspond with the point of impact while the positions of the at least three reference points are maintained. A system for aligning a point of aim with a point of impact for a projectile device is also disclosed.

Methods and systems for aligning a point of aim with a point of impact for a projectile device are disclosed. Using a superposition device coupled to the projectile device, at least one optical reference point is superposed within a first target area. The point of impact is created on a second target area using a projectile expelled from the projectile device towards the second target area. The point of aim for the projectile device is aligned with the point of impact while the position of the at least one optical reference point is maintained. Parallax is eliminated (or minimized) by aligning a primary and a secondary sight alignment indicator with each other and with a common optical axis extending through a scope configured to be coupled with the projectile device.

A firearm includes a firearm identification tag carried in a space between lugs of an accessory mounting rail. A firearm accessory mounting rail assembly includes a firearm identification tag carried in a recoil groove of a Picatinny rail, and including a housing having geometry complementary to a lug of the Picatinny rail, and a transmitter carried in the housing. A firearm identification tag for a firearm accessory mounting rail includes a trapezoidal housing having geometry complementary to Picatinny rail geometry and configured to be press fit between Picatinny lugs, and including sides, a major base, a minor base, and legs between the bases disposed at acute angles to the major base.

A firearm rail mount has an elongated rail body having an upper surface defining a horizontal plane, the elongated rail body having lateral rail edges configured to be engaged by a scope ring base, the elongated rail body defining a channel transverse to the elongated rail body and open in an upward direction, the channel having a floor defining a floor plane, and the floor plane being angularly offset from the horizontal plane. The floor plane may be offset from the horizontal plane by 10-20 degrees. The floor plane may be offset from the horizontal plane by 1-44 degrees. The floor plane may be offset from the horizontal plane by 10-20 degrees. The elongated rail body may define a pattern of alternating blocks and gaps, and the channel is registered with one of the gaps. Each gap may include a bottom surface parallel to the horizontal plane.

A human transported weapon system is comprised of an automated targeting subsystem, a sensing subsystem, munitions storage, munitions logic, sensor logic, target logic, and, munitions logic, a decision subsystem, trigger activation logic, aim adjustment logic; and a firing subsystem. The automated targeting subsystem identifies and provides for selection of a selected target in a field of view of the human transported weapon system. The sensing subsystem tracking location of the available targets in the field of view of the human transported weapon system. The munitions storage provides storage of up to a plurality of types of munitions and having at least one of the types of munitions available to select from. The munitions logic determines which of the types of munition is available. The sensor logic gathers target data from sensors, recognizing type of target from analyzing the target data. The target logic chooses a selected target based on the types of munitions available. The munitions logic chooses a selected munition from the types of munitions available based on the selected target. The decision subsystem locates where target is at a firing time responsive to the sensor logic. The trigger activation logic fires the selected munition at a firing time.