Modular sighting assembly and method

What is claimed is: 1. A laser sighting system, comprising: a fixed section having a housing and a fastener for providing a rigid connection of the fixed section to a weapon; a laser assembly including one or more lasers, the laser assembly rotatably attached to the fixed section and rotatable about an axis which extends in a direction which is generally transverse to a longitudinal axis of a barrel of the weapon; a processor assembly including a processor and an associated computer readable memory encoded with executable instructions, the processor configured, upon execution of the executable instructions, to receive input representative of a distance to a target and calculate a trajectory angle of the weapon based on the distance to the target whereby the weapon will launch a projectile a distance that corresponds to the distance to the target; a motor mount disposed within the fixed section and including a projecting portion which extends into a complimentary cavity in the laser assembly, wherein the laser assembly is rotatable with respect to the motor mount; a motor received within the motor mount and having a drive shaft coupled to the laser assembly, the motor configured to operate under the control of the processor assembly; the processor configured, upon execution of the executable instructions, to operate the motor to rotate the laser assembly relative to the fixed section such that the barrel of the weapon will be aligned with the trajectory angle when an optical axis of the one or more lasers is aligned with the target; and one or both of a windage adjustment assembly and an elevation adjustment assembly; the windage adjustment assembly including a windage adjustment rod having a first end rotatable by a user and a second end attached to the motor mount, wherein rotation of the windage adjustment rod in a first direction is configured to impart a side-to-side adjustment of an aiming direction of the laser assembly in a first side-to-side direction and rotation of the windage adjustment rod in a second direction is configured to impart a side-to-side adjustment of the aiming direction of the laser assembly in a second side-to-side direction, and further wherein the windage adjustment assembly includes a threaded rod rotatably engaging a threaded opening in the motor mount and a ball and socket joint joining the threaded rod and the windage adjustment rod; and the elevation adjustment assembly including an elevation adjustment rod having a first end rotatable by a user and a second end coupled to the motor mount, wherein rotation of the elevation adjustment in a first direction is configured to impart an upward adjustment of an aiming direction of the laser assembly and rotation of the elevation adjustment in a second direction is configured to impart a downward adjustment of an aiming direction of the laser assembly, the elevation adjustment assembly further including an eccentric cam attached to the elevation adjustment rod and received within an opening in the motor mount, the eccentric cam configured to impart vertical movement of the motor mount responsive to rotation of the elevation adjustment rod. 2. The laser sighting system of claim 1 , further comprising: a sight attached to the laser assembly and optically aligned with the one or more lasers, the sight selected from the group consisting of a mechanical sight, a reflex sight, a telescopic sight, or any combination thereof. 3. The laser sighting system of claim 1 , further comprising a display configured to display the distance to the target in human viewable form. 4. The laser sighting system of claim 1 , wherein the distance to the target is a calculated distance received from an associated range finder, the range finder including an optical emitter for sending an optical signal to the target and an optical detector for detecting the optical signal reflected from the target. 5. The laser sighting system of claim 1 , further comprising a laser range finder operatively coupled to the laser sighting system, the laser range finder configured to calculate the distance to the target. 6. The laser sighting system of claim 1 , wherein the processor is configured, upon execution of the executable instructions, to operate in a first mode wherein the input representative of a distance to a target is received from an associated range finder and a second mode wherein the input representative of a distance to a target is manually input by a user. 7. The laser assembly sighting system of claim 6 , wherein the laser assembly is manually rotatable with respect to the fixed section and further wherein the processor is configured, upon execution of the executable instructions, to receive input representative of a distance to a target based on a degree of manual rotation of the laser assembly. 8. The laser sighting system of claim 1 , wherein the motor mount is movable within the housing. 9. The laser sighting system of claim 1 , further comprising a remote control unit operatively coupled to the processor assembly for controlling operation of the laser sighting system. 10. The laser sighting system of claim 1 , wherein laser assembly includes one or more pointing lasers. 11. The laser sighting system of claim 10 , wherein the laser assembly further includes at least one illumination laser. 12. The laser sighting system of claim 1 , wherein the laser assembly includes a first pointing laser which is operable to emit infrared radiation, a second pointing laser which is operable to emit visible radiation, and an illumination laser which is operable to emit infrared radiation, wherein the first pointing laser, the second pointing laser, and the illumination laser are optically aligned with each other to emit radiation in the same direction along parallel optical axes. 13. The laser sighting system of claim 1 , wherein the laser assembly includes a plurality of lasers and a plurality of adjustment set screws engaging each laser, each of the adjustment set screws rotatable to adjust an optical axis of such laser independently of the other lasers in said plurality of lasers. 14. The laser sighting system of claim 1 , wherein the weapon is a grenade launcher. 15. The laser sighting system of claim 1 , wherein the fastener is a weapon accessory rail clamp. 16. The laser sighting system of claim 15 , wherein the weapon accessory rail clamp is configured for removable attachment to a Picatinny accessory rail. 17. A laser sighting system, comprising: a fixed section having a housing and a fastener for providing a rigid connection of the fixed section to a weapon; a laser assembly including one or more lasers, the laser assembly rotatably attached to the fixed section and rotatable about an axis which extends in a direction which is generally transverse to a longitudinal axis of a barrel of the weapon; a processor assembly including a processor and an associated computer readable memory encoded with executable instructions, the processor configured, upon execution of the executable instructions, to receive input representative of a distance to a target and calculate a trajectory angle of the weapon based on the distance to the target whereby the weapon will launch a projectile a distance that corresponds to the distance to the target; a motor mount disposed within the fixed section and including a projecting portion which extends into a complimentary cavity in the laser assembly, wherein the laser assembly is rotatable with respect to the motor mount; a motor received within the motor mount and having a drive shaft coupled to the laser