Precision engagement system

1 . A system including: a first device mounted on a first gimbal mount; a first visual feedback mechanism providing feedback regarding the orientation of the first device on the first gimbal; a second device mounted on a second gimbal mount, the second gimbal mount being physically displaced relative to the first gimbal mount in at least one direction; a second visual feedback mechanism providing feedback regarding the orientation of the second device on the second gimbal mount; the orientation of the first device differing from the orientation of the second device by a correction amount, the correction amount being a dynamic value that differs through a range of possible orientations of the first device; a gimbal controller that determines motion of the first device and communicates instructions to cause motion of the second device that is responsive to the motion of the first device; and a correction controller having input that when acted upon by a user causes movement of the second device independently of movement of the first device to alter the correction amount to a revised correction amount such that subsequent movement of the first device causes motion in the second device that is at least partially dependent upon the revised correction amount. 2 . The system of claim 1 , wherein the first device is a first camera. 3 . The system of claim 2 , wherein the first visual feedback mechanism is hardware operable to receive a signal from the first camera and provide the signal to a device proximate the user. 4 . The system of claim 1 , wherein the second device is a projectile launching device. 5 . The system of claim 4 , wherein the second visual feedback mechanism is a second camera. 6 . The system of claim 5 , wherein the second visual feedback mechanism provides an indication of where the projectile launching device is aimed. 7 . The system of claim 6 , wherein the correction controller includes a display that displays signals from the first visual feedback mechanism and the second feedback mechanism simultaneously to permit the user to determine a correspondence between the orientation of the first device and the aim of the projectile launching device. 8 . The system of claim 7 , wherein the correction controller is operable to receive input from the user to cause improved correspondence between the orientation of the first device and the aim of the projectile launching device. 9 . The system of claim 1 , further including a database, the database storing data indicating a correlation between orientations of the first and second devices. 10 . A weapon control system including: an operator station having; a first input receiving data from a first camera mounted on a first gimbal mount; a second input receiving data from a second camera providing an indication of a direction in which a weapon is aimed, the weapon being mounted on a second gimbal, the second gimbal mount being physically displaced relative to the first gimbal mount in at least one direction; a data storage storing a plurality of offset values corresponding to a difference in the orientation of the first camera from the orientation of the weapon that accounts for the physical displacement of the first camera relative to the weapon to permit both the first camera and the weapon to be aimed at a common point, the offset values being dynamic values that differ through a range of possible orientations of the first camera; a display showing data feed from the first camera and the second camera; an output that communicates instructions to cause motion of the weapon in response to motion of the first camera; and a correction controller that when acted upon by a user causes data to be communicated to the output to cause movement of the weapon independently of movement of the first camera to alter at least one offset value, the alteration generating a revised offset value such that subsequent movement of the first camera causes motion in the weapon that is at least partially dependent upon the revised offset amount. 11 . The system of claim 10 , wherein the correction controller causes movement of the second camera allowing the user to verify that the first camera and second camera are aimed at a common element. 12 . The system of claim 10 , wherein the data feed from the second camera displayed on the display includes a target reticle. 13 . The system of claim 10 , wherein the first camera is at least partially isolated from the weapon such that forces experienced by and generated by the weapon are at least partially isolated from the first camera. 14 . The system of claim 10 , wherein the first camera has greater resolution than the second camera. 15 . A method of operating a weapons system including: obtaining a system having: an input operable to receive a signal from a first camera on a first gimbal providing an indication of the directional aim of the first camera; an input operable to receive a signal from a second camera on a second gimbal providing an indication of the directional aim of the second camera, the second camera being offset from the first camera in at least one direction; an input operable to receive a signal descriptive of an orientation of the first gimbal; an output operable to supply a control signal to change the orientation of the second gimbal; a storage medium storing information regarding a plurality of orientations of the second gimbal that cause the second camera to be aimed at the same location as the first camera for a plurality of respective orientations of the first camera; and a display showing the signal of the first camera and the signal of the second camera; viewing the signals of the first and second camera by a user; interacting with an interface, by the user viewing the signals of the first and second camera, to cause the second camera to move its aim to provide a closer correlation between where the first camera is aimed and where the second camera is aimed to produce an adjusted correlation between the first camera and the second camera; and saving data regarding the adjusted correlation such that subsequent movement of the first camera causes a movement of the second camera that is at least partially based on the adjusted correlation. 16 . The method of claim 15 , wherein the adjusted correlation produces a linked pair of positions of the first and second gimbals. 17 . The method of claim 15 , wherein the adjusted correlation causes an adjustment in a dynamic positioning function that has an orientation of the first gimbal as an input and an orientation of the second gimbal as an output. 18 . The method of claim 15 , wherein the indication of the directional aim of the first camera is a video feed from the first camera and the indication of the directional aim of the second camera is a video feed from the first camera. 19 . The method of claim 15 , wherein the second camera is aligned with a weapon mounted on the second gimbal. 20 . A system including: a first camera mounted on a first gimbal mount; a first visual feedback mechanism providing feedback regarding the orientation of the first camera on the first gimbal, the first visual feedback mechanism being hardware operable to receive a signal from the first camera and provide the signal to a device proximate a user; a projectile launching device mounted on a second gimbal mount, the second gimbal mount being physically displaced relative to the first gimbal mount in at least one direction; a second camer