Dynamic compensation of a robot arm mounted on a flexible arm

The invention claimed is: 1. A system including: a boom supported from a boom base, said boom having a robot arm mounted by a robot base therefrom, said robot arm having an end effector, said boom being moveable relative to said boom base by a boom controller interfaced with a boom actuator to position said robot base to a programmed location, said robot arm being movable by a robot arm controller interfaced with a robot arm actuator to position said end effector at a programmed position and orientation; and, a control system having a tracker system to track a position of the robot base based on a position of a first target located by an offset proximal to said robot base; wherein said tracker system tracks the position of said first target and feeds data to said boom controller while the control system operates said boom actuator to position and orientate said first target close to said offset and thereby position said robot base close to said programmed location, and said tracker system tracks a position of the end effector based on a position and orientation of a second target located with a tool centre point (TCP) offset from an end effector TCP, and said tracker system tracks the position and orientation of said second target while the boom actuator moves the robot base and feeds data derived from said second target and said first target to said robot arm controller while the control system operates said robot arm actuator to position and orientate said end effector TCP to said programmed position and orientation; wherein said boom controller operates said boom actuator with a slow dynamic response, and the robot arm controller operates said robot arm actuator with a fast dynamic response to thereby compensate for boom motion errors and deflection; and the fast dynamic response is faster than a natural frequency of the boom and the slow dynamic response is slower than the natural frequency of the boom. 2. The system as claimed in claim 1 wherein said second target is located with said TCP offset from said end effector TCP so as to move with movement and pose of said end effector. 3. The system as claimed in claim 1 wherein said robot base is mounted proximal to a remote end of said boom, away from said boom base. 4. The system as claimed in claim 3 wherein said robot base and said first target is mounted on a head, mounted to the remote end of the boom. 5. The system as claimed in claim 4 wherein said head is pivotally mounted to the remote end of the boom. 6. The system as claimed in claim 4 wherein said head is pivotally mounted about a horizontal axis to the remote end of the boom. 7. The system as claimed in claim 3 wherein said robot arm controller is controllably switched between a first state wherein said robot arm controller is responsive to positioning feedback data derived from said tracker system, to a second state where pre-calibrated positioning data referenced to the robot base (and hence the remote end of the boom) is relied on, and when switched between said first state and said second state, said robot arm controller controls movement of said robot arm to dampen movement of the robot arm, to avoid sudden movement of said robot arm and said end effector. 8. The system as claimed in claim 1 wherein a pose of the head is controlled by a separate controller to the boom controller, and the boom controller operates the boom actuator to position the first target along three orthogonal axes. 9. The system as claimed in claim 1 wherein control of a pose of the head is integrated into the boom controller, and the tracker system tracks the position and orientation of the first target. 10. The system as claimed in claim 1 wherein said tracker system includes separate target tracking devices for said first target and said second target. 11. The system as claimed in claim 1 wherein said boom base is provided with movement apparatus to move said boom base relative to the ground. 12. The system as claimed in claim 11 wherein the movement apparatus is selected from a wheeled conveyance, incorporating locomotion or not, or self powered endless tracks. 13. The system as claimed in claim 12 wherein the movement apparatus incorporates self levelling to level the boom base. 14. The system as claimed in claim 11 wherein said boom base is mounted on an active suspension system, and said boom base incorporates a third target for said tracker system, said active suspension system having a suspension controller interfaced with a suspension actuator to control the position and orientation of said boom base in response to data from said tracker system reading the position and orientation of said third target. 15. The system as claimed in claim 11 wherein said boom base is mounted to an object having larger inertia than said boom on an active suspension system, and said boom base incorporates a third target for said tracker system; said active suspension system having a suspension controller interfaced with a suspension actuator to control the position and orientation of said boom base relative to said object in response to data from said tracker system reading the position and orientation of said third target, said suspension actuator to control the position of said boom base with a slower dynamic response than said boom controller operates said boom actuator.