Steady hand micromanipulation robot

We claim: 1. A cooperative-control robot, comprising: a base component; a mobile platform arranged proximate said base component; a translation assembly operatively connected to said base component and said mobile platform and configured to move said mobile platform with translational degrees of freedom substantially without rotation with respect to said base component; a tool assembly connected to said mobile platform, wherein said tool assembly comprises a tool holder and a tool rotation assembly connected to said tool holder; a control system configured to communicate with said translation assembly to control motion of said mobile platform in response to forces by a user applied to at least a portion of said cooperative-control robot; and at least one force sensor attached to said holder, wherein said translation assembly comprises at least three independently operable actuator arms, each connected to a separate position of said mobile platform, wherein said tool rotation assembly provides at least two rotational degrees of freedom for orienting said tool when held by said tool holder, and wherein said at least one force sensor detects at least one force component applied by said user to said tool when held by said tool holder causing said control system to move said mobile platform and said tool assembly a desired way. 2. A cooperative-control robot according to claim 1 , wherein said translation assembly further comprises at least three motors, each operably connected to a respective one of said at least three independently operable actuator arms, wherein each of said at least three motors is supported by said base component such that said mobile platform is free to move without carrying weight of said motors. 3. A cooperative-control robot according to claim 1 , wherein each of said at least three independently operable actuator arms comprises a pair of interconnected structural members arranged to form a parallelogram shape which is variable in skewness during operation. 4. A cooperative-control robot according to claim 1 , wherein said at least three independently operable actuator arms are articulated arms. 5. A cooperative-control robot according to claim 3 , wherein said at least three independently operable actuator arms are articulated arms. 6. A cooperative-control robot according to claim 1 , wherein said translation assembly further comprises at least three linear tracks arranged such that each of said at least three independently operable actuator arms has an end that is constrained to move along a respective one of said at least three linear tracks. 7. A cooperative-control robot according to claim 6 , wherein said at least three linear tracks are at least one of attached to, or integral with, said base component. 8. A cooperative-control robot according to claim 1 , wherein said base component is adapted to be mountable to an overhead boom. 9. A cooperative-control robot according to claim 1 , wherein said base component is adapted to be mountable to a bedrail. 10. A cooperative-control robot according to claim 7 , wherein said base component is adapted to be mountable to an overhead boom. 11. A cooperative-control robot according to claim 7 , wherein said base component is adapted to be mountable to a bedrail. 12. A cooperative-control robot according to claim 1 , wherein said force sensor is a six-degree-of-freedom force sensor. 13. A robotic system, comprising: a support structure; first and second cooperative-control robots connected to said support structure; and a control system adapted to communicate with said first and second cooperative-control robots, wherein each of said first and second cooperative-control robots comprises: a base component connected to said support structure, a mobile platform arranged proximate said base component, a translation assembly operatively connected to said base component and said mobile platform and configured to move said mobile platform with translational degrees of freedom substantially without rotation With respect to said base component, and a tool assembly connected to said mobile platform, wherein said control system is configured to control motion of each said mobile platform in response to forces by a user applied to at least a portion of a corresponding one of said first and second cooperative-control robots, wherein each said translation assembly comprises at least three independently operable actuator arms, each connected to a separate position of said mobile platform, wherein said tool assembly comprises a tool holder and a tool rotation assembly connected to said tool holder, wherein said tool rotation assembly provides at least two rotational degrees of freedom for orienting said tool when held by said tool holder, and wherein at least one force sensor attached to said tool holder detects at least one force component applied by said user to said tool when held by said tool holder causing said control system to move said mobile platform and said tool assembly a desired way. 14. A robotic system according to claim 13 , wherein said support structure comprises a first overhead boom. 15. A robotic system according to claim 14 , wherein said support structure comprises a second overhead boom rotatably attached to the first overhead boom. 16. A robotic system according to claim 13 , wherein said support structure comprises a first bedrail. 17. A robotic system according to claim 16 , wherein said support structure comprises a second bedrail, and wherein said first cooperative-control robot is connected to the first-mentioned bedrail and said second cooperative-control robot is connected to said second bedrail. 18. A robotic system according to claim 13 , further comprising a user input device adapted to communicate with said control system to at least one of interrupt or supplement cooperative control due to said forces applied by said user. 19. A robotic system according to claim 18 , wherein said user input device is a foot pedal. 20. A cooperative-control robot according to claim 1 , wherein said control system moves said mobile platform and said tool assembly said desired way in a smooth manner in response to said forces by said user. 21. A robotic system according to claim 13 , wherein said control system moves said mobile platform and said tool assembly said desired way in a smooth manner in response to said forces by said user. 22. A robotic system according to claim 13 , wherein said translation assembly further comprises at least three linear tracks arranged such that each of said at least three independently operable actuator arms has an end that is constrained to move along a respective one of said at least three linear tracks. 23. A robotic system according to claim 22 , wherein said at least three linear tracks are at least one of attached to, or integral with, said base component.