Robotic mechanism with two degrees of freedom

We claim: 1. A robotic mechanism comprising: a first and a second base element; first and second cylinders, each having an oblique truncated form, said cylinders being confined between said base elements such that an obliquely formed end surface of said first cylinder and an obliquely formed end surface of said second cylinder can mutually rotate in sliding association with each other; first and second driving motors attached to said first and second base elements, each driving motor being coupled to enable rotation relative to its base element of the cylinder adjacent to that base element, such that rotation of at least one of said cylinders causes said base elements to undergo change in their mutual orientation; and a passive inverted universal joint connecting said first and second base element such that said base elements are prevented from separating, and connected external to the axes of said cylinders, such that said axes can be free of impediments. 2. A robotic mechanism according to claim 1 , wherein said motors are adapted to generate relative rotation between said two cylinders, such that the axes of said cylinders undergo mutual change in inclination as said cylinders rotate relative to each other. 3. A robotic mechanism according to claim 1 , wherein a combination of rotation modes of said cylinders enables adjustment of the pose of one of said base elements relative to the other, within the envelope made available by the angles of inclination of the obliquely formed end surfaces of said two cylinders. 4. A robotic mechanism according to claim 1 , wherein rotation of one of said cylinders with respect to the other defines a combination of the inclination and the azimuthal orientation of one of said cylinder axes relative to the other. 5. A robotic mechanism according to claim 1 , wherein synchronized rotation of both said cylinders in the same direction and at the same speed defines the azimuthal orientation of one of said cylinders relative to the other, while keeping the inclination fixed. 6. A robotic mechanism according to claim 1 wherein synchronized rotation of both said cylinders in opposite directions and at the same speed defines the inclination angle of one of said cylinders relative to the other while keeping the azimuthal orientation fixed. 7. A robotic mechanism according to claim 1 , wherein both of said end surfaces of at least one of said cylinders are obliquely formed end surfaces. 8. A robotic mechanism according to claim 1 , wherein that end surface of at least one of said cylinders, in sliding rotational contact with its associated base element, is formed perpendicular to the axis of said at least one cylinder. 9. A robotic mechanism comprising: a first and a second base element; first and second cylinders, each having an oblique truncated form, said cylinders being confined between said base elements such that an obliquely formed end surface of said first cylinder and an obliquely formed end surface of said second cylinder can mutually rotate in sliding association with each other; first and second driving motors attached to said first and second base elements, each driving motor being coupled to enable rotation relative to its base element of the cylinder adjacent to that base element, such that rotation of at least one of said cylinders causes said base elements to undergo change in their mutual orientation; clamping elements disposed external to said cylinders adapted to confine said cylinders between said base elements in rotary sliding association with each other and with their respective base elements; and at least one attachment member connected between said base elements to prevent their mutual angular rotation. 10. A robotic mechanism according to claim 9 , wherein said motors are adapted to generate relative rotation between said two cylinders, such that the axes of said cylinders undergo mutual change in inclination as said cylinders rotate relative to each other. 11. A robotic mechanism according to claim 9 , wherein rotation of one of said cylinders with respect to the other defines a combination of the inclination and the azimuthal orientation of one of said cylinder axes relative to the other. 12. A robotic mechanism according to claim 9 , wherein both of said end surfaces of at least one of said cylinders are obliquely formed end surfaces. 13. A robotic mechanism according to claim 9 , wherein that end surface of at least one of said cylinders, in sliding rotational contact with its associated base element, is formed perpendicular to the axis of said at least one cylinder. 14. A robotic mechanism according to claim 1 , wherein said passive inverted universal joint is any one of a flexible shaft, a spiral spring element, and a pair of half-shafts connected by a flexible polymer central section. 15. A robotic mechanism according to claim 9 , wherein said clamping elements disposed external to said cylinders are C-profile segments fitted onto lip flanges formed on said end surfaces of adjacent pairs of said cylinders. 16. A robotic mechanism according to claim 9 , wherein said at least one attachment member comprises hinged telescopic rods connecting said base elements at different circumferential points. 17. A robotic mechanism according to claim 9 , wherein a combination of rotation modes of said cylinders enables adjustment of the pose of one of said base elements relative to the other, within the envelope made available by the angles of inclination of the obliquely formed end surfaces of said two cylinders. 18. A robotic mechanism according to claim 9 , wherein synchronized rotation of both said cylinders in the same direction and at the same speed defines the azimuthal orientation of one of said cylinders relative to the other, while keeping the inclination fixed. 19. A robotic mechanism according to claim 9 , wherein synchronized rotation of both said cylinders in opposite directions and at the same speed defines the inclination angle of one of said cylinders relative to the other while keeping the azimuthal orientation fixed.