Compact vibration reducing human support

The invention claimed is: 1. A vibration reduction system VRS with: a grounding for fixing the VRS to a vibrating environment; a frame for carrying a support structure suitable for supporting a live human; a plurality of displacement actuators, each having two ends, including a stator end, an actuator end, and a displacement extension range in a direction associated with the respective actuator, with each of the actuators having one of the two end affixed to the frame, and the other of the two ends affixed to the grounding; one or more elastomeric damping bodies (EDBs) composed of a material having a dynamic Young's Modulus of 0.1-2.5 MPa, and a resilience test rebound height less than 40%, and having a first end affixed to the grounding and a second end affixed to the frame to provide elastic restorative forces and damping in each of the respective directions along an axis of the EDB; and no other path to couple the ground to the frame in any of the respective directions under normal operating conditions of the VRS. 2. The VRS of claim 1 where the grounding comprises a bracket for retaining a casing of at least one of the actuators, wherein the bracket: surrounds at least one of the plurality of actuators; composed of an assembly of separate parts; is adjustable for a size, weight or feature of the live human; is releasably mountable to the grounding, frame or one or more EDBs; or is reconfigurably mountable to the grounding, frame or one or more EDBs in two or more arrangements. 3. The VRS of claim 2 where a first of the at least one EDBs is mounted on one side to a wall of the casing, which squarely faces an opposite wall of one of the grounding and frame to constrain the EDB, whereby the casing is part of the frame or grounding. 4. The VRS of claim 1 where the bracket has a surface, and a first of the at least one EDBs is mounted on one side to the bracket surface, which squarely faces an opposite wall of one of the grounding structure and frame to confine the EDB. 5. The VRS of claim 4 where the first EDB alone, or with one or more of the at least one EDBs, is arranged so that the EDB rotationally symmetrically surrounds the actuator end of a first of the actuators, or the first EDB's axis is collinear with a direction of the first actuator's extension range. 6. The VRS of claim 1 where the axis of the first EDB is parallel to both first and second actuators of the plurality of actuators, and the first EDB alone, or with one or more of the at least one EDBs, are arranged to lie: symmetrically between the first and second actuators, symmetrically around the first and second actuators; or both. 7. The VRS of claim 6 where first and second actuators are: aligned to a common plane and the symmetry is rotational symmetry about a centre of the first and second actuators in this plane; or oriented oppositely and offset by 0.5-1 times a width of the first and second actuator bodies in an offset direction that is perpendicular to the direction of the first and second actuators's extension ranges, and the symmetry is rotational symmetry about a centre of the first and second actuators in a plane spanned by the offset direction and the direction of the first and second actuators's extension ranges. 8. The VRS of claim 1 further comprising a sensor sensitive to vibrations and a feedback circuit for controlling motors of the plurality of actuators. 9. The VRS of claim 1 wherein the actuation directions of the plurality of actuators span 1, 2 or 3 Cartesian directions and: an equal number and power of the actuators are provided in each actuation direction, and each EDB has an equivalent absorption profile; or a higher number of actuators or higher power actuators are disposed in directions of greatest vibration amplitudes, or in directions where vibrations are more injurious to an occupant. 10. The VRS of claim 1 wherein the one or more EDBs have a shape factor to control stiffness and damping in multiple degrees of freedom. 11. The VRS of claim 1 wherein the material has a resilience test rebound height of 3-30. 12. The VRS of claim 1 wherein the material has a resilience test rebound height of 5-15. 13. The VRS of claim 1 wherein the material is sorbothane. 14. The VRS of claim 1 wherein each of the actuators has a displacement actuation range of 0.75-25 mm. 15. The VRS of claim 1 wherein each of the actuators has a displacement actuation range of 0.8-8 mm. 16. The VRS of claim 1 wherein each of the actuators is adapted to exert a force of at least 20 N. 17. The VRS of claim 1 wherein the human support is designed to support a whole human body, or part thereof, in one or more poses and orientations, including standing, seated, or squatted, erect, recumbent, or partially recumbent. 18. The VRS of claim 1 wherein the human support is a floor, chamber, panel, seat, armrest, table, bench, bed, sling, hammock, harness or suspension system. 19. The VRS of claim 1 further comprising a failure support in event of excessive force that engages to mechanically couple the frame to the grounding that bypasses the actuators, in the event of a force that exceeds a threshold.