Characterising motion constraints

The invention claimed is: 1. A robot comprising: a base; a flexible arm extending from the base and having a plurality of joints whereby the configuration of the aim can be altered, a plurality of drivers arranged to drive the joints to move, a plurality of sensors configured to sense the position of each of the joints and an attachment structure configured to attach a tool to the arm, the joints permitting the angular attitude of the attachment structure relative to the base to be varied; and a control unit configured to control the drivers and to receive inputs from the sensors indicating the position of the joints, and operable in a calibration mode in which, whilst a tool is attached to the attachment structure and captive in a port, it: (i) controls the drivers so as to permit the aim to be reconfigured by the action of an external force applied to the arm; (ii) from the sensor inputs indicating the position of the joints, monitors the configuration of the arm under the presence of each of a plurality of external forces applied to the arm and transmitted through the tool to the port so as to cause the attitude of the attachment structure to the base to alter; and (iii) estimates the natural centre of rotation of the port from the monitored arm configurations. 2. A robot as claimed in claim 1 , wherein the control unit is configured to estimate the natural centre of rotation of the port as a point through which a straight line extended with constant angular attitude relative to the attachment point is maintained under the presence of each external force. 3. A robot as claimed in claim 2 wherein the control unit is configured to store the estimated natural centre of rotation of the port. 4. A robot as claimed in claim 3 , the control unit being operable in a driven mode in which, when a tool is attached to the attachment structure, it receives a demand signal indicating a desired location of a part of the tool, calculates a configuration of the arm in which the part of the tool will be at the desired location and the tool intersects the natural centre of rotation of the port, and controls the drivers so the aim adopts the calculated configuration. 5. A robot as claimed in claim 1 , wherein the control unit is configured to, in the calibration mode, control the drivers so as to resist the action of gravity and thereby cause the arm to maintain a configuration imposed by each external force independently of the action of gravity. 6. A robot as claimed in claim 1 , wherein the control unit is configured to, in the calibration mode, control the drivers so as to present a limited resistance to reconfiguration under each external force independently of the action of gravity. 7. A robot as claimed in claim 1 , wherein the control unit is configured to, in the calibration mode, control the drivers so as to present increasing resistance to reconfiguration under each external force as the arm is moved so as to increase the deviation of the attitude of the attachment structure relative to the base from a neutral value. 8. A robot as claimed in claim 1 , wherein the control unit is configured to, in the calibration mode, control the drivers so as to resist angulation beyond a predetermined threshold of a tool attached to the arm. 9. A robot as claimed in claim 1 , wherein the control unit is configured to, in the calibration mode, control the drivers so as to resist translation beyond a predetermined threshold of a tool attached to the arm in a direction away from the interface between the tool and the arm. 10. A robot as claimed in claim 1 , wherein the arm comprises a plurality of force sensors configured to sense forces applied about the joints, and the control unit is configured to, in the calibration mode, control the drivers in dependence on the outputs of the force sensors. 11. A robot as claimed in claim 1 , wherein the control unit comprises a processor and a memory configured to store non-transiently a set of instructions executable by the processor for implementing the calibration mode. 12. A robot as claimed in claim 1 , comprising a tool attached to the attachment structure, the tool being a surgical tool. 13. A robot as claimed in claim 1 , wherein the robot is a surgical robot. 14. A method configured to control a robot, the robot comprising a base; a flexible arm extending from the base and having a plurality of joints whereby the configuration of the arm can be altered, a plurality of drivers arranged to drive the joints to move, a plurality of sensors configured to sense the position of each of the joints and an attachment structure configured to attach a tool to the arm, the joints permitting the angular attitude of the attachment structure relative to the base to be varied; the method comprising, whilst a tool is attached to the attachment structure and captive in a port: control the drivers so as to permit the arm to be reconfigured by the action of an external force applied to the aim; from the sensor inputs indicating the position of the joints, monitoring the configuration of the aim under the presence of each of a plurality of external forces applied to the arm and transmitted through the tool to the port so as to cause the attitude of the attachment structure to the base to alter; and estimating the natural centre of rotation of the port from the monitored arm configurations.