Cockpit inceptor system

The invention claimed is: 1. An aircraft inceptor system comprising: an inceptor member arranged to be operated by a user to cause a corresponding movement of a moveable aircraft surface, the inceptor member comprising a force sensor and at least one of a position sensor to measure a position of the inceptor member, a speed sensor to measure a speed of movement of the inceptor member and an accelerometer to measure acceleration of the inceptor member; and means for detecting the operation of the inceptor member by the user and for providing a movement signal, associated with the detected operation, to a control device, the control device providing a control signal to an actuator to move the aircraft surface according to the movement signal; wherein the means for detecting the operation of the inceptor member by the user comprises the force sensor and the force sensor is configured to sense the force applied by the user to the inceptor member, the movement signal being derived based on the sensed force; wherein the control device provides the control signal based on an algorithm that converts a force signal indicative of the sensed force to a position signal; and wherein the algorithm takes into account system inertial load, calculated from the output of the at least one of a position sensor to measure a position of the inceptor, the speed sensor to measure a speed of movement of the inceptor and the accelerometer to measure acceleration of the inceptor, in converting the force signal to the position signal; wherein the algorithm takes into account system damping, calculated from the output of the at least one of the position sensor, the speed sensor and the accelerometer, in converting the force signal to the position signal; wherein the algorithm uses a vectorial sum of the sensed force and the inertial load and the damping load in converting the force signal to the position signal. 2. The system of claim 1 , wherein the algorithm converts the force signal to the position signal based on the static feel. 3. The system of claim 1 , wherein the algorithm includes a stop function defining a limit on the extent to which an increase in force causes a change in the position signal. 4. The system of claim 1 , wherein the control device is a device external to the inceptor member. 5. The system of claim 1 , further comprising means whereby the position signal is compared to a measured position signal indicative of the actual position to provide a position error. 6. The system of claim 1 , wherein the algorithm is performed: within the control device, in a device external to the control device; or by circuitry in the inceptor member. 7. The system of claim 1 , wherein the force sensor is located on or in the inceptor member closer to the part of the inceptor member to which the user directly applies force than any components of the inceptor member that could generate a jam condition. 8. The system of claim 1 , wherein the force sensor comprises a strain gauge, or wherein the sensor comprises a magnetostrictive sensor. 9. A method of controlling movement of an aircraft flight control surface, the method comprising: measuring a force applied by a user to a flight inceptor member with a force sensor in the flight intercept member; measuring a position of interceptor with a position sensor in the flight intercept member; measuring a speed of movement of the flight inceptor member with a speed sensor in the flight inceptor member; measuring with an accelerometer in the flight inceptor member an acceleration of the flight inceptor member; detecting the operation of the inceptor member by the user; providing a movement signal, associated with the detected operation, to a control device; wherein the algorithm takes into account system inertial load calculated from the output of the at least one of a position sensor to measure a position of the inceptor, the speed sensor to measure a speed of movement of the inceptor and the accelerometer to measure acceleration of the inceptor, in converting the force signal to the position signal; wherein the algorithm takes into account system damping, calculated from the output of the at least one of the position sensor, the speed sensor and the accelerometer, in converting the force signal to the position signal; wherein the algorithm uses a vectorial sum of the sensed force and the inertial load and the damping load in converting the force signal to the position signal; and controlling movement of the flight control surface according to the control signal. 10. The method of claim 9 , wherein the algorithm converts the force signal to the position signal based on the static feel; or wherein the algorithm includes a stop function defining a limit to the extent to which an increase in force causes a change in the position signal. 11. The method of claim 9 , wherein the position signal is compared to a measured position signal indicative of the actual position to provide a position error. 12. The method of claim 9 , wherein the force signal is indicative of the sensed force, the force signal being corrected using the algorithm, the corrected force signal used by a control device to cause movement of the flight control surface, the control device having an architecture allowing continued control of the flight control surface in the event of a jam of the inceptor member without any reconfiguration of logic used by the control device and without the need to use an alternative input signal.