Monitoring and control system

The invention claimed is: 1. A method of controlling the angular orientation of at least one variable fluidfoil, the method comprising the steps of: a) receiving detected fluidfoil angular orientation data for the at least one fluidfoil; b) receiving data regarding the operating point of the variable fluidfoil and/or of all or part of a broader system in which the variable fluidfoil is employed; c) receiving a fluidfoil angular orientation demand; d) selecting a modification algorithm for calculating a modified angular orientation demand, the selection of the modification algorithm being made according to the operating point of the variable fluidfoil and/or of all or part of a broader system in which the variable fluidfoil is employed; e) generating the modified demand by modifying the fluidfoil angular orientation demand before it is used to control adjustment of the at least one fluidfoil, the modification being performed using the detected fluidfoil angular orientation data; and f) outputting the modified demand and controlling the at least one fluidfoil angular orientation in accordance with the modified demand. 2. A method according to claim 1 where the detected fluidfoil angular orientation data is used when calculating the modified demand to adjust for an assumed fluidfoil angular orientation and/or assumed actuation system performance used in producing the demand. 3. A method according to claim 1 where the operating point of the variable fluidfoil and/or of all or part of the broader system is determined with reference to one or more operability maps for the variable fluidfoil and/or broader system respectively. 4. A method according to claim 3 further comprising receiving detected dynamic excitation data for the fluidfoil which is used in calculating the modified demand. 5. A variable fluidfoil control unit arranged in use to control the angular orientation of at least one fluidfoil, the control unit comprising a modification processor, a demand input and a fluidfoil angular orientation input, the modification processor being arranged in use to modify a fluidfoil angular orientation demand received via the demand input, before it is used to control adjustment of the at least one fluidfoil, the modification being performed using detected fluidfoil angular orientation data received via the fluidfoil angular orientation input; and the modification processor being further arranged to select a modification algorithm for calculating the modified demand, the selection of the modification algorithm being made according to the operating point of the variable fluidfoil and/or of all or part of a broader system in which the variable fluidfoil is employed. 6. A fluidfoil assembly comprising at least one variable fluidfoil, at least one rotary angular detector, and a receiver, wherein: the rotary angular detector is arranged to detect and output the angular orientation of the fluidfoil to the receiver, the receiver is a fluidfoil control unit arranged to control adjustments to the angular orientation of the fluidfoil, the fluidfoil control unit has a demand input arranged in use to receive fluidfoil angular orientation demands from a management system, the fluidfoil control unit further comprises a modification processor arranged to calculate angular orientation modifications for the fluidfoil, and the modification processor is in use an intermediary between the management system and the variable fluidfoil, using variable fluidfoil angular orientation information from the rotary angular detector to modify demands from the management system. 7. A fluidfoil assembly according to claim 6 where the modification processor has an algorithm input arranged to receive one or more modification algorithms from a digital store for use in calculating fluidfoil angular orientation modifications. 8. A fluidfoil assembly according to claim 7 where the fluidfoil control unit is provided with a parameter input arranged in use to receive operability data for the variable fluidfoil and/or all or part of the broader system, from the management system. 9. A fluidfoil assembly according to claim 7 where the modification processor has a map input arranged in use to receive one or more operability maps from a digital store, a selected map being used by the modification processor to ascertain the current operating point of the variable fluidfoil and/or of all or part of the broader system. 10. A fluidfoil assembly according to claim 6 where the rotary angular detector is further arranged to detect and output a dynamic excitation of the fluidfoil to the receiver. 11. A fluidfoil according claim 6 where at least one variable fluidfoil is provided with two rotary angular detectors, one at each end. 12. A fluidfoil according to claim 11 where a first detector is positioned at the proximal end of the fluidfoil relative to a rotational drive mechanism for the fluidfoil and is arranged to detect and output angular orientation. 13. A fluidfoil assembly according to claim 12 where a second detector is positioned at the distal end relative to the rotational drive mechanism for the fluidfoil and is arranged to detect dynamic excitation of the fluidfoil.