Wind turbines

The invention claimed is: 1. An upwind wind turbine comprising: a tower; a rotor; and a pressure sensing device disposed on the tower at a location within the wake of the rotor at a level corresponding to the lower half of a rotor disc defined by rotation of the rotor, the pressure sensing device configured to sense air pressure within the wake of the rotor and provide a signal indicative of the sensed air pressure to a wind turbine controller for use in controlling the rotor of the wind turbine. 2. The upwind wind turbine of claim 1 , wherein the pressure-sensing device is at least as far from a rotor axis as a longitudinal midpoint of a rotor blade. 3. The upwind wind turbine of claim 1 , wherein the pressure-sensing device is mounted at a height substantially corresponding to the height of the lowest point of a rotor disc defined by rotation of the rotor. 4. The upwind wind turbine of claim 1 , wherein the pressure-sensing device includes a plurality of sensors. 5. The upwind wind turbine of claim 4 , wherein the sensors are spaced around the circumference of the tower. 6. The upwind wind turbine of claim 4 , wherein two or more sensors are vertically spaced apart. 7. The upwind wind turbine of claim 1 , further comprising a monitoring device for monitoring wind speed and/or wind direction, the monitoring device being vertically spaced apart from the pressure-sensing device. 8. The upwind wind turbine of claim 7 , wherein the monitoring device is located within the wake of the rotor at a level corresponding to an upper half of a rotor disc defined by rotation of the rotor. 9. A method of controlling a wind turbine having a tower and a rotor, the method comprising sensing air pressure within the wake of the rotor at a location where the wake impinges upon the tower at a level corresponding to the lower half of a rotor disc defined by rotation of the rotor, and controlling the rotor based upon the sensed air pressure. 10. The method of claim 9 , further comprising controlling the rotor based upon wind speed and/or wind direction within the wake of the rotor at a level corresponding to an upper half of the rotor disc. 11. The method of claim 9 , further comprising determining the clearance between the tower and a point along a rotor blade as the blade passes the tower. 12. The method of claim 11 , further comprising monitoring surges in the sensed pressure as a blade passes the tower and inferring the clearance from characteristics associated with said surges. 13. The method of claim 11 further comprising increasing the clearance in the event that it approaches or falls below a predefined minimum value or if the probability of a collision between a blade and the tower exceeds a predetermined maximum acceptable value. 14. The method of claim 11 , further comprising introducing or varying a cyclic pitch pattern of the rotor blades to reduce the lift generated in the lower part of the rotor disc in the event that the clearance approaches or falls below a predefined minimum value or if the probability of a collision between a blade and the tower exceeds a predetermined maximum acceptable value. 15. A wind turbine control system for controlling a wind turbine having a tower and a rotor, wherein the wind turbine control system includes a wind turbine controller configured to receive a signal indicative of a sensed air pressure from a pressure-sensing device disposed on the tower at a location within the wake of the rotor at a level corresponding to the lower half of a rotor disc defined by rotation of the rotor, and to utilise the signal to control the rotor. 16. The wind turbine control system of claim 15 , further including a monitoring device for monitoring wind speed and/or wind direction within the wake of the rotor at a level corresponding to an upper half of the rotor disc, wherein the controller is configured to control the rotor in accordance with signals from the monitoring device and signals from the pressure-sensing device. 17. The wind turbine control system of claim 15 , wherein the controller is configured to monitor peaks in the signal from the pressure-sensing device, the peaks corresponding to surges in pressure as a blade passes the tower, and to determine, based upon characteristics of the peaks, the clearance between the tower and a point along a rotor blade, for example the tip of the blade, as the blade passes the tower. 18. The wind turbine control system of claim 17 , wherein the controller accesses a model correlating the characteristics of the peaks with values for the clearance. 19. The wind turbine control system of claim 17 , wherein the controller is configured to maintain the clearance within predefined limits and/or to maintain the probability of a collision between a blade and the tower below a predetermined maximum acceptable value.