Compact load cells

The invention claimed is: 1. A force sensing apparatus for measuring forces in a load plane vertically offset from a sensor plane by a distance h, the force sensing apparatus comprising: at least one compact load cell comprising: at least three force sensing elements arranged in the sensor plane about a point and horizontally spaced a distance d from the point, each force sensing element comprising a pressure sensor encased in a force transmission medium such that the at least three force sensing elements form an array of pressure sensors; a load plate in contact with the force transmission medium; a load beam having a first end and a second end, the first end connected to the load plate and the second end extending axially from the point to the load plane; at least one rotor connected to the second end of the load beam located in the load plane; and wherein the load beam defines a motor shaft configured to drive the rotor such that forces acting on the rotor are transmitted to the sensor plane via the motor shaft, and a changing pressure field over the load plate produces measurements across the sensor elements from which axial and transverse forces applied to the rotor may be derived to calculate a local aerodynamic flow-field at the rotor; wherein the measurements obtained by the sensor elements include vertical and lateral components of force applied to the rotor; and wherein the force transmission medium is selected according to a desired degree of damping. 2. The force sensing apparatus of claim 1 , wherein the force sensing elements are arranged uniformly around the point. 3. The force sensing apparatus of claim 1 , wherein the force sensing elements are arranged non-uniformly with each sensing element a different distance d from the point. 4. The force sensing apparatus of claim 1 , wherein the sensor plane comprises a printed circuit board and the force sensing elements are bonded and electrically connected to the printed circuit board. 5. The force sensing apparatus of claim 4 , wherein the printed circuit board suitably includes signal processing electronics. 6. The force sensing apparatus of claim 1 , wherein the sensor plane comprises a single-die MEMS force-torque sensor. 7. The force sensing apparatus of claim 1 , wherein the force transmission medium is polyurethane rubber. 8. The force sensing apparatus of claim 1 , wherein the load plate is made from polymethylmethacrylate. 9. The force sensing apparatus of claim 1 , wherein the load plate is bonded to the force transmission medium. 10. The force sensing apparatus of claim 9 , wherein the bonding is by gluing. 11. The force sensing apparatus of claim 1 , wherein the motor shaft is flexible and is fixed to the centre of the load plate. 12. The force sensing apparatus of claim 11 , wherein the fixing is by gluing. 13. The force sensing apparatus of claim 11 , wherein the motor shaft is made of carbon fibre. 14. The force sensing apparatus of claim 1 , wherein the load beam is fixed to the whole load plate, or a substantial part of the load plate. 15. The force sensing apparatus of claim 1 , wherein an axis of the rotor is aligned with the centre of the load plate. 16. The force sensing apparatus of claim 1 , wherein the force sensing apparatus is fixed to a reference plane. 17. The force sensing apparatus of claim 16 , wherein the reference plane is a moving plane. 18. The force sensing apparatus of claim 17 , wherein the reference plane is an airframe of a Unmanned Aerial Vehicle (UAV). 19. The force sensing apparatus of claim 1 , further comprising an array of compact load cells and an array of rotors, wherein each compact load cell is attached to a vehicle and connected to a rotor of the vehicle. 20. A system for measuring forces on a vehicle, the system comprising: the force sensing apparatus according to claim 19 ; and a processor that receives the measurements from each array of pressure sensors of each compact load cell and calculates an aggregate thrust and an aggregate velocity of the vehicle by summing the measurements obtained from all scaled sensor readings of the compact load cells. 21. The system of claim 20 , wherein the force sensing apparatus comprises two compact load cells and two rotors. 22. The system of claim 20 , wherein the force sensing apparatus comprises four compact load cells and four rotors, each compact load cell comprising four force sensing elements. 23. The system of claim 20 , wherein the vehicle is a quadrotor Unmanned Aerial Vehicle (UAV) and there are four compact load cells and four rotors each offset from the center of mass of the quadrotor UAV. 24. The system of claim 23 , wherein the processor determines from the compact load cell measurements one or more of: pitch; yaw; roll; x-axis motion; y-axis motion; and z-axis motion at the rotors.