Position sensing device

The invention claimed is: 1. A position sensing device for measuring a position, the position sensing device comprising: a plurality of sensors, each of the plurality of sensors being arranged to produce a respective sense signal, each of the respective sense signals produced by the plurality of sensors being a function of an input phase representative of a position to be measured, a combiner circuit arranged to receive each of the sense signals respectively produced by the plurality of sensors and to generate an error signal by combining the respective sense signals produced by the plurality of sensors according to a plurality of weight factors, the error signal being indicative of a difference between an output phase representative of the position and the input phase representative of the position to be measured, a processing block comprising a loop filter to filter the error signal and to produce a filtered error signal, the processing block being further configured to obtain from the filtered error signal an estimated output phase, and a feedback loop comprising a feedback signal unit arranged for receiving the estimated output phase and for adjusting based on the estimated output phase the plurality of weight factors, so that the weight factors are a function of the estimated output phase, wherein the plurality of sensors comprises at least three sensors, each of the at least three sensors being arranged to respectively produce a sense signal, each of the respective sense signals produced by the at least three sensors being a different function of an input phase representative of a position to be measured. 2. The position sensing device as in claim 1 , wherein the combiner circuit, the processing block, and the feedback signal unit are implemented in the digital domain. 3. The position sensing device as in claim 1 , wherein the estimated output phase is a quantized signal. 4. The position sensing device as in claim 1 , wherein the feedback signal unit comprises an angle-to-gain conversion block arranged for receiving the estimated output phase. 5. The position sensing device as in claim 4 , further comprising a digital gain control unit arranged to adapt the weight factors. 6. The position sensing device as in claim 5 , wherein the plurality of weight factors is implemented by switchably connected components in the digital gain control unit. 7. The position sensing device as in claim 1 , wherein the sensors are magnetic sensors arranged for measuring an angle of a magnetic field. 8. The position sensing device as in claim 1 , wherein the error signal is proportional to the difference between the output phase and the input phase. 9. The position sensing device as in claim 1 , wherein the weight factors are trigonometric functions of the estimated output phase. 10. The position sensing device as in claim 1 , wherein the feedback signal unit is arranged for adjusting the plurality of weight factors based on software-based calculations and/or digital logic performed on the estimated output phase. 11. The position sensing device as in claim 1 , wherein the number of weight factors equals the number of sensor signals. 12. A position sensing device for measuring a position, the position sensing device comprising: a plurality of sensors including at least a first sensor and a second sensor, each of the plurality of sensors being arranged to produce a respective sense signal such that the first sensor produces at least a first sense signal and the second sensor produces at least a second sense signal, each of the respective sense signals produced by the plurality of sensors being a function of an input phase representative of a position to be measured, a combiner circuit arranged to receive each of the sense signals produced by the plurality of sensors including the first sense signal and the second sense signal and to generate an error signal by combining each of the sense signals produced by the plurality of sensors including the first sense signal and the second sense signal with a plurality of corresponding weight factors, the error signal being indicative of a difference between an output phase representative of the position and the input phase representative of the position to be measured, a processing block comprising a loop filter to filter the error signal and to produce a filtered error signal, the processing block being further configured to obtain from the filtered error signal an estimated output phase, and a feedback loop comprising a feedback signal unit arranged for receiving the estimated output phase and for adjusting based on the estimated output phase the plurality of weight factors, so that the weight factors are a function of the estimated output phase, wherein the plurality of sensors includes a third sensor, wherein the third sensor is arranged to produce a third sense signal, the third sense signal also being a function of an input phase representative of a position to be measured. 13. The position sensing device as in claim 12 , wherein the combiner circuit is arranged to combine the first sense signal and the second sense signal with a plurality of corresponding weight factors by multiplying the first sense signal with a first corresponding weight factor and the second sense signal with a second corresponding weight factor. 14. The position sensing device as in claim 12 , wherein the combiner circuit is arranged to receive the first sense signal, the second sense signal, and third sense signal and to generate an error signal by combining the first sense signal, the second sense signal, and third sense signal with a plurality of corresponding weight factors, the error signal being indicative of a difference between an output phase representative of the position and the input phase representative of the position to be measured.