Phase current regulation in BLDC motors

The invention claimed is: 1. A method for determining a phase current direction and a zero-crossing moment of the phase current in a sinusoidally controlled brushless direct current motor, the brushless direct current motor comprising a coil per phase, wherein the phase of the brushless direct current motor is driven by a half bridge driver comprising a high side field effect transistor and a low side field effect transistor, the method comprising the following steps: measuring the drain source voltage over the high side field effect transistor and low side field effect transistor, determining the zero crossing moment of the phase current by determining the current direction based on the measured drain source voltages and by determining the moment the current changes direction. 2. The method according to claim 1 , wherein determining the zero crossing moment of the phase current comprises filling a current direction indication table with the current direction for each measurement. 3. A method for driving a sinusoidally driven brushless direct current motor, the brushless direct current motor comprising a coil per phase, wherein the phase of the brushless direct current motor is driven by a half bridge driver comprising a high side field effect transistor and a low side field effect transistor, the method comprising the following steps: applying a driving waveform to each field effect transistor of each phase wherein each of the driving waveforms has an undriven period, determining the zero-crossing moment of the phase current using a method according to claim 1 , determining a delay between the zero crossing moment of the current through the coil and a zero crossing moment of a back-electromotive force voltage over the coil, adjusting the driving waveforms with the determined delay such that the zero crossing of the phase current substantially corresponds with the zero crossing of the back-electromotive force voltage. 4. A method according to claim 3 , furthermore comprising, before the step of determining a delay between the zero crossing moment of the current through the coil and a zero crossing moment of a back-electromotive force voltage over the coil, measuring the back-electromotive force voltage during an undriven period of the phase, determining the zero crossing moment of the back-electromotive force voltage of the phase based on the measured back-electromotive force voltages. 5. The method according to claim 4 , wherein determining the zero crossing moment of the back-electromotive force voltage of the phase comprises filling a back-electromotive force voltage table with the measured back-electromotive force voltages sampled during the undriven period of the phase. 6. The method according to claim 3 , wherein at least one of the driving waveforms is pulse width modulated. 7. The method according to claim 3 , wherein the total current is measured by using a shunt resistor. 8. A current monitoring device for determining the phase current direction and zero-crossing moment of the phase current in a sinusoidally controlled brushless direct current motor, the brushless direct current motor comprising a coil per phase, wherein the phase of the brushless direct current motor is driven by a half bridge driver comprising a high side field effect transistor and a low side field effect transistor, the device comprising: a drain source voltage monitoring device for monitoring the drain source voltage over the field effect transistors, a processing device arranged for determining the phase current direction, and for determining the moment the phase current changes direction thus identifying the zero-crossing moment of the phase current. 9. A device for driving a sinusoidally driven brushless direct current motor, the brushless direct current motor comprising a coil per phase, wherein the phase of the brushless direct current motor is driven by a half bridge driver, wherein the half bridge driver comprises a high side field effect transistor and a low side field effect transistor, the device comprising: a current monitoring device according to claim 8 , a back-electromotive force voltage measurement and analysis unit for measuring the back-electromotive force voltage, determining the zero-crossing moment of the back-electromotive force voltage, a synchronization unit for time shifting the driving waveform such that the phase current and the back-electromotive force voltage are aligned.