Current measuring apparatus for use with electric motors

The invention claimed is: 1. A current measuring circuit adapted to provide an output indicative of the change in the current flowing in at least one phase of an electric motor over a measurement period of time, the current measurement circuit including: a current measurement element having a resistance in series with at least one phase of the motor; a switch which, in use, selectively permits and prevents transmission of a voltage that is indicative of the instantaneous value of the voltage dropped across the current measurement element to a part of the current measurement circuit that measures the change in the voltage dropped across the current measurement element during the measurement period of time; and a switch controller which is adapted to operate the switch in response to timing signals supplied by the switch controller so as to define the measurement period of time, in which the current measurement circuit is adapted to provide an output indicative of the change in the current flowing in the at least one phase during the measurement period of time, wherein the measurement period of time either starts after the leading edge of a pulse and ends before the next trailing edge of the pulse or starts after a trailing edge of the pulse and before the next leading edge of a pulse, the voltage applied to the phase being constant during the measurement period of time, and to determine therefrom the inductance of at least one of the phases thereby to determine the rotational position of the motor from a known variation of inductance with motor position. 2. A current measuring circuit according to claim 1 in which the switch is operable between a first state in which it is open and a second state in which it is closed. 3. A current measuring circuit according to claim 1 in which the current measuring element comprises one or more resistors connected in series with a phase of the motor such that current flowing through the motor phase flows through the resistor, the measuring circuit being arranged to measure the change in the voltage dropped across the resistor during the measurement period of time. 4. A current measuring circuit according to claim 3 which further includes a capacitor which prior to the measurement period of time is electrically connected to the resistor when the switch is in the first state such that the voltage across the capacitor is dependent on the voltage across the resistor, and which during the measurement period of time the capacitor is electrically isolated from the resistor so as to hold across its terminals a voltage equal to the voltage across the resistor at the time that the switch is moved to it second state. 5. A current measuring circuit according to claim 4 in which in the first state the switch is open and in the second state it is closed. 6. A current measuring circuit according to claim 4 in which the capacitor and switch form part of a sample and hold circuit with the switch performing the function of the trigger for the sample and hold circuit. 7. A current measuring circuit according to claim 6 in which the sample and hold circuit comprises a differential amplifier having a first input connected to the current measuring element and a second input connected to the side of the capacitor that is not connected to the switch. 8. A current measuring circuit according to claim 1 which includes a capacitor which prior to the measurement period of time is electrically connected at one end to the resistive element both immediately prior to the measuring period and during the measuring period and in which the switch is adapted to connect the other end of the capacitor to ground immediately prior to the measuring period of time and to isolate the said other end of the capacitor from ground during the measurement period of time. 9. A current measuring circuit according to claim 8 in which the said other end of the capacitor is electrically connected to the input of an amplifier to form a keyed clamp or DC restoration amplifier circuit with respect to the DC component of the voltage dropped across the resistive element. 10. A current measuring circuit according to claim 1 in which the switch comprises a field effect transistor, the control signal being applied to the base of the transistor to vary the impedance between its collector and emitter. 11. A current measuring circuit according to claim 1 in which the output from the measuring circuit is further amplified using an analogue amplifier and then fed to an A/D converter where the magnitude of the signal is converted into digital form as a measured current value. 12. A drive system for a multi-phase brushless electric motor comprising a plurality of phases, the system comprising: a drive circuit including phase switching means for varying the phase voltage applied across each of the plurality of phases, and control means arranged to control the phase switching means so as to provide PWM control of the phase voltages to control the mechanical output of the multi-phase brushless electric motor, measure a rate of change of current in at least one of the plurality of phases during a test period and to determine therefrom the inductance of at least one of the plurality of phases thereby to determine the rotational position of the multi-phase brushless electric motor, the control means determining the change of current using the output of a current measurement circuit comprising: a current measurement element in series with at least one phase of the motor; a switch which, in use, selectively permits and prevents transmission of a voltage that is indicative of the voltage dropped across the current measurement element to a part of the current measurement circuit that measures the change in the voltage dropped across the current measurement element during the measurement period of time; and a switch controller which is adapted to operate the switch in response to timing signals supplied by the switch controller so as to define the measurement period of time in which the current measurement circuit is adapted to provide an output indicative of the change in the current flowing in the at least one phase during the measurement period of time, wherein the measurement period of time either starts after the leading edge of a pulse and ends before the next trailing edge of the pulse or starts after a trailing edge of the pulse and before the next leading edge of a pulse, the voltage applied to the phase being constant during the measurement period of time, and to determine therefrom the inductance of at least one of the phases thereby to determine the rotational position of the motor from a known variation of inductance with motor position. 13. The system of claim 12 which includes a memory which stores inductance values relative to motor angular position. 14. A current measuring circuit according to claim 1 in which the switch ensures that at least parts of the measuring circuit is not exposed to the voltage request the current measurement element at a time when excessively high rates of change of current occur in the phase. 15. A current measuring circuit according to claim 12 in which the switch ensures that at least parts of the measuring circuit is not exposed to the voltage request the current measurement element at a time when excessively high rates of change of current occur in the phase.