Accelerometer control

The invention claimed is: 1. An accelerometer closed loop control system comprising: a capacitive accelerometer comprising a proof mass moveable relative to first and second fixed capacitor electrodes; a pulse width modulation (PWM) generator arranged to generate in-phase and anti-phase PWM drive signals with a drive frequency and an adjustable mark/space ratio, wherein said in-phase and anti-phase PWM drive signals are applied to the first and second fixed capacitor electrodes respectively such that they are charged alternately, wherein the in-phase PWM drive signal has a first amplitude and the anti-phase PWM drive signal has a second amplitude; an output signal detector arranged to detect a pick-off signal from the accelerometer representing a displacement of the proof mass from a null position to provide an error signal, wherein the null position is the position of the proof mass relative to the first and second fixed capacitor electrodes when no acceleration is applied; a PWM servo operating in closed loop arranged to vary the adjustable mark/space ratio of said in-phase and anti-phase PWM drive signals in response to the error signal so that mechanical inertial forces are balanced by electrostatic forces to maintain the operating point of the proof mass at a null position; and a differential voltage servo arranged to vary a difference between the first amplitude of the in-phase PWM drive signal and the second amplitude of the anti-phase PWM drive signal in response to the error signal. 2. The accelerometer closed loop control system as claimed in claim 1 , wherein the differential voltage servo comprises a microcontroller arranged to produce first and second digital control words, wherein: said first digital control word is input to a first digital to analogue converter arranged to receive the in-phase PWM drive signal at a first reference input and output a scaled in-phase PWM drive signal; and said second digital control word is input to a second digital to analogue converter arranged to receive the anti-phase PWM drive signal at a second reference input and output a scaled anti-phase PWM drive signal. 3. The accelerometer closed loop control system as claimed in claim 1 , wherein the PWM servo comprises an integral loop filter arranged to vary the adjustable mark/space ratio in response to the integral of the error signal. 4. The accelerometer closed loop control system as claimed in claim 1 , wherein the differential voltage servo is arranged to vary the in proportion to the error signal. 5. The accelerometer closed loop control system of claim 1 , wherein the error signal is digital. 6. The accelerometer closed loop control system as claimed in claim 1 , wherein the output signal detector comprises a charge amplifier having an input connected to the proof mass and an output, said charge amplifier being arranged to produce at its output a voltage proportional to the capacitance between the proof mass and whichever of the first and second capacitor electrodes is charged at any given time. 7. The accelerometer closed loop control system as claimed in claim 6 , wherein the output signal detector further comprises a demodulator having an input connected to the output of the charge amplifier, wherein said demodulator is arranged to: sample the output of the charge amplifier while the in-phase PWM drive signal is high so as to produce a first sample; sample the output of the charge amplifier while the anti-phase PWM drive signal is high so as to produce a second sample; and calculate a difference between said first and second samples; and produce the error signal, wherein the error signal is dependent on said difference. 8. The accelerometer closed loop control system as claimed in claim 7 , wherein the demodulator is further arranged to receive a synchronisation signal, wherein the demodulator uses said synchronisation signal to produce the error signal at a predetermined frequency. 9. The accelerometer closed loop control system as claimed in claim 8 , wherein the predetermined frequency is the drive frequency. 10. A closed loop method of controlling a capacitive accelerometer comprising a proof mass moveable relative to first and second fixed capacitor electrodes, the method comprising: applying in-phase and anti-phase pulse width modulation (PWM) drive signals to the first and second fixed capacitor electrodes with an adjustable mark/space ratio, wherein the in-phase PWM drive signal has a first amplitude and the anti-phase PWM drive signal has a second amplitude; detecting a pick-off signal from the accelerometer representing a displacement of the proof mass from a null position to provide an error signal, wherein the null position is the position of the proof mass relative to the first and second fixed capacitor electrodes when no acceleration is applied; operating in closed loop by varying the adjustable mark/space ratio of said in-phase and anti-phase PWM drive signals in response to the error signal so that mechanical inertial forces are balanced by electrostatic forces to maintain the operating point of the proof mass at the null position; and using the error signal so as to vary a difference between the first amplitude of the in-phase PWM drive signal and the second amplitude of the anti-phase PWM drive signal. 11. The closed loop method as claimed in claim 10 , further comprising: produce first and second digital control words; using said first digital control word and the in-phase PWM drive signal to produce a scaled in-phase PWM drive signal; and using said second digital control word and the anti-phase PWM drive signal to produce a scaled anti-phase PWM drive signal. 12. The closed loop method as claimed in claim 10 , wherein the error signal is digital. 13. The closed loop method as claimed in claim 10 , further comprising: producing a voltage proportional to the capacitance between the proof mass and whichever of the first and second capacitor electrodes is charged at any given time. 14. The closed loop method as claimed in claim 13 , further comprising: sampling the voltage proportional to the capacitance while the in-phase PWM drive signal is high so as to produce a first sample; sampling voltage proportional to the capacitance while the anti-phase PWM drive signal is high so as to produce a second sample; and calculating a difference between said first and second samples; and producing the error signal, wherein the error signal is dependent on said difference. 15. The closed loop method as claimed in claim 14 , further comprising using a synchronisation signal to produce the error signal at a predetermined frequency.