Control of magnetic sector mass spectrometer magnet

The invention claimed is: 1. A control system for controlling a magnet of a magnetic sector mass spectrometer, comprising: a magnetic field sensor for sensing the magnetic field of the magnet and generating an output representative thereof; a set point generator configured to generate an output representative of, or related to, a desired magnetic field of the magnet; and a digital controller configured to receive a variable digital input signal from the output of the magnetic field sensor and a set point digital input signal from the output of the set point generator, and to generate a digital output from which is derived a control signal for controlling a current to the magnet so as to control, in turn, the magnetic field thereof; an ion detector for detecting ions passing through the magnetic sector mass spectrometer, the ion detector being configured to generate a detector output signal representative of the quantity of ions incident upon the detector; and a processor, wherein the processor is arranged to receive the detector output signal, and configured to calculate a controller setting based upon the detection of ions at the detector, and wherein the control system is arranged to apply to the digital controller a selected one of a plurality of different controller settings, in accordance with the desired magnetic field of the magnet. 2. The control system of claim 1 , wherein the magnetic field sensor further comprises an analogue to digital converter (ADC) so as to convert an analogue signal representative of the magnetic field of the magnet into the said variable digital input signal for the digital controller, at the magnetic field sensor. 3. The control system of claim 2 , further comprising a temperature controlling arrangement for controlling the ADC output in accordance with the temperature of the ADC and magnetic field sensor. 4. The control system of claim 3 , wherein the temperature controlling arrangement includes a temperature sensor positioned so as to determine the temperature at or adjacent the magnetic field sensor. 5. The control system of claim 4 , wherein the temperature sensor has an output that is provided to the ADC, for temperature correction of the magnetic field measured by the magnetic field sensor. 6. The control system of claim 5 , wherein the digital controller is furnished with a calibration curve or look up table representative of the response of the magnetic field sensor as a function of the temperature measured by the temperature sensor, the temperature sensor output being supplied as a further input to the digital controller which then adjusts the variable digital input signal derived from the magnetic field sensor in accordance with the temperature sensor output. 7. The control system of claim 4 , wherein the temperature controlling arrangement further comprises a temperature controller and a heater/cooler, the temperature sensor providing a measured input to the temperature controller for comparison against a set point temperature input, the temperature controller generating a control signal output to the heater/cooler so as to reduce an error between the set point and measured temperature inputs. 8. The control system of claim 7 further comprising a digital filter arranged to filter the ADC output. 9. The control system of claim 8 , wherein the digital filter is an infinite impulse response filter such as a Chebyshev type I filter. 10. The control system of claim 1 , wherein the magnetic field sensor is a magneto-resistive sensor formed from a single crystal. 11. The control system of claim 1 , further comprising a digital to analogue converter (DAC) arrangement for converting the digital output of the digital controller into an analogue signal. 12. The control system of claim 11 , wherein the DAC arrangement forms a part of the digital controller. 13. The control system of claim 11 , further comprising an analogue power amplifier between the digital controller and the magnet, for amplifying the output of the DAC arrangement. 14. The control system of claim 13 , further comprising an analogue damping circuit arranged between magnet and the analogue power amplifier, the analogue damping circuit having an output which is combined with the output of the DAC to form a first input to the analogue power amplifier. 15. The control system of claim 14 , wherein the power amplifier is an operational amplifier, the combination of the analogue damping circuit output and the DAC output being connected to the non inverting input of the operational amplifier. 16. The control system of claim 14 , wherein the analogue damping circuit has a switchable frequency response. 17. The control system of claim 11 , wherein the DAC arrangement comprises a plurality of DACs. 18. A magnetic sector mass spectrometer comprising: an ion source arranged to generate a beam of ions having a mass to charge ratio m/z; an ion accelerator arranged to accelerate ions to a potential U o ; and a magnet under the control of the control system of claim 1 , arranged to divert the accelerated ions along a circular path in accordance with m/z, U o , and the magnetic flux density within the magnet. 19. The magnetic sector mass spectrometer of claim 18 , further comprising a second ion detector also positioned downstream of the magnet but spatially separated in a transverse direction perpendicular to the direction of travel of the ion beam; wherein the ion beam comprises ions of first and second mass-to-charge ratios, the processor being configured to control the parameters of the mass spectrometer so as to align an edge of a mass spectral peak of ions of the first mass-to-charge ratio with the second ion detector, whilst ions of the second mass to charge ratio are directed toward the first ion detector. 20. A magnetic sector mass spectrometer according to claim 19 , wherein the ion source is arranged to generate a beam of ions containing a plurality of ion species each having a mass to charge ratio (m/z) i ; the ion accelerator is arranged to accelerate the ions in the ion beam to a potential U o ; the magnet is arranged to divert the accelerated ions along a circular path in accordance with (m/z) i , U o and the magnetic flux density B within the magnet; the ion source is arranged to generate ions of a first sacrificial on species having a mass to charge ratio (m/z) 1 which follow a first curved path within the magnet, and to generate ions of a second, analyte ion species different to the sacrificial species having a mass to charge ratio (m/z) 2 which follow a second curved path, different to the first curved path, within the magnet, and further wherein the ion detection arrangement has a plurality of spatially separated detectors; the control system being configured to adjust one or more of the flux density B, the acceleration potential U 0 and/or the position of a detector or detectors in the ion detection arrangement, so that ions of the sacrificial species are directed toward a first detector in order that the edge of a mass peak representative of those ions of the sacrificial species is aligned with the first detector, whilst ions of the analyte ion species are directed toward a second detector, spatially separated from the first detector, so that a mass Peak representative of those analyte ions is generally aligned with the second detector away from the mass peak edges; and further wherein the magnetic field sensor includes the first detector, the first detector having an output signal representin