High Frequency Voltage Supply Control Method for Multipole or Monopole Analysers

1 . A voltage supply system for supplying an RF voltage to an RF resonant load comprising an ion-optical component of a mass spectrometer, said system comprising: a Direct Digital Synthesiser (“DDS”) arranged and adapted to output an RF voltage; wherein said voltage supply system is arranged and adapted: (i) to vary the frequency of said RF voltage output by said Direct Digital Synthesiser; (ii) to determine a first resonant frequency of said RF resonant load comprising said ion-optical component; (iii) to determine whether or not the generation of an RF voltage at said first resonant frequency by said Direct Digital Synthesiser would also result in the generation of a spur frequency close to said first resonant frequency; wherein if it is determined that a spur frequency would be generated close to said first resonant frequency then said voltage supply system is further arranged and adapted: (iv) to consult a look-up table comprising one or more preferred frequencies; and (v) to direct said Direct Digital Synthesiser to generate an RF voltage at a second frequency which corresponds with one of said preferred frequencies from said look-up table, wherein said second frequency is different to said first resonant frequency. 2 . A voltage supply system as claimed in claim 1 , wherein said RF load comprising said ion-optical component has a first resonant frequency f c and a quality factor Q and wherein a spur frequency is close to said first resonant frequency f c if said spur frequency is within 10f c /Q of said first resonant frequency f c . 3 . A voltage supply system as claimed in claim 1 , wherein said voltage supply system is arranged and adapted to scan or step through said one or more preferred frequencies. 4 . A voltage supply system as claimed in claim 1 , wherein said voltage supply system is arranged and adapted to determine which of said one or more preferred frequencies is closest to said first resonant frequency. 5 . A voltage supply system as claimed in claim 4 , wherein said voltage supply system is arranged and adapted to generate an RF voltage at said second frequency which corresponds with one of said one or more preferred frequencies which is determined to be closest to said first resonant frequency. 6 . A voltage supply system for supplying an RF voltage to an RF resonant load comprising an ion-optical component of a mass spectrometer, said system comprising: a Direct Digital Synthesiser (“DDS”) arranged and adapted to output an RF voltage; wherein said voltage supply system is arranged and adapted: (i) to vary the frequency of said RF voltage output by said Direct Digital Synthesiser; (ii) to determine a first resonant frequency of said RF resonant load comprising said ion-optical component; (iii) to determine whether or not the generation of an RF voltage at said first resonant frequency by said Direct Digital Synthesiser would also result in the generation of a spur frequency close to said first resonant frequency; wherein if it is determined that a spur frequency would be generated close to said first resonant frequency then said voltage supply system is further arranged and adapted: (iv) to consult a look-up table comprising one or more undesired frequencies; and (v) to direct said Direct Digital Synthesiser to generate an RF voltage at a second frequency which does not correspond with one of said undesired frequencies from said look-up table, wherein said second frequency is different to said first resonant frequency. 7 . A voltage supply system as claimed in claim 6 , wherein said RF load comprising said ion-optical component has a first resonant frequency f c and a quality factor Q and wherein a spur frequency is close to said first resonant frequency f c if said spur frequency is within 10f c /Q of said first resonant frequency f c . 8 . A voltage supply system as claimed in claim 1 , wherein said second frequency is substantially close to said first resonant frequency but does not result in the generation of a spur frequency close to said first resonant frequency. 9 . A voltage supply system as claimed in claim 1 , wherein said Direct Digital Synthesiser is arranged and adapted to output a generally sinusoidal RF voltage having a fixed amplitude. 10 . A voltage supply system as claimed in claim 1 , wherein said Direct Digital Synthesiser further comprises a Numerically Controlled Oscillator (“NCO”). 11 . A voltage supply system as claimed in claim 10 , wherein said Direct Digital Synthesiser further comprises a Digital to Analogue Converter (“DAC”) coupled to an output of said Numerically Controlled Oscillator. 12 . A voltage supply system as claimed in claim 1 , wherein said voltage supply system comprises a digital controller arranged and adapted to control the frequency of said RF voltage output by said Direct Digital Synthesiser. 13 . A voltage supply system as claimed in claim 1 , further comprising one or more amplifiers for amplifying said RF voltage output by said Direct Digital Synthesiser so that an amplified RF voltage is supplied to said RF resonant load comprising said ion-optical component. 14 . A voltage supply system as claimed in claim 1 , further comprising an RF amplitude measurement device arranged and adapted to determine the amplitude of said RF voltage as supplied to said RF resonant load comprising said ion-optical component. 15 . A voltage supply system as claimed in claim 1 , wherein said voltage supply system is arranged and adapted to determine said first resonant frequency at which the measured amplitude of said RF voltage as supplied to said RF resonant load comprising said ion-optical component is at a maximum or wherein the RF is maximum when compared with a drive level. 16 . A voltage supply system as claimed in claim 1 , wherein said ion-optical component comprises a multipole or monopole mass filter or mass analyser. 17 . A voltage supply system as claimed in claim 16 , wherein said ion-optical component comprises a quadrupole mass filter or mass analyser. 18 . A voltage supply system as claimed in claim 1 , wherein said ion-optical component comprises an RF ion trap. 19 . A voltage supply system as claimed in claim 1 , further comprising an RF amplitude detector arranged and adapted to output a DC voltage or current which is substantially proportional to the amplitude and the frequency of said RF voltage as supplied to said RF resonant load comprising said ion-optical component. 20 . A voltage supply system as claimed in claim 1 , further comprising one or more fixed inductors which couple said voltage supply system to said ion-optical component. 21 . A mass spectrometer comprising a voltage supply system as claimed claim 1 . 22 . A mass spectrometer as claimed in claim 21 , wherein said mass spectrometer comprises a miniature mass spectrometer. 23 . A method of supplying an RF voltage to an RF resonant load comprising an ion-optical component of a mass spectrometer comprising: providing a Direct Digital Synthesiser (“DDS”) which outputs an RF voltage; varying the frequency of said RF voltage output by said Direct Digital Synthesiser; determining a first resonant frequency of said RF resonant load comprising said ion-optical component; and determining whether or not the generation of an RF voltage at said first resonant frequency by said Direct Digital Synthesiser would also result in the generation of a spur frequency close to said first resonant