Oscillator generators and methods of using them

The invention claimed is: 1. A generator configured to sustain an inductively coupled plasma in a torch body, the generator comprising a processor and an oscillation circuit electrically coupled to the processor, the oscillation circuit configured to electrically couple to an induction device and provide power to the induction device in an oscillation mode to sustain the inductively coupled plasma in the torch body, the circuit configured to provide harmonic emission control during sustaining of the inductively coupled plasma in the torch body in the oscillation mode of the generator. 2. The generator of claim 1 , in which the circuit comprises a first transistor configured to electrically couple to the induction device. 3. The generator of claim 2 , in which the circuit further comprises a first driver electrically coupled to the first transistor and configured to electrically couple to the induction device. 4. The generator of claim 3 , in which the first driver is configured to electrically couple to the induction device through a first low pass filter. 5. The generator of claim 4 , in which the circuit further comprises a second driver electrically coupled to the second transistor and configured to electrically couple to the induction device. 6. The generator of claim 5 , in which the second driver is configured to electrically couple to the induction device through a second low pass filter. 7. The generator of claim 6 , in which each of the first low pass filter and the second low pass filter is configured to filter a feedback signal provided to the first power transistor and the second power transistor. 8. The generator of claim 7 , in which each of the first low pass filter and the second low pass filter comprise a high order ceramic low-pass filter. 9. The generator of claim 8 , in which the high order ceramic low pass filter is configured to provide at least a 20 dB cut off at 200 MHz or higher frequencies. 10. The generator of claim 1 , in which the circuit is configured to provide impedance matching within about three RF cycles. 11. The generator of claim 1 , further comprising a detector electrically coupled to the processor and configured to determine when the plasma is ignited. 12. The generator of claim 11 , in which the processor is configured to disable the oscillation circuit if the plasma is extinguished. 13. The generator of claim 11 , further comprising a signal converter between the processor and the detector. 14. The generator of claim 1 , in which the oscillation circuit is configured to electrically couple to an induction device that comprises an induction coil or a plate electrode. 15. The generator of claim 2 , in which the oscillation circuit is configured to divide power evenly to the first transistor and the second transistor. 16. The generator of claim 15 , in which the oscillation circuit is configured to cross couple feedback signals from the induction device to the first transistor and the second transistor to divide the power evenly. 17. The generator of claim 16 , in which the oscillation circuit comprises a first feedback resistor electrically coupled to the first transistor. 18. The generator of claim 17 , in which the oscillation circuit comprises a second feedback resistor electrically coupled to the second transistor. 19. The generator of claim 18 , in which the oscillation circuit comprises a first DC block capacitor electrically coupled to the first transistor. 20. The generator of claim 19 , in which the oscillation circuit comprises a second DC block capacitor electrically coupled to the second transistor.