Apparatus and method for magnetic control of an electron beam

What is claimed is: 1. A control circuit for an electron beam manipulation coil for an x-ray generation system comprising: a first low voltage source; a second low voltage source; a first switching device coupled in series with the first low voltage source and configured to create a first current path with the first low voltage source when in a closed position; a second switching device coupled in series with the second low voltage source and configured to create a second current path with the second low voltage source when in a closed position; a capacitor coupled in parallel with an electron beam manipulation coil and positioned along the first and second current paths; and a current source circuit electrically coupled to the electron beam manipulation coil and constructed to generate an offset current in the first and second current paths. 2. The control circuit of claim 1 wherein the current source circuit comprises a bidirectional circuit configurable to inject one of a positive current offset and a negative current offset in the first and second current paths. 3. The control circuit of claim 1 wherein the current source circuit comprises a unidirectional circuit configured to inject one of a positive current offset and a negative current offset in the first and second current paths. 4. The control circuit of claim 3 wherein the current source circuit comprises: a first offset switch; an inductor coupled in series with the first offset switch; a current monitoring device electrically coupled to the inductor; and a control electrically coupled to the current monitoring device, the control configured to monitor a current flow in the current source circuit and transmit switching signals to the first offset switch based on the monitored current. 5. The control circuit of claim 4 wherein the control is configured to close the first offset switch when the monitored current flow is less than a threshold. 6. The control circuit of claim 4 wherein the control is configured to open the first offset switch after a predetermined time period. 7. The control circuit of claim 4 wherein the control is configured to open the first offset switch when the monitored current flow is greater than a threshold. 8. The control circuit of claim 4 wherein the current source circuit further comprises an independent power supply configured to charge the inductor. 9. The control circuit of claim 4 wherein the current source circuit further comprises a second offset switch; and wherein the control is configured to: transmit switching signals to the first offset switch to inject the positive current offset; and transmit switching signals to the second offset switch to inject the negative current offset. 10. The control circuit of claim 1 wherein the first and second low voltage sources are constructed to supply a voltage of approximately R*I volts, where R represents an overall parasitic resistance of the control circuit, and I represents a desired steady state current supplied to the electron beam manipulation coil. 11. The control circuit of claim 1 wherein the first low voltage source, the capacitor, and the first switching device are arranged to generate a current flow having a first polarity across the electron beam manipulation coil; and wherein the second low voltage source, the capacitor, and the second switching device are arranged to generate a current flow having a second polarity, opposite the first polarity, across the electron beam manipulation coil. 12. A method for driving an electron beam manipulation coil comprising the steps of: (A) closing a first switching device to cause a first current at a first polarity to flow along a first current path, through a resonance circuit, and through a first energy storage device, the resonance circuit comprising an electron beam manipulation coil and a resonance capacitor; (B) opening the first switching device after closing the first switching device to initiate a first resonance cycle in the resonance circuit; (C) closing a second switching device after the first resonance cycle has been initiated to cause a second current at a second polarity to flow along a second current path, through the resonance circuit, and through a second energy storage device; and (D) controlling switching of a current source circuit to cause a shift in the first current and a shift in the second current such that an average of the shifted first current and the shifted second current is non-zero. 13. The method of claim 12 further comprising the steps of: (E) opening the second switching device after closing the second switching device to initiate a second resonance cycle in the resonance circuit; (F) closing the first switching device after the second resonance cycle has been initiated to cause the first current at the first polarity to flow along the first current path, through the resonance circuit, and through the first energy storage device; and (G) repeating steps (B)-(F). 14. The method of claim 12 further comprising controlling switching of the current source to maintain a steady-state shift in the first and second current. 15. The method of claim 14 further comprising: monitoring a current flow in the current source circuit; and closing a switch in the current source circuit to recharge the current source circuit when the monitored current flow is below a threshold. 16. A computed tomography (CT) system comprising: a rotatable gantry having an opening therein for receiving an object to be scanned; a table positioned within the opening of the rotatable gantry and moveable through the opening; a detector; an x-ray tube coupled to the rotatable gantry and configured to emit a stream of electrons toward a target, the target positioned to direct a beam of x-rays toward the detector; a deflection coil mounted on the x-ray tube and positioned to deflect the stream of electrons; a control circuit electrically coupled to the deflection coil, the control circuit comprising: a first low voltage source sized to supply steady-state current at a first polarity; a second low voltage source sized to supply steady-state current at a second polarity, opposite the first polarity; a first switch coupled to the first low voltage source and configured to create a first current path with the first low voltage source when the first switch is closed; a second switch coupled to the second low voltage source and configured to create a second current path with the second low voltage source when the second switch is closed; a resonance capacitor coupled in parallel with the deflection coil and positioned along the first and second current paths; and a current shifting circuit electrically coupled to the deflection coil and configured to inject a current offset in the first and second current paths; and a controller electrically coupled to the control circuit and programmed to control switching of the first and second switches. 17. The CT system of claim 16 wherein the current shifting circuit comprises: a first offset switch; a first inductor coupled in series with the first offset switch; a first current probe electrically coupled to the first inductor; a control electrically coupled to the first current probe to sense a current flow in the current shifting circuit; and wherein the control is configured to transmit switching signals to the first offset switch based on the sensed current flow. 18. The CT system of claim 17 wherein the current shifting circuit further comprises: a second offset