Method of controlling the switched mode ion energy distribution system

What is claimed is: 1. A system comprising: a power supply configured to provide a periodic voltage function to an output configured to couple to a substrate support, the periodic voltage function having pulses and a portion between the pulses; an ion current compensation component configured to provide compensation current, I C , to modify a slope, dV 0 /dt, of the portion between the pulses to form a modified periodic voltage function, which is provided to the output; and a controller in communication with the power supply, the ion current compensation component, and a non-transitory tangible computer readable medium encoded with instructions, and wherein the controller is configured to execute the instructions, the instructions comprising: accessing a memory to obtain an effective internal capacitance, C 1 , of a plasma processing chamber; determining the slope, dV 0 /dt, of the portion between pulses; and adjusting a magnitude of the compensation current, I C , applied to the substrate support until I C = C 1 ⁢ dVo dt . 2. The system of claim 1 , wherein the instructions further include identifying an amplitude of the pulses of the periodic voltage function that, when provided to the substrate support, result in a defined ion energy of ions reaching a surface of a substrate on the substrate support. 3. The system of claim 2 , wherein the instructions further include adjusting an amplitude of the pulses of the periodic voltage function until the defined ion energy of ions reaching the surface of the substrate is achieved. 4. A system comprising: an electrical node configured to electrically couple to a substrate support of a plasma processing chamber; means for storing an effective internal capacitance value, C 1 , of the substrate support; means for providing compensation current, I C , to the electrical node; means for providing a periodic voltage function to the electrical node, the periodic voltage function being modified by the compensation current, I C , to form a modified periodic voltage function at the electrical node, the modified periodic voltage function having pulses and a portion between the pulses; a controller in communication with the means for providing the compensation current, I C , and the means for providing the periodic voltage function, the controller encoded with instructions for: determining a slope, dV 0 /dt, of the portion between the pulses of the modified periodic voltage function; and adjusting a magnitude of the compensation current, I C , applied to the substrate support until I C = C 1 ⁢ dVo dt . 5. The system of claim 4 , wherein the determining includes sampling a voltage of the portion between the pulses of the modified periodic voltage function at two or more times. 6. The system of claim 5 , wherein the determining includes calculating the slope, dV 0 /dt, from the voltage sampled at the two or more times. 7. The system of claim 6 , wherein the determining includes calculating the slope, dV 0 /dt, for two or more cycles of the modified periodic voltage function, where each of the two or more cycles is associated with a different value of the compensation current, I C . 8. The system of claim 5 , wherein the determining includes: sampling a voltage of the portion between the pulses of the modified periodic voltage function during a first cycle and during a second cycle; and calculating the slope, dV0/dt, from at least these two sampled voltages. 9. The system of claim 1 , wherein the instructions further comprise: once I C = C 1 ⁢ dVo dt , further adjusting the magnitude of the compensation current, I C , applied to the substrate support such that I C is not equal to C 1 ⁢ dVo dt in order to widen an ion energy distribution function of ions reaching a surface of the substrate. 10. The system of claim 4 , wherein the instructions further comprise: once I C = C 1 ⁢ dVo dt , further adjusting the magnitude of the compensation current, I C , applied to the substrate support such that I C is not equal to C 1 ⁢ dVo dt in order to widen an ion energy distribution function of ions reaching a surface of the substrate support. 11. The system of claim 1 , wherein the instructions further comprise: calculating a sheath voltage across a plasma sheath of the plasma. 12. The system of claim 4 , wherein the instructions further comprise: calculating a sheath voltage across a plasma sheath of the plasma. 13. The system of claim 1 , wherein the effective internal capacitance value, C 1 , includes capacitances of an electrical path between the output and the substrate support as well as one or more capacitances of the substrate support. 14. The system of claim 4 , wherein the effective internal capacitance value, C 1 , includes capacitances of an electrical path between the output and the substrate support as well as one or more capacitances of the substrate support. 15. The system of claim 1 , wherein the effective internal capacitance value, C 1 , also accounts for a capacitance of a substrate coupled to the substrate support. 16. The system of claim 4 , wherein the effective internal capacitance value, C 1 , also accounts for a capacitance of a substrate coupled to the substrate support. 17. The system of claim 15 , wherein the effective internal capacitance value, C 1 , also accounts for insul