Inverter/power amplifier with capacitive energy transfer and related techniques

The invention claimed is: 1. A circuit for providing dc-to-rf conversion comprising: a first power conversion stage adapted to receive an input voltage and in response thereto to provide an output voltage at an output thereof; and a second power conversion stage adapted to receive a signal from said first power conversion stage and deliver power to an output, wherein: said first power conversion stage comprises a reconfigurable switched capacitor (SC) voltage modulator configured to provide a plurality of voltage conversion ratios from its input to its output and said reconfigurable switched capacitor (SC) voltage modulator having a pair of input terminals adapted to be coupled to an input voltage source and a pair of output terminals adapted to be coupled to input terminals of said second power conversion stage, the reconfigurable switched capacitor voltage modulator comprising a plurality of switches operable to provide four or more steady-state voltage conversion ratios from the input to the output, wherein said plurality of switches are operable to enable the steady-state voltage conversion ratios to be dynamically reconfigured; and said second power conversion stage comprises at least one of: an RF amplifier; or a power supply input of an RF amplifier, wherein said reconfigurable switched-capacitor voltage modulator comprises a first set of capacitors and a second set of capacitors corresponding to energy transfer capacitors and where said first set of capacitors are provided having a capacitance which is relatively small compared with the capacitance of the second set of capacitors such that a load may be used to soft charge and discharge said energy transfer capacitors in whole or in part. 2. The circuit of claim 1 wherein said first power conversion stage comprises a multilevel switched-capacitor circuit coupled to said second stage through an output configuration switch bank. 3. The circuit of claim 1 wherein said first power conversion stage comprises a multilevel switched-capacitor circuit configured to be coupled to at least one input source through an input configuration switch bank. 4. The circuit of claim 1 wherein the one or more switches dynamically control a conversion ratio of the first power conversion stage such that an intermediate voltage can be modulated as a function of any of: (a) an input voltage; (b) a reference voltage; or (c) an rf output amplitude. 5. A switched-mode capacitor voltage modulator circuit comprising: a first stage comprising an energy transfer capacitor and a switch network having at least five switches, said switch network coupled about said single energy transfer capacitor such that said first stage effectively provides one of at least four voltage levels at an output thereof and permits rapid dynamic switching among levels; a second stage having one or more controls and an input coupled to the output of said first stage such that said second stage is adapted to receive each of the four voltage levels; and a feedforward signal coupled between the first stage, the second stage, and a controller, the feedforward signal configured to feedforward a voltage modulator output voltage to the controller, the controller configured to adjust the one or more controls of the second stage to thereby reduce variations in the output of the second stage, wherein said energy transfer capacitor is provided having a capacitance which is relatively small such that a load may be used to soft charge and discharge said energy transfer capacitor in whole or in part. 6. The circuit of claim 5 , wherein the controller is configured to adjust the one or more controls of the second stage, based upon the feedforward signal, to reduce memory effects in the switched-mode capacitor voltage modulator. 7. A system for coupling at least one input source to at least one load, the system comprising: an input configuration switch bank having one or more input ports and one or more output ports, and a plurality of input configuration switches, each of the switches having an input configured to selectively couple to at least one of the at least one input source; a multilevel switched-capacitor voltage circuit providing a plurality of voltage levels having steady-state ratiometric relationships, at least one of said voltage levels coupled to at least some of the one or more output ports of said input configuration switch bank; and an output configuration switch bank having two or more input ports and one or more output ports, with each of the two or more input ports coupled to said voltage levels of said multilevel switched-capacitor voltage circuit and each of the one or more output ports configured to be selectively coupled to at least one of the at least one load, wherein said multilevel switched-capacitor voltage circuit comprises a first set of capacitors and a second set of capacitors corresponding to energy transfer capacitors and where said first set of capacitors are provided having a capacitance which is relatively small compared with the capacitance of the second set of capacitors such that a load may be used to soft charge and discharge said energy transfer capacitors in whole or in part. 8. The system of claim 7 wherein said input configuration switch bank comprises a first set of input configuration switches to provide the input and/or output ports. 9. The system of claim 7 wherein said output configuration switch bank comprises a plurality of output configuration switches. 10. The system of claim 7 wherein said output configuration switch bank comprises a first plurality of switches configured to be selectively coupled to a first one of the at least one load and a second plurality of switches configured to be selectively coupled to a second, different one of the at least one load. 11. The system of claim 7 wherein said system is provided as an Asymmetric Multilevel Backoff (AMBO) system. 12. The system of claim 7 wherein: said multilevel switched-capacitor voltage circuit comprises a plurality of switches operable to provide switched-capacitor voltage conversion yielding four or more steady-state ratiometric relationships among a plurality of voltages V 1 -V 4 ; and said input configuration switch bank comprises a first set of input selector switches and said output configuration switch bank comprises a first set of output selector switches wherein said input selector switches and said output selector switches are operable to enable a steady-state conversion ratio from input voltage V in to a voltage v x supplied to an amplifier to be dynamically reconfigured. 13. The system of claim 12 wherein said system comprises M input selector switches S im and N output selector switches S onx , where M and N are positive integers, and wherein steady-state voltages at the switched-capacitor voltage circuit output v x are selected as a function of configurations of the M input selector switches and the N output selector switches and wherein placing certain ones of input and output selector switches S im and S onx in their ON state results a steady state voltage v x =(N/M) V in . 14. The system of claim 12 wherein a state of output selector switches S o1x -S o4x may be changed to rapidly modulate a voltage provided by the multilevel switched-capacitor voltage circuit to a power amplifier without the inducing significant variations in voltages V 1 -V 4 such that rapid discrete drain modulation of the power amplifier is provided in response to rapid changes in a desired output amplitude. 15. The system of claim 12 wherein said input selector switches S i1 -S i4 are configured such that chan