Resonant switching regulator with continuous current

What is claimed is: 1. A power conversion circuit comprising: a plurality of serially connected solid-state switches coupled between an input terminal and a ground and including an output terminal; an inductor coupled between the output terminal and a load; a capacitor coupled in parallel with two of the serially connected solid-state switches; and a controller configured to control the plurality of solid-state switches to generate a unidirectional current in the inductor by repetitively (1) charging the capacitor causing a temporary increase in the unidirectional current in the inductor and before the unidirectional current stops, (2) discharging the capacitor causing a temporary increase in the unidirectional current in the inductor and before the unidirectional current stops, repeating (1). 2. The power conversion circuit of claim 1 further comprising generating a first preflux condition in the inductor before (1). 3. The power conversion circuit of claim 1 further comprising generating a second preflux condition in the inductor before (2). 4. The power conversion circuit of claim 3 wherein during the second preflux condition at least two of the plurality of solid-state switches are in an on state. 5. The power conversion circuit of claim 1 wherein the load comprises central processing unit circuitry. 6. The power conversion circuit of claim 1 wherein the load comprises a processor. 7. The power conversion circuit of claim 1 wherein the load, the plurality of serially connected solid-state switches and the controller are disposed on a unitary semiconductor substrate. 8. The power conversion circuit of claim 1 wherein when repetitively performing (1) and (2) a continuous current flows through the inductor. 9. A unitary integrated circuit comprising: a unitary semiconductor substrate; a central processing unit circuit disposed on the unitary semiconductor substrate; a power regulator circuit configured to supply power to the central processing unit circuit and including: a plurality of serially connected solid-state switches disposed on the unitary semiconductor substrate, the plurality of serially connected solid-state switches coupled between an input terminal and a ground and including an output terminal; an inductor coupled between the output terminal and the central processing unit circuit; a capacitor coupled in parallel with two of the serially connected solid-state switches; and a controller disposed on the unitary semiconductor substrate and configured to control the plurality of solid-state switches to generate a current in the inductor by repetitively (1) charging the capacitor causing a temporary increase in the current in the inductor and before the current stops, (2) discharging the capacitor causing a temporary increase in the current in the inductor and before the current stops, repeating (1). 10. The unitary integrated circuit of claim 9 further comprising generating a first preflux condition in the inductor before (1). 11. The unitary integrated circuit of claim 9 further comprising generating a second preflux condition in the inductor before (2). 12. The unitary integrated circuit of claim 11 wherein during the second preflux condition at least two of the plurality of solid-state switches are in an on state. 13. The unitary integrated circuit of claim 9 wherein when repetitively performing (1) and (2) a continuous current flows through the inductor. 14. The unitary integrated circuit of claim 9 wherein in response to a voltage at the central processing unit circuit being above a predetermined threshold voltage the controller allows the current in the inductor to stop in (1). 15. A method of operating a power conversion circuit to deliver power to a load, the method comprising: supplying power to a first terminal of the power conversion circuit with a power supply, the power conversion circuit comprising: a plurality of serially connected solid-state switches coupled between the first terminal and a ground; an output terminal positioned between two of the plurality of serially connected solid-state switches; an inductor coupled between the output terminal and the load; a capacitor coupled in parallel with two of the serially connected solid-state switches; and a controller coupled to each of the plurality of solid-state switches; operating the plurality of solid-state switches to generate a unidirectional current in the inductor by repetitively (1) charging the capacitor causing a temporary increase in the unidirectional current in the inductor and before the unidirectional current stops, (2) discharging the capacitor causing a temporary increase in the unidirectional current in the inductor and before the unidirectional current stops, repeating (1). 16. The method of claim 15 further comprising generating a first preflux condition in the inductor before (1). 17. The method of claim 15 further comprising generating a second preflux condition in the inductor before (2). 18. The method of claim 15 wherein the load, the plurality of serially connected solid-state switches and the controller are disposed on a unitary semiconductor substrate. 19. The power conversion circuit of claim 15 wherein the load comprises a processor. 20. The power conversion circuit of claim 15 wherein when repetitively performing (1) and (2) a continuous current flows through the inductor.