Power converter with a dynamically configurable controller and output filter

What is claimed is: 1. A system, comprising: an output filter capacitor with a first terminal directly coupled to a first output terminal of a power converter; an output filter inductor, directly coupled between a second terminal of said output filter capacitor and a second output terminal of said power converter, selected to stabilize a feedback control loop of said power converter in combination with said output filter capacitor; another output filter capacitor directly coupled to said first and second output terminals, and coupled directly in parallel to said output filter capacitor and said output filter inductor, wherein said first and second output terminals of said power converter are load terminals capable of sustaining a direct current (“dc”) output characteristic of said power converter; and a controller configured to control a duty cycle of at least one power switch to regulate said dc output characteristic of said power converter, wherein the at least one power switch is coupled to the first output terminal of said power converter, wherein said controller includes: an error amplifier with first and second input terminals, and a switch configured to provide one of said dc output characteristic and a reference voltage of said power converter to said first and second input terminals as a function of a power conversion mode of said power converter, wherein said dc output characteristic is an output voltage and said switch is responsive to a power conversion mode control signal produced by a comparator in accordance with an input voltage of said power converter and said output voltage of said power converter. 2. The system as recited in claim 1 wherein said power converter is operable in different power conversion modes of operation. 3. The system as recited in claim 1 wherein said another output filter capacitor is configured to provide a low impedance bypass for high frequency ripple components at said first and second output terminals of said power converter. 4. The system as recited in claim 1 wherein at least one of said output filter capacitor and said another output filter capacitor is a ceramic capacitor. 5. The system as recited in claim 1 further comprising another filter inductor coupled to said first terminal of said output filter capacitor. 6. The system as recited in claim 1 wherein said output filter inductor is configured to shift down a self resonant frequency of said output filter capacitor. 7. A power converter, comprising: a power train, including: at least one power switch coupled to a first output terminal of said power converter, and an output filter, including: an output filter capacitor with a first terminal directly coupled to said first output terminal of said power converter, an output filter inductor, directly coupled between a second terminal of said output filter capacitor and a second output terminal of said power converter, selected to stabilize a feedback control loop of said power converter in combination with said output filter capacitor, and another output filter capacitor directly coupled to said first and second output terminals, and coupled directly in parallel to said output filter capacitor and said output filter inductor, wherein said first and second output terminals of said power converter are load terminals capable of sustaining a direct current (“dc”) output characteristic of said power converter; and a controller configured to control a duty cycle of said at least one power switch to regulate said dc output characteristic of said power converter, wherein said controller includes: an error amplifier with first and second input terminals, and a switch configured to provide one of said dc output characteristic and a reference voltage of said power converter to said first and second input terminals as a function of a power conversion mode of said power converter, wherein said dc output characteristic is an output voltage and said switch is responsive to a power conversion mode control signal produced by a comparator in accordance with an input voltage of said power converter and said output voltage of said power converter. 8. The power converter as recited in claim 7 wherein said power converter is operable in different power conversion modes of operation. 9. The power converter as recited in claim 7 wherein said another output filter capacitor is configured to provide a low impedance bypass for high frequency ripple components at said first and second output terminals of said power converter. 10. The power converter as recited in claim 7 wherein at least one of said output filter capacitor and said another output filter capacitor is a ceramic capacitor. 11. The power converter as recited in claim 7 wherein said output filter further comprises another filter inductor coupled to said first terminal of said output filter capacitor. 12. The power converter as recited in claim 7 wherein said output filter inductor is configured to shift down a self resonant frequency of said output filter capacitor. 13. The power converter as recited in Claim 7 wherein said error amplifier includes an operational amplifier including said first and second input terminals and a feedback path including at least one of a resistor and a capacitor between said first and second input terminals and an output terminal thereof. 14. A method of operating a power converter, comprising: providing a power train, including: at least one power switch coupled to a first output terminal of said power converter, and an output filter, including: an output filter capacitor with a first terminal directly coupled to said first output terminal of said power converter, an output filter inductor, directly coupled between a second terminal of said output filter capacitor and a second output terminal of said power converter, selected to stabilize a feedback control loop of said power converter in combination with said output filter capacitor, and another output filter capacitor directly coupled to said first and second output terminals, and coupled directly in parallel to said output filter capacitor and said output filter inductor, wherein said first and second output terminals of said power converter are load terminals capable of sustaining a direct current (“dc”) output characteristic of said power converter; and controlling a duty cycle of said at least one power switch to regulate said dc output characteristic of said power converter, wherein controlling the duty cycle to regulate said dc output characteristic comprises: providing one of said dc output characteristic and a reference voltage of said power converter to first and second input terminals of an error amplifier as a function of a power conversion mode of said power converter via a switch, wherein said dc output characteristic is an output voltage and said switch is responsive to a power conversion mode control signal produced by a comparator in accordance with an input voltage of said power converter and said output voltage of said power converter. 15. The method as recited in claim 14 further comprising providing a low impedance bypass for high frequency ripple components at said first and second output terminals of said power converter with said another output filter capacitor. 16. The method as recited in claim 14 wherein at least one of said output filter capacitor and said another output filter capacitor is a ceramic capacitor. 17. The method as recited in claim 14 wherein said output filter inductor shifts down a self resonant frequency of said output filter capacito