Automated method and apparatus for testing a power converter

What is claimed is: 1. A method for testing operability of a power converter with an existing power conversion assembly of a renewable energy system, the power converter having a bridge circuit and a power filter, the method comprising: transferring, by the existing power conversion assembly, a first pulse of energy from the existing power conversion assembly to the power filter through one or more first cells within the bridge circuit, wherein the first cells of the bridge circuit comprise a first switching element and a first diode, and wherein the first pulse of energy is transferred to an inductive element of the power filter through the first switching element of the bridge circuit; determining, by a converter controller, a first current-voltage feedback associated with the first pulse of energy; transferring, by the existing power conversion assembly, a second pulse of energy from the power filter to the existing power conversion assembly through one or more second cells within the bridge circuit such that at least a portion of the first pulse of energy within the power filter is included in the second pulse of energy, wherein the second cells of the bridge circuit comprise a second switching element and a second diode; determining, by the converter controller, a second current-voltage feedback associated with the second pulse of energy; and, comparing, by the converter controller, the first and second current-voltage feedbacks with tolerances of the power converter to ensure that the power converter is operating properly. 2. The method of claim 1 , wherein the first and second cells comprise any one of or combination of the following: a diode, an insulated-gate bipolar transistor (IGBT), a relay, a silicon-controlled rectifier (SCR), a thyristor, a triode for alternating current (TRIAC), a metal-oxide-semiconductor field effect transistor (MOSFET), a junction gate field-effect transistor (JFET), a bipolar junction transistor (BJT), an integrated-gate commutated thyristor (IGCT), a gate turn-off thyristor (GTO), a MOS-controlled thyristor (MCT), or a static induction transistor and thyristor (SIT). 3. The method of claim 1 , further comprising implementing a first non-gating interval such that at least a portion of the first pulse of energy is directed from the inductive element of the power filter into a capacitive element of the power filter through the first diode of the bridge circuit. 4. The method of claim 3 , wherein determining the first current-voltage feedback associated with the first pulse of energy further comprises: determining a first flux measurement of the inductive element of the power filter based on a developed current of the inductive element, a steady-state voltage of the power filter, and a first charge for the first pulse of energy; determining a first inductance measurement of the power filter based on the first flux measurement and the developed current of the inductive element; and, determining a first capacitance measurement of the power filter based on the first charge and the steady-state voltage of the power filter. 5. The method of claim 4 , wherein the second pulse of energy includes at least a portion of the first pulse of energy within the power filter such that during transferring, the second pulse of energy including at least a portion of the first energy moves from the capacitive element of the power filter to the inductive element through the second switching element within the bridge circuit. 6. The method of claim 5 , further comprising implementing a second non-gating interval such that the second pulse of energy including at least a portion of the first pulse of energy within the inductive element moves to the existing power conversion assembly through the second diode within the bridge circuit. 7. The method of claim 6 , wherein determining the second current-voltage feedback associated with the second pulse of energy further comprises: determining a second flux measurement of the inductive element of the power filter based on a developed current of the inductive element, a steady-state voltage of the power filter, and a second charge for the second pulse of energy; determining a second inductance measurement of the power filter based on the second flux measurement and the developed current of the inductive element; and, determining a second capacitance measurement of the power filter based on the second charge and the voltage of the power filter. 8. The method of claim 7 , further comprising comparing the first and second inductance measurements and the first and second capacitance measurements of the power filter with tolerances of the power converter to ensure that the power converter is performing within the tolerances. 9. The method of claim 1 , wherein comparing the first current-voltage feedback and the second current-voltage feedback with tolerances of the power converter to ensure that the power converter is operating properly further comprises: comparing the first and second current-voltage feedbacks with tolerances of the power filter; and based on the comparison, determining whether the bridge circuit is operating properly. 10. A method for coupling one or more energy storage devices to an existing power conversion assembly of a renewable energy system via a power converter, the power converter having a bridge circuit and a power filter, the method comprising: implementing, by a converter controller, a test sequence for testing operability of the power converter with the existing power conversion assembly, wherein the test sequence comprises: transferring, by the existing power conversion assembly, a first pulse of energy from the existing power conversion assembly to the power filter through one or more first cells within the bridge circuit, the first cells of the bridge circuit comprising a first switching element and a first diode, the first pulse of energy being transferred to an inductive element of the power filter through the first switching element, determining, by the converter controller, a first current-voltage feedback associated with the first pulse of energy, transferring, by the existing power conversion assembly, a second pulse of energy from the power filter to the existing power conversion assembly through one or more second cells within the bridge circuit such that at least a portion of the first pulse of energy within the power filter is included in the second pulse of energy, the one or more second cells comprising a second switching element and a second diode, determining, by the converter controller, a second current-voltage feedback associated with the second pulse of energy, comparing, by the converter controller, the first and second current-voltage feedbacks with tolerances of the power converter to ensure that the power converter is operating properly, and electrically coupling one or more energy storage devices with the power converter when the first and second current-voltage feedbacks are within the tolerances. 11. The method of claim 10 , wherein the first cells of the bridge circuit comprise a first switching element and a first diode, and wherein the second cells of the bridge circuit comprise a second switching element and a second diode. 12. An apparatus for testing operability of a power converter with an existing power conversion assembly of a renewable energy system, the apparatus comprising: the power converter electrically coupled with the existing power conversion assembly, the power converter comprising a bridge circuit and a power filter, the bridge circuit comprising one or more first cells and one or more second cells; and, a converter controller communica