Electric power conversion apparatus having single-phase and multi-phase operation modes

What is claimed is: 1. An apparatus for converting a first AC signal to a DC signal, comprising: an electronic controller including a processor and a memory; and first, second, and third single-phase AC/DC conversion module each connected to and controlled by said controller, and wherein respective output signals from said conversion modules are electrically joined at an output node, each conversion module comprising: (i) an indirect matrix converter having an input interface configured to receive said first AC signal and an output interface configured to produce a second AC signal; (ii) a transformer having a primary winding and an electrically isolated and magnetically coupled secondary winding; (iii) a coupling inductor in series between said output interface of said indirect matrix converter and said primary winding; and (iv) an H-bridge switching arrangement connected to said secondary winding and configured to produce on said output node a respective output signal having a DC component and at least one AC component; wherein in a first mode of operation where said first AC signal comprises a multi-phase AC signal, said controller is configured to enable operation of said first, second, and third AC/DC conversion modules wherein respective AC components of said respective output signals tend to cancel each other out; and wherein in a second mode of operation where said first AC signal comprises a single-phase AC signal, said controller enables operation of said first and second AC/DC conversion modules and disables operation of said indirect matrix converter of said third AC/DC conversion module, said controller being configured to actuate said H-bridge switching arrangement of said third AC/DC conversion module having an active filter coupled thereto, according to a filtering strategy to reduce said AC component of said output signals of said first and second AC/DC conversion modules. 2. The apparatus of claim 1 wherein said active filter is selectively removable. 3. The apparatus of claim 1 wherein said active filter comprises an inductor-capacitor (LC) tank circuit. 4. The apparatus of claim 3 further comprising a filter housing in which said tank circuit is disposed and a main housing in which at least said first, second, and third AC/DC conversion modules and said controller are disposed, said filter housing including a first electrical coupling feature and said main housing including a second electrical coupling feature complementary to said first coupling feature, wherein said first coupling feature cooperates with said second coupling feature to electrically couple said LC tank circuit between said H-bridge switching arrangement and an output ground node. 5. The apparatus of claim 4 wherein said first feature is one of male and female electrical terminals and said second feature is the other one of said male and female electrical terminals. 6. The apparatus of claim 1 wherein said electronic controller includes main control logic stored in said memory, said main control logic when executed by said processor is configured, when in said first mode of operation, to control operation of said indirect matrix converter and said H-bridge switching arrangement of said first, second, and third AC/DC conversion module to achieve power factor correction (PFC) and zero voltage switching (ZVS). 7. The apparatus of claim 1 wherein said indirect matrix converter comprises a rectifier responsive to said first AC signal configured to produce a first direct current (DC) signal, said rectifier including a plurality of rectifier switches arranged in a full bridge arrangement; and wherein said electronic controller includes rectifier logic stored in said memory, said rectifier logic when executed by said processor is configured to generate a first set of switch control signals corresponding to gate drive signals for said plurality of rectifier switches. 8. The apparatus of claim 7 further comprising a grid voltage sensor in sensing relation to an AC power source outputting a grid power signal and configured to generate a grid voltage signal indicate of said grid voltage. 9. The apparatus of claim 8 wherein said rectifier logic is responsive to said grid voltage signal in generating said first set of switch control signals. 10. The apparatus of claim 7 wherein said first AC signal has a first frequency and said indirect matrix converter further comprises a DC to AC converter coupled to said rectifier and configured to convert said first DC signal into said second AC signal, said second AC signal having a second frequency that is greater than said first frequency, said DC to AC converter including a plurality of DC to AC switches, wherein said main control logic when executed by said processor of said electronic controller is configured to generate a second set of switch control signals corresponding to gate drive signals for said DC to AC switches. 11. The apparatus of claim 10 wherein said H-bridge switching arrangement includes a plurality of H-bridge switches arranged in an H-bridge configuration, said main control logic when executed by said processor of said electronic controller is configured to generate a third set of switch control signals corresponding to gate drive signals for said H-bridge switches. 12. The apparatus of claim 11 wherein said main control logic includes power factor correction (PFC) logic which, when executed by said processor of said electronic controller, is configured to generate said second and third sets of switch control signals to increase a power factor associated with power drawn from said AC source towards one. 13. The apparatus of claim 12 wherein said PFC logic is configured to vary a phase difference in gate drive signals associated with respective H-bridge switches. 14. The apparatus of claim 1 wherein current through said coupling inductor is bi-directional. 15. The apparatus of claim 1 further comprising an output capacitor coupled between said output node and a ground node. 16. The apparatus of claim 1 wherein said electronic controller includes main control logic stored in said memory, said main control logic when executed by said processor is configured to determine when said first input AC signal is said multi-phase signal and enter said first mode of operation, said main control logic being configured, when in said first mode of operation, to control operation of said indirect matrix converter and said H-bridge switching arrangement of said first, second, and third AC/DC conversion module and wherein said H-bridge switching arrangement includes a plurality of H-bridge switches arranged in an H-bridge configuration, and wherein said main control logic is further configured to generate a third set of switch control signals corresponding to gate drive signals for said H-bridge switches. 17. The apparatus of claim 1 wherein said electronic controller includes main control logic stored in said memory, said main control logic when executed by said processor is configured to determine when said first input AC signal is said single-phase signal and enter said second mode of operation, said main control logic being configured, when in said second mode of operation: (i) to enable operation of said first and second AC/DC conversion modules; and (ii) to disable operation of said indirect matrix converter and to control operation of said H-bridge switching arrangements of said third AC/DC conversion module. 18. The apparatus of claim 17 wherein said H-bridge switching arrangement includes a plurality of H-bridge switch