Multi-phase AC/DC converter

What is claimed is: 1. An AC/DC converter, comprising: a plurality of internal terminals including positive, negative, and neutral internal terminals; an input stage connected to the positive, negative, and neutral internal terminals and having at least three input terminals for connecting to a three-phase AC power source; a switching stage having a plurality of modules, each module having a plurality of switches and a capacitor, at least one of the modules connected to the positive internal terminal, at least one of the modules connected to the negative internal terminal, and at least two of the modules connected to the neutral internal terminal; an output stage connected to the positive internal terminal and configured to provide DC voltage to output terminals for connecting to a load; and a controller having a plurality of control signal outputs connected to the plurality of switches and configured to generate control signals for said switches; wherein: each module of the plurality of modules has two switches, and the two switches and the capacitor are connected serially in a loop, the module connected to the positive terminal is connected to the positive terminal by a node in the loop connecting the two switches of said module, the module connected to the negative terminal is connected to the negative terminal by a node in the loop connecting one of the switches to the capacitor of said module, a first of the at least two modules connected to the neutral internal terminal is connected to the neutral terminal by a node in the loop connecting one of the switches to the capacitor of said module, and a second of the at least two modules connected to the neutral internal terminal is connected to the neutral terminal by a node in the loop connecting the two switches of said module. 2. The converter of claim 1 , wherein the switching stage has two modules, a first module of the two modules is both the module connected to the positive terminal and the first of the at least two modules connected to the neutral internal terminal, and a second module of the two modules is both the module connected to the negative terminal and the second of the at least two modules connected to the neutral internal terminal. 3. The converter of claim 1 , wherein the switching stage has (n+m) modules (n and m being positive integers greater than 1) divided into a first n modules and a second m modules, the first n modules include a 1 st module of the first n modules which is the module connected to the positive terminal, an n-th module of the first n modules which is the first of the at least two modules connected to the neutral internal terminal, and wherein each i-th (1≤i≤n−1) module is connected by a node in the loop connecting one of the switches to the capacitor of said i-th module to a respective (i+1)-th module at a node in the loop connecting the two switches of said (i+1)-th module, and the second m modules include a Pt module of the second m modules which is the second of the at least two modules connected to the neutral internal terminal, an m-th module of the second m modules which is the module connected to the negative terminal, and wherein each j-th (1≤j≤(m−1)) module is connected by a node in the loop connecting one of the switches to the capacitor of said jth module to a respective (j+1)-th module at a node in the loop connecting the two switches of said (j+1)-th module. 4. The converter of claim 1 , wherein the switching stage has (2n+2m) modules, where n and m are positive integers, for each module the plurality of switches comprises two switches, and the two switches and the capacitor of each module are connected serially in a loop, the module connected to the positive terminal is connected to the positive terminal by a node in the loop connecting the two switches of said module, the module connected to the negative terminal is connected to the negative terminal by a node in the loop connecting the two switches of said module, a first of the at least two modules connected to the neutral internal terminal is connected to the neutral terminal by a node in the loop connecting the two switches of said module, and a second of the at least two modules connected to the neutral internal terminal is connected to the neutral terminal by a node in the loop connecting the two switches of said module. 5. The converter of claim 4 , wherein each of the 2n modules is paired with another of the 2n modules and each of the 2m modules is paired with another of the 2m modules, each pair having a common node that for both modules in said pair connects the capacitor of the respective module to one of the switches of the respective module. 6. The converter of claim 5 , wherein n=1, m=1, the module connected to the positive terminal is paired with the first of the at least two modules connected to the neutral internal terminal, and the module connected to the negative terminal is paired with the second of the at least two modules connected to the neutral internal terminal. 7. The converter of claim 1 , wherein the output stage comprises a plurality of capacitors connected in series between the positive and negative internal terminals, a transformer having a first winding and a second winding, the first winding having a first terminal and a second terminal connected to the neutral terminal; a resonant inductor and resonant capacitor connected in series between a midpoint node in the series connected plurality of capacitors and the first terminal of the first winding of the transformer; and a full-wave diode bridge connected to the second winding of the transformer and the output terminals. 8. The converter of claim 1 , wherein the output stage is further connected to the negative and neutral terminals. 9. The converter of claim 1 , wherein the output stage is a first output stage, the output terminals are first output terminals, and the load is a first load, the converter further comprising a second output stage connected to the negative internal terminal and configured to provide DC voltage to second output terminals for connecting to a second load. 10. The converter of claim 1 , wherein the output stage is a first output stage, the output terminals are first output terminals, and the positive and negative internal terminals are a first positive and first negative internal terminals, respectively, the converter further comprising: a second positive internal terminal and a second negative internal terminal, wherein the input stage is further connected to said second positive and second negative internal terminals; a second switching stage having a second plurality of modules serially connected between the second positive and second negative internal terminals; and a second output stage connected to the first and second negative internal terminals and configured to provide DC voltage to second output terminals, wherein the first output stage is further connected to the second positive internal terminal. 11. An AC/DC converter comprising: input terminals for connecting to a three-phase input voltage source; an input filter stage coupled to the input terminals and connected to a positive node, a negative node and a neutral node; a switching stage having n half bridge modules, where n is a positive integer greater than 1, the half bridge modules connected in series between the positive node and the negative node, and having the neutral node connected to a series connection between the j-th and (j+1)-th half bridge modules in the series (where 1≤j≤n−1); an output stage connected to the positive node and configured to provide DC voltage to output terminals for connecting to a load; and