Systems and Methods For Reducing Circulating Current and Phase to Phase Imbalance In A Parallel Modular Converter System

What is claimed is: 1 . A system for powering a plurality of electrical loads, the system comprising: a first parallel modular converter module, with an input and an output, to provide a first alternating current (AC) output; a second parallel modular converter module, with an input and an output, to provide a second AC output; and a load balancer connected to the input and the output of the first parallel modular converter module and the second parallel modular converter module, wherein the load balancer compares the output from the first parallel modular converter module and the second parallel modular converter module, and wherein the load balancer modifies the input to the first parallel modular converter module to equalize the output of the first parallel modular converter module with the output of the second parallel modular converter module. 2 . The system of claim 1 , further comprising: a third parallel modular converter module, with an input and an output, to provide a third alternating current (AC) output, wherein the load balancer compares an output current of the output from the first parallel modular converter module, the second parallel modular converter module, and the third parallel modular converter module, and wherein the load balancer modifies the input for one or more of the first parallel modular converter module, the second parallel modular converter module, and the third parallel modular converter module such that the output current of the first parallel modular converter module, the second parallel modular converter module, and the third parallel modular converter module are substantially balanced. 3 . The system of claim 1 , wherein the load balancer comprises a proportional-integral-derivative (PID) controller. 4 . The system of claim 3 , wherein an error for the PID controller comprises a difference between an output current from the first parallel modular converter module and the second parallel modular converter module, and wherein the PID controller modifies the input to the first parallel modular converter module, the second parallel modular converter module, or both to reduce the error. 5 . A parallel module converter comprising: a first parallel modular converter module to provide a first alternating current (AC) output and connected to a module communications bus; a second parallel modular converter module to provide a second AC output and connected to the module communications bus; a master logic controller to assign a first load to one or more of the first parallel modular converter module and the second parallel modular converter module, the module communications bus connecting the first parallel modular converter module and the second parallel modular converter module; a master communications controller connected to the module communications bus and the master logic controller to route messages therebetween; and a load balancer connected to an input and an output of both the first parallel modular converter module and the second parallel modular converter module. 6 . The parallel module converter of claim 5 , wherein the master logic controller places the first parallel modular converter module and the second parallel modular converter module in parallel using a power switching network and assigns the first load to the first parallel modular converter module and the second parallel modular converter module; and wherein the load balancer modifies the input to the first parallel modular converter module to equalize the output of the first parallel modular converter module with the output of the second parallel modular converter module. 7 . The parallel module converter of claim 6 , further comprising: a third parallel modular converter module to provide a third AC output signal and connected to the module communications bus, wherein the master logic controller places the first parallel modular converter module, the second parallel modular converter module, and the third parallel modular converter module in parallel using the power switching network and assigns the first load to the first parallel modular converter module, the second parallel modular converter module, and the third parallel modular converter module, and wherein the load balancer modifies the input to one or more of the first parallel modular converter module, the second parallel modular converter module, and the third parallel modular converter module to equalize the output of the first parallel modular converter module, the second parallel modular converter module, and the third parallel modular converter module. 8 . The parallel module converter of claim 7 , wherein the load balancer modifies a motor control algorithm for one or more of the first parallel modular converter module, the second parallel modular converter module, and the third parallel modular converter module such that an output current of the first parallel modular converter module, the second parallel modular converter module, and the third parallel modular converter module are substantially balanced. 9 . The parallel module converter of claim 8 , wherein the motor control algorithm comprises a field oriented control algorithm and the load balancer modifies a pulse width modulation (PWM) signal for one or more of the first parallel modular converter module, the second parallel modular converter module, and the third parallel modular converter module. 10 . The parallel module converter of claim 5 , further comprising: a motor control system for providing one or more motor control algorithms to the first parallel modular converter module and the second parallel modular converter module; and a control switching network for connecting the one or more motor control algorithms to the first parallel modular converter module and the second parallel modular converter module, wherein the input for the first parallel modular converter module and the second parallel modular converter module is the one or more motor control algorithms, and wherein the output for the first parallel modular converter module and the second parallel modular converter module is one or more output currents. 11 . A method for balancing outputs between a plurality of parallel modular converter modules, the method comprising: receiving a request to power a first load from a vehicle controller at a system controller; calculating a number of parallel modular converter modules required to power the first load with a load balancer; placing the calculated parallel modular converter modules required to power the first load in parallel with a master logic controller; sensing an output from each of the calculated parallel modular converter modules with the load balancer; and modifying an input signal to one or more of the calculated parallel modular converter modules with the load balancer such that the output of each of the calculated parallel modular converter modules is equal. 12 . The method of claim 11 , further comprising: calculating an ideal load for each of the calculated parallel modular converter modules with the load balancer; and modifying an input motor signal to one or more of the calculated parallel modular converter modules such that the output of each of the calculated parallel modular converter modules is substantially equal to the calculated ideal load. 13 . The method of claim 12 , wherein modifying the input signal comprises modifying a motor control algorithm to one or more of the calculated parallel modular converter modules such that output currents for each of the calculated parallel modular converter modules are synchronized.