A decoupled control of 5-legs PWM inverter feeding a two induction motors-based electric vehicle powertrain

This paper proposes a traction drive system for electric vehicles (EVs) with two separate induction motor drive-based wheels. In this context, two three-phase induction motors are associated to five legs power inverter which one leg is shared by two phases of the motors. The independent control of the two induction motors allows replacing the mechanical differential speeds by an equivalent electrical module called electric differential (ED). In the proposed EV powertrain based on 5-leg inverter, the challenge is to achieve a decoupled control of the induction motors to ensure the EV stability while cornering or under slippery road condition. For this, the proposed independent control uses Indirect Field Oriented Control to ensure speed and rotor flux control of each induction motor, a Pulse Width Modulation to provide the command sequences to the 5-leg inverter and electric differential to generate the an appropriate reference when the two induction motors should be controlled at different speeds. For this, a numerical implementation of the independent controls on an embedded board (TMS 320F2812) to ensure a separate control of induction motor fed by the 5-leg inverter. Moreover, the proposed control takes into account the EV context such as the EV dynamic and uses European and American normalized driving cycles. EV-specific experimental tests on a digital signal processor TMS320LF2812 are carried-out to show the effectiveness of the proposed independent control for ED in terms of robustness and stability.