As the environmental crises become more significant, electric vehicles have drawn more attentions and have been rapidly developed in recent years. Even though permenant magnetic motors (PM) are usually preferred due to their inherent characteritics of high torque and power density, induction motors (IM) behave better on the aspects of cost, reliability, and with a wider operational speed range. Particularly, IMs dominate PMs with higher overload capability on applications of low-powered electric vehicle. However, control techniques of IMs are still chanllenging to meet high-torque and high-efficiency vehicle performance. Therefore, this study is dedicated to developing a DSP-based precise servo control with maximizing torque and efficiency for the IM implemented on electric vehicles, and the developed automatic control strategy is successfully implemented on the TMS320F28335 DSP microcontroller. The indirect vector control is commonly exploited for high performance servo control of the IM. To achieve control of the flux and torque, precise synchronous angle estimation based on the rotor time constant is crucial for stator current decoupling, and thus control performance is highly dependent on the accuracy of parameters. Due to the fact that conventional identification approaches are suffered from difficulty of implementation, an acceleration-based identification process which can be directly performed on the vehicle with satisfactory accuracy is developed in this thesis. In addition, the maximum torque per amperage (MTPA) operation is considerably important to provide desirable acceleration of the vehicle. It has been already recognized that by dividing the stator current equally into the flux-producing component and the torque-producing component, the MTPA can be thus obtained. Nevertheless, such arrangement causes severe flux saturation and the desirable operation is usually lost. In this Thesis, a standard experimental process is developed to find proper setting of the flux-producing current so that the maximum acceleration can be fulfilled. Despite of the maximum acceleration performance of the electric vehicle obtained by the MTPA operation, its operating efficiency is still comparatively low. In general, the efficiency can be improved by adjusting the flux-producing current. A novel switching control strategy where the defined slip factor can be automatically adjusted according to driving conditions is developed for achieving both the maximum acceleration and the highest efficiency, and experimental results show that it is more suitable to traction control of the electric vehicle because of its smooth operating performance. It has been also verified that all the acceleration, efficiency coefficient, and final vehicle speed can be improved by 67%, 273.6%, and 111.8%, respectively, when the system is fed by the maximum stator current compared with those of the conventional control approach by applying equal d-q current command.