Abstract— The induction motor is very popular right now, especially for industrial and household applications. It is amazing and commendable how far variable speed drive technology has come. Due to their durability and low maintenance requirements, induction motors are being used more and more in a variety of industries where the majority of applications require quick response times and sophisticated speed control. The primary challenge to achieving the highest efficiency and maximum torque is speed control. This research introduces the formulation of the speed control as well as the speed control approaches. In this research, a hybrid speed-control system for a three-phase squirrel cage induction motor (SCIM) is presented. The proposed approach applies vector control and combines FOC with conventional controllers. The three-phase induction motor's speed response is enhanced using this technique, which combines the benefits of conventional controllers with FOC. Proportional integral - field oriented control (PI- FOC) simulation results and implementation are used to evaluate the performance of the hybrid system controller. At different load scenarios, performance measures such as rise time (tr), maximum percent overshoot, and settling time (ts) are recorded. By using MATLAB/ Simulink, the results demonstrated improved speed tracking performance and system stability, and they demonstrated the effectiveness of the proposed hybrid speed controller under a range of operating conditions

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