This thesis studies the sensorless control strategy of Interior Permanent Magnet Synchronous Motor (IPMSM). In order to apply it to the electric motorcycle system stably, it is necessary to test the stability of the motor speed in each speed range. The experiment not only studies and analyzes a single sensorless algorithm, but also gives appropriate control strategies for different speed ranges. High frequency injection method injects signal into the direct axis at zero and low speeds, extracts feedback current signals to estimate the rotor position and speed values, and tunes the PI parameters to obtain stable system response. At medium and high speed range, Sliding Mode Observer method with robustness to nonlinear system is used to observe the back EMF signal, then using the signal as an input to the Phase-Locked Loop (PLL) system to obtain rotor angle information. The experiments show that stable response can be achieved at different speeds. Finally, different algorithms are combines to obtain the most accurate speed response at any speed range. From the above research of theoretical and practical part, this thesis will use Matlab/Simulink software combined with SVPWM and vector control technology to simulate the PMSM system and analyze the response of current, voltage and torque waveforms. Then using DSP TMS320F28069m and a three-phase inverter to develop the motor control system. Finally, verifying the feasibility of sensorless control strategy on IPMSM.