The intent of this research is to introduce a novel design for high frequency piezoelectric bulk acoustic wave (BAW) gyroscope using hybrid resonance modes of length extensional vibration mode and secondary elliptical mode (n = 3). Finite element analysis (FEA) of COMSOL Multiphysics software has been used for optimizing structures, and demonstrating the effective detection of Coriolis force due to rotation in comparison with reported high-frequency piezoelectric resonator gyroscopes. Simulation shows that this device has a sensitivity of 12.26 nA◦ /s with the linear dynamic range greater than 5000 ◦ /s at Q = 10000. An annular gyroscope is also designed for the purpose of reference about n = 3 mode by thin film piezoelectric transduction. The commercial process (PiezoMUMPs, MEMSCAP inc.) is selected for the fabrication with device structural thickness of 10 µm of (100) single crystal silicon (SCS), 0.5 µm thick aluminum nitride (AlN) thin film deposited on SCS surface, along with 1 µm thick aluminum (Al) top electrode. The resonance characteristics of two gyroscopes are first measured using network analyzer. In according with the test results, the frequency split between drive and sense modes of hybrid resonance gyroscope is 11.7 kHz, even though, the drive direction and sense direction of referred gyroscope have not been aligned to on the surface of SCS. It obtains quality factor exceeding 1000 in air with the resonance frequency of about 10.8 MHz. The conventional placement of electrodes on top of an annular gyroscope to stimulate the resonance of n = 3 mode has achieved a poor performance based on frequency response from simulation and experimental measurement. The driven closed-loop control and open-loop readout configuration of a digital lock-in amplifier are utilized for angular rate measurement. Hybrid resonance gyroscope has been ii firstly demonstrated to be sensitive to Coriolis force, and the gyroscope has a scale factor of about 787 pA/◦ /s in a dynamic range of ±95 ◦ /s with a resolution of 0.38 ◦ /s/√ Hz under the mode-mismatch operation before demodulation. A zero bias instability of 0.167 ◦ /s and an angle random walk of 110.6 ◦ / √ h have been attained for short-time measurement. The measured output noise floor that compromises of a discrete amplifier circuit is 32.61 µV/√ Hz.