Abstract:Due to its distinctive spiral wavefront structure, the vortex beam produces a rotational Doppler shift proportional to the rotational speed when detecting rotating objects. The speed measurement accuracy of a double-mode vortex beam is twice that of a single-mode vortex beam, but the noise interference during the detection process causes a decrease in measurement accuracy. First, a comprehensive analysis of the mechanisms involved in measuring the velocity of rotating objects using a dual-mode vortex beam is undertaken, elucidating the various factors influencing measurement accuracy. Second, the object speed extraction algorithm is designed based on the measurement system design. Finally, the effects of four cases, Gaussian noise, multiplicative noise, detector accumulation time and beam mode purity, on speed measurement accuracy are analyzed. The results indicate that the high-order dual-mode vortex beam effectively improves speed measurement accuracy in noisy environments. Moreover, it achieves a mode purity improvement of 94% or more. Additionally, optimizing the control of detector accumulation time to exceed 0.49s yields superior speed measurement accuracy