2D full-field displacement and vibration measurements of specularly reflecting surfaces by two-beam common-path digital holography

A new, to the best of our knowledge, configuration of common-path off-axis digital holography is proposed for simultaneous evaluation of out-of-plane and in-plane displacements of the vibrating object. The object is illuminated from two different directions, and each illumination interferes with its corresponding reference beam generated near the object, resulting in two independent holograms that are spatially multiplexed in a single camera image. Two multiplexed holograms, at undeformed and deformed states of the object, are recorded and processed to obtain the out-of-plane and in-plane displacements simultaneously. The proposed digital holographic system has the advantage of a simple and compact optical setup, is less sensitive to environmental disturbances, and has high temporal phase stability. The two-dimensional (z, x) full-field amplitude and phase vibration analysis of a perfect specularly reflecting surface are also demonstrated by the proposed holographic system. The experimental results authenticate the feasibility of the proposed system and reveal its unique advantages. The proposed digital holographic system, owing to simple and compact geometry and providing several advantages over other two-channel holographic systems, may find a wide range of applications in investigating real-time dynamic phenomena. (C) 2021 Optical Society of America.

Automated summary

A new configuration of common-path off-axis digital holography is proposed for evaluating out-of-plane and in-plane displacements of a vibrating object simultaneously. The system features a simple and compact optical setup, low sensitivity to environmental disturbances, and high temporal phase stability. The experimental results authenticate the feasibility of the proposed system and demonstrate its unique advantages for investigating real-time dynamic phenomena.