DMD-based optical pattern recognition using holograms generated with the Hartley transform

High-speed optical reconstruction of holographic and diffractive optical elements is widely used in encryption and recognition, 3D-displays, beam shaping, nanofabrication, visualization, etc. This paper proposes the use of amplitude holograms generated by the Hartley transform (HT) as filters in an incoherent correlator. The real computations using the HT are faster and less computationally intensive than the standard complex transforms. Generated holograms using HT and Fourier transform (FT) were compared. It is demonstrated that the diffraction efficiency of HT-based holograms is not inferior to the FT case. The reconstruction quality is better in metrics (NSTD, MSE, SNR, RMS contrast, SSIM) by 2-10%. An optical incoherent correlator based on two digital mi-cromirror devices (DMDs) was constructed. DMDs have very high frame rates (up to 30 kHz) that provides its great potential for application in fast recognition problems. The object images were displayed on the first DMD. The holograms generated with the HT were binarized and displayed on the second DMD. The objects were suc-cessfully recognized. Thus, HT-based amplitude holograms can be successfully used instead of FT-based amplitude holograms.

Automated summary

This paper proposes the use of amplitude holograms generated by the Hartley transform as filters in an incoherent correlator. The real computations using the HT are faster and less computationally intensive than the standard complex transforms. The performance of HT-based holograms is comparable to FT-based holograms in terms of diffraction efficiency, and shows better reconstruction quality in various metrics.