This work presents color holographic display, which is based on a single phase only spatial light modulator (SLM). In the display entire area of the SLM is illuminated by an on-axis white light beam generated by a single large LED. The holographic display fully utilizes SLM bandwidth and has capability of full-color, full frame rate imaging of outstanding quality. This is achieved through: (i) optimal use of the source coherence volume, (ii) application of the single white light LED source, (iii) a development of a novel concept of color multiplexing technique with color filter mask in Fourier plane of the SLM, (iv) and a complex coding with improved diffraction efficiency. Within experimental part of the paper we show single color, full-color holographic 2D and 3D images generated for reconstruction depth exceeding 10 cm.
Visual quality assessment of digital holograms is facing many challenges. Main difficulties are related to the limited spatial resolution and angular field of view of holographic displays in combination with the complexity of steering and operating them for such tasks. Alternatively, non-holographic displays -and in particular light-field displays -can be utilized to visualize the numerically reconstructed content of a digital hologram. However, their suitability as alternative for holographic displays has not been validated. In this research, we have investigated this issue via a set of comprehensive experiments. We used Fourier holographic principle to acquire a diverse set of holograms, which were either computer-generated from point clouds or optically recorded from real macroscopic objects. A final public data set comprising 96 holograms was created using three compression methods which encoded the holograms at four bit-depths. Three separate subjective-tests were conducted using a holographic display, a light field display and a 2D display. For these subjective experiments, a double stimulus, multi-perspective, multi-depth subjective testing methodology was designed and implemented. The tests show that the nonholographic displays indicate a higher sensitivity to artifacts than the holographic display, though at the same time it is demonstrated they are highly correlated. This indicates that the numerically reconstructed holograms rendered on a light field or 2D display have a high predictive value for the perceived quality on holographic display.
We present an end-to-end full color Fourier holographic imaging approach, which involves standard holographic recording with three wavelengths and an improved LED-driven display. It provides almost undistorted orthoscopic reconstruction of large objects in full color, which can be viewed with a naked eye. High quality reconstruction is preserved across large object depths, measured in meters, as shown theoretically and experimentally. Our imaging approach is based on capture, processing and display of the object wave fields without spherical phase factors. This efficient convention combined with a novel numerical propagator for confocal fields enables complete axial decoupling of both ends of the imaging chain, and consequently, free manipulation of axial position as well as size of the image without visible deformations and with minimal computation effort.
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