Image quality improvement of random phase-free holograms by addressing the cause of ringing artifacts

Yuki Nagahama; Tomoyoshi Shimobaba; Takashi Kakue; Yasuhiro Takaki; Tomoyoshi Ito

doi:10.1364/AO.58.002146

Applied Optics
Vol. 58,
Issue 9,
pp. 2146-2151
(2019)
•https://doi.org/10.1364/AO.58.002146

Image quality improvement of random phase-free holograms by addressing the cause of ringing artifacts

Yuki Nagahama, Tomoyoshi Shimobaba, Takashi Kakue, Yasuhiro Takaki, and Tomoyoshi Ito

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Yuki Nagahama, Tomoyoshi Shimobaba, Takashi Kakue, Yasuhiro Takaki, and Tomoyoshi Ito, "Image quality improvement of random phase-free holograms by addressing the cause of ringing artifacts," Appl. Opt. 58, 2146-2151 (2019)

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Abstract

Holographic projectors utilize holography techniques, although there are several barriers to realizing holographic projections. One such challenge is the deterioration of the hologram image quality caused by speckle noise and ringing artifacts. Several methods designed to reduce the speckle noise and ringing artifacts have been proposed. However, these methods require multiple diffraction calculations and a significant amount of computational time. In this paper, we reveal that ringing artifacts are due to object light being recorded on the edge of the hologram and that the high-frequency component of the original image leaks outside of the recording area of the hologram when the random phase-free method is used. Therefore, this study proposes an object light centering method that prevents object light from being recorded on the edge of the hologram and prevents the high-frequency component of the original image from leaking outside the recording area of the hologram, which removes the ringing artifact and extends the random phase-free method to an off-axis hologram.

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CGH resolution	$512 \times 512$ (pixels)
CGH pixel pitch	4.0 (μm)
Laser wavelength	513.8 (nm)
Projection distance $z_{2}$	0.5 (m)
Magnification	12.0
$x$ offset	14.4 (mm)
$y$ offset	14.4 (mm)

	Dynamic Range
$x$ offset and $y$ offset	14.4 (mm)	16.8 (mm)	19.2 (mm)
Random phase-free method	0.0993	0.1087	0.1190
Random phase-free method + GS algorithm (10 iterations)	0.1151	0.1253	0.1403
Object light centering method $(α = 0.5)$	0.0924	0.0931	0.0908

	PSNR (dB)	SSIM	Calculation Time (ms)
Random phase-free method	22.69	0.816	145
Random phase-free method + GS algorithm (10 iterations)	29.14	0.909	2384
Object light centering method $(α = 0.5)$	28.59	0.892	145

	$x$ offset and $y$ offset (mm)	PSNR (dB)	SSIM	Diffraction Efficiency (a.u.)
Random phase-free method	14.4	19.40	0.689	$4.49 \times 10^{- 4}$
	16.8	19.27	0.702	$3.75 \times 10^{- 4}$
	19.2	19.70	0.714	$3.12 \times 10^{- 4}$
Random phase-free method + GS algorithm (10 iterations)	14.4	24.32	0.802	$3.46 \times 10^{- 4}$
	16.8	24.61	0.829	$2.92 \times 10^{- 4}$
	19.2	24.59	0.836	$2.33 \times 10^{- 4}$
Object light centering method $(α = 0.5)$	14.4	23.98	0.792	$5.37 \times 10^{- 4}$
	16.8	28.00	0.820	$5.30 \times 10^{- 4}$
	19.2	29.34	0.828	$5.56 \times 10^{- 4}$

SLM resolution	$1920 \times 1080$ (pixels)
SLM pixel pitch (Sampling pitch in the hologram plane)	6.4 (μm)
Laser wavelength	513.8 (nm)
Projection distance	1.1 (m)
Magnification	2.0
$x$ offset	10.24 (mm)
$y$ offset	10.24 (mm)

Abstract

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Applied Optics