Binary code DOE optimization for speckle suppression in a laser display

Victor Yurlov; Anatoliy Lapchuk; Kyunghun Han; Seong-Jin Son; Bok Hyeon Kim; Nan Ei Yu

doi:10.1364/AO.57.008851

Applied Optics
Vol. 57,
Issue 30,
pp. 8851-8860
(2018)
•https://doi.org/10.1364/AO.57.008851

Binary code DOE optimization for speckle suppression in a laser display

Victor Yurlov, Anatoliy Lapchuk, Kyunghun Han, Seong-Jin Son, Bok Hyeon Kim, and Nan Ei Yu

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Victor Yurlov, Anatoliy Lapchuk, Kyunghun Han, Seong-Jin Son, Bok Hyeon Kim, and Nan Ei Yu, "Binary code DOE optimization for speckle suppression in a laser display," Appl. Opt. 57, 8851-8860 (2018)

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Related Topics
Table of Contents Category
- Imaging Systems, Image Processing, and Displays
Optics & Photonics Topics
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The topics in this list come from the Optics and Photonics Topics applied to this article.

About this Article
History
- Original Manuscript: June 18, 2018
- Revised Manuscript: August 29, 2018
- Manuscript Accepted: September 18, 2018
- Published: October 12, 2018

Abstract

Using a laser light source in imaging devices provides a wide color gamut, high brightness, resolution, and efficiency. At the same time, it creates a speckle pattern that deteriorates the image quality. This paper is related to the application of the moving binary code diffractive optical element (DOE) for speckle suppression in a laser display. Analytical optimization of DOE parameters is made in this paper. The optimal DOE pitch is found analytically. Limitation of the DOE code length is shown, and the highest possible code length is estimated. Application of the compound Barker code for the DOE design is suggested. As an alternative, the $M$ -sequence and minimum peak side-lobe codes are considered. The expected residual speckle contrast ratio after application of those codes is estimated for the number of codes. A comparison of the different codes is done, and recommendations for speckle suppression DOE design are provided.

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$τ_{opt} = T_{opt} / λ$	NA	1/A
11.0	0.25	$4 ∶ 3$
5.1	0.5	$4 ∶ 3$
10.9	0.25	$16 ∶ 9$
5.0	0.5	$16 ∶ 9$

Code Length $N$	Inner Code Length $P$	Outer Code Length $K$	Code Sequence (Hexadecimal)
10	2	5	159
14	2	7	15A6
15	5	3	085D
16	4	4	22D2
20	5	4	10BA2
25	5	5	210BA2
26	2	13	155A599
28	7	4	1A3790D
33	3	11	049DB1D8E
35	7	5	0D1A3790D
44	11	4	1DA3B7890ED
49	7	7	03468DE5C86F2

Code Length $N$	Code Sequence (Hexadecimal)
15	09AF
31	7B4C1C8A

Code Length $N$	Code Sequence (Hexadecimal)
10	167
14	1483
15	182B
16	6877
20	5181B
25	12540E7
26	2380AD9
28	8F1112D
33	0CCAA587F
35	00796AB33
44	0FECECB2AD7
49 [21]	012ABEC79E46F

Code Length $N$	Code Sequence (Hexadecimal)
10	123
14	2A60

$N$	$M$ - Sequences		Compound Barker Codes		MPS codes [19]		New Optimized Codes [17]
$N$	1D	2D	1D	2D	1D	2D	1D	2D
10			18.6	6	19.3	6.4	18.0	5.6
14			15.5	4.1	14.9	3.9	14.9	3.9
15	14.3	3.5	15.9	4.4	14.5	3.6
16			13.7	3.2	14.9	3.8
20			13.1	3.0	13.4	3.1
25			13.3	3.1	12.0	2.5
26			11.1	2.1	11.8	2.4
28			10.9	2.1	11.0	2.1
31	9.9	1.7			10.4	1.9
33			11.1	2.1	9.7	1.6
35			10.3	1.8	9.7	1.6
44			8.6	1.3	8.3	1.2
49			8.8	1.3	9.1	1.4

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Applied Optics