Your search keyword '"Lenslet array"' showing total 28 results

1. P‐4.26: Virtual Reality Headsets with Ultra‐Compact Pancake Optics Utilizing Free‐Form Optical Lenslet Array Simulation Models.

Author

Hou, Tianwen, Bi, Ye, Gao, Yuan, Rui, Congsan, Liang, Jiaojiao, Zang, Shunli, Wang, Chaohao, Le, Chengrui, and Zhao, Lei

Subjects

VIRTUAL reality, PANCAKES, waffles, etc., SIMULATION methods & models, HEADSETS, OPTICS, HEAD-mounted displays

Abstract

This paper presents a simulation model for a large field‐of‐view, wide eye‐box, and high‐resolution ultra‐thin near‐eye display based on a freeform optical lens array. It creatively incorporates a polarization‐based optical folding technique (pancake lens), reducing the thickness of the simulation model to less than 1.4 cm (excluding the display screen). Compared to traditional VR devices, this significantly reduces the volume and weight of the equipment. The parameters of the simulation model are as follows: eye‐box size of 10mm, resolution utilization rate of 50%; the introduction of freeform optics greatly improves the imaging quality of the displayed images. At the same time, the field of view reaches 116° (single eye, vertical direction). [ABSTRACT FROM AUTHOR]

Published

2024

2. Imaging Analysis of Photonic Integrated Interference Imaging System Based on Compact Sampling Lenslet Array Considering On-Chip Optical Loss.

Author

Deng, Xiaoqin, Tao, Wei, Diao, Yuqing, Sang, Benliang, and Sha, Wei

Subjects

IMAGING systems, OPTICAL losses, IMAGE analysis, SILICON nitride, INTEGRATED circuits

Abstract

A photonic integrated interference imaging system (PIIIS) is a computational imager based on Michelson interference and photonic integrated circuits (PICs). In this paper, a PIIIS based on a compact sampling lenslet array that can sample the zero spatial frequency through a single lenslet, densely sample the frequency in the azimuth direction through the configuration of a hierarchical multistage lenslet array, and continuously sample the frequency in the radial direction through a Langford sequence is proposed. We introduce the design process of the compact sampling lenslet array in detail and simulate the imaging of the system. The simulation results demonstrate that the lenslet array can effectively improve the imaging quality of a PIIIS. In addition, we design a silicon PIC and a silicon nitride transition PIC that match the compact sampling lenslet array and simulate the imaging of the system under the influence of the on-chip optical loss of PICs (the average interference baseline loss is 15.4 dB at 1550 nm). The results show that on-chip optical loss mainly affects the brightness and contrast of the reconstructed image but has little effect on the structure. [ABSTRACT FROM AUTHOR]

Published

2023

3. 52‐1: Ultracompact Virtual Reality System.

Author

Zou, Junyu, Luo, Zhenyi, Rao, Yi, and Wu, Shin‐Tson

Subjects

OPTICAL elements, INTERPOLATION

Abstract

We demonstrate an ultracompact virtual reality (VR) system with thickness of about 1‐cm. In this system, the imaging optics consists of a lenslet array, a deflector array, and a Pancharatnam‐Berry deflector (PBD). We have experimentally demonstrated a polarization interpolation configuration to reduce the system thickness by nearly 50%. [ABSTRACT FROM AUTHOR]

Published

2023

4. Experimental Studies on Fabricating Lenslet Array with Slow Tool Servo.

Author

Kang, Wenjun, Seigo, Masafumi, Xiao, Huapan, Wang, Daodang, and Liang, Rongguang

Subjects

DIAMOND turning, SURFACE topography

Abstract

On the demand of low-cost, lightweight, miniaturized, and integrated optical systems, precision lenslet arrays are widely used. Diamond turning is often used to fabricate lenslet arrays directly or molds that are used to mold lenslet arrays. In this paper, mainly by real-time monitoring position following error for slow tool servo, different fabrication parameters are quantitatively studied and optimized for actual fabrication, then by actual fabrication validation, uniform and high-fidelity surface topography across the actual whole lenslet array is achieved. The evaluated fabrication parameters include sampling strategy, inverse time feed, arc-length, etc. The study provides a quick, effective, and detailed reference for both convex and concave lenslet array cutting parameter selection. At the end, a smooth zonal machining strategy toolpath is demonstrated for fabricating concave lenslet arrays. [ABSTRACT FROM AUTHOR]

Published

2022

5. Imaging Analysis of Photonic Integrated Interference Imaging System Based on Compact Sampling Lenslet Array Considering On-Chip Optical Loss

Author

Xiaoqin Deng, Wei Tao, Yuqing Diao, Benliang Sang, and Wei Sha

Subjects

lenslet array, interference imaging, photonic integrated circuits, spatial frequency coverage, baseline optimization, Applied optics. Photonics, TA1501-1820

Abstract

A photonic integrated interference imaging system (PIIIS) is a computational imager based on Michelson interference and photonic integrated circuits (PICs). In this paper, a PIIIS based on a compact sampling lenslet array that can sample the zero spatial frequency through a single lenslet, densely sample the frequency in the azimuth direction through the configuration of a hierarchical multistage lenslet array, and continuously sample the frequency in the radial direction through a Langford sequence is proposed. We introduce the design process of the compact sampling lenslet array in detail and simulate the imaging of the system. The simulation results demonstrate that the lenslet array can effectively improve the imaging quality of a PIIIS. In addition, we design a silicon PIC and a silicon nitride transition PIC that match the compact sampling lenslet array and simulate the imaging of the system under the influence of the on-chip optical loss of PICs (the average interference baseline loss is 15.4 dB at 1550 nm). The results show that on-chip optical loss mainly affects the brightness and contrast of the reconstructed image but has little effect on the structure.

Published

2023

6. Orthoscopic integral imaging for different lenslet arrays in real and virtual fields.

Author

Wu, Wei, Zhong, Cheng, Wang, Shigang, and Han, Minghao

Subjects

*PHOTOGRAPHY techniques, *THREE-dimensional imaging, *INTEGRALS, *PARALLAX, *RAY tracing

Abstract

In the future, various types and parameters of display devices and lenslet arrays will be commercially available. Different display devices can be matched by cutting and expanding elemental images, while different lenses require changing the pixel mapping structure individually for each pixel, which involves complex calculations. A simple pseudoscopic-to-orthoscopic conversion for lenslet arrays with different apertures in real and virtual fields has meaningful practical implications. To this end, orthoscopic integral imaging for different lenslet arrays in real and virtual fields is proposed herein. The tilt-shift photography technique is used to generate a wider view image array, which is cropped to form the orthoscopic elemental image arrays required for lenslet arrays of various shapes, considering their specific structures and shapes. The approach expands the viewing angle without the need to change the system parameters or recalculate the elemental image relative to the viewer's position, enabling multiple individuals to view the three-dimensional (3D) images from different angles simultaneously. It does not require additional devices or depth information. The repositioning of the original camera array enables various display modes, such as real images, virtual images, and co-displays, which enhance the 3D display effect. The experimental results demonstrate that the proposed method can generate 3D images with correct depth relationships and large viewing angles, through subjective and quantitative comparison of the parallax. • The pseudoscopic problem in viewing 3D images effectively addressed. • A flexible method for generating orthoscopic integral images proposed. • Method applicable for different lenslet arrays in real and virtual fields. • Real, virtual, and co-displayed 3D images obtained. • Simulations and optical experiments confirmed method efficacy. [ABSTRACT FROM AUTHOR]

Published

2024

7. Experimental Studies on Fabricating Lenslet Array with Slow Tool Servo

Author

Wenjun Kang, Masafumi Seigo, Huapan Xiao, Daodang Wang, and Rongguang Liang

Subjects

diamond turning, slow tool servo, lenslet array, position following error, optics fabrication, Mechanical engineering and machinery, TJ1-1570

Abstract

On the demand of low-cost, lightweight, miniaturized, and integrated optical systems, precision lenslet arrays are widely used. Diamond turning is often used to fabricate lenslet arrays directly or molds that are used to mold lenslet arrays. In this paper, mainly by real-time monitoring position following error for slow tool servo, different fabrication parameters are quantitatively studied and optimized for actual fabrication, then by actual fabrication validation, uniform and high-fidelity surface topography across the actual whole lenslet array is achieved. The evaluated fabrication parameters include sampling strategy, inverse time feed, arc-length, etc. The study provides a quick, effective, and detailed reference for both convex and concave lenslet array cutting parameter selection. At the end, a smooth zonal machining strategy toolpath is demonstrated for fabricating concave lenslet arrays.

Published

2022

8. Integral Imaging With Full Parallax Based on Mini LED Display Unit

Author

Wei Wu, Shigang Wang, Cheng Zhong, Meilan Piao, and Yan Zhao

Subjects

Elemental image, integral imaging, mini LED, lenslet array, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

Integral imaging has been considered as the most applicable technology of true 3D display in the near future. In this paper, we propose the method to achieve full parallax and large-screen integral imaging display based on mini LED. Compared to the existing integral imaging systems based on the LED, the proposed method can present both horizontal and vertical parallaxes. We explore the optical parameter matching method between mini LED display unit and lenslet unit and design three different shapes of lenslet arrays. The imaging performance of lenslet arrays of circular-shape, square-shape, and hexagonal-shape is analyzed. The method of window interception is proposed to generate elemental images for the lenslet arrays with different apertures and arranging structures. The experimental results show that the true 3D display with full parallax and screen scalability has been realized using the proposed method and the display effect of lenslet array with hexagonal-shape is the best according to the evaluation of both subjective and objective merits.

Published

2019

9. Beam Pre-Shaping Methods Using Lenslet Arrays for Area-Based High-Resolution Vehicle Headlamp Systems.

Author

Li, Yang, Knöchelmann, Marvin, and Lachmayer, Roland

Subjects

TRAFFIC safety, AUTOMOBILE lighting, VEHICLES, GLARE, LIGHTING

Abstract

High-resolution light distributions are lately in demand for vehicle headlamp systems as an innovative lighting approach. This lighting approach can realize functionalities, such as precise glare avoidance and on-road projection, which are useful for improving traffic comfort and safety. For achieving the required high-resolution light distribution, area-based projection technologies, such as DMD, LCD, and LCoS, are considered to be integrated into such headlamps. These projection devices demand rectangular illumination areas with specific light distributions to fulfill the requirements for illumination efficiency and performance in headlamp systems. Lenslet arrays, based on the principle of Köhler illumination, can effectively homogenize the light and shape it into rectangular shapes simultaneously. Such components are widely used in projection applications. However, they also show functional potentialities to be applied in high-resolution headlamps. This paper explains the design principles and methods of lenslet arrays for beam pre-shaping in headlamp systems. It validates the homogenization using a self-designed and manufactured lenslet array in a demonstrator in the first place. Afterward, this paper introduces two new methods for the centralized beam shaping required by some headlamps. These methods are validated by optical simulations. [ABSTRACT FROM AUTHOR]

Published

2020

10. Beam Pre-Shaping Methods Using Lenslet Arrays for Area-Based High-Resolution Vehicle Headlamp Systems

Author

Yang Li, Marvin Knöchelmann, and Roland Lachmayer

Subjects

high-resolution vehicle headlamps, lenslet array, beam pre-shaping methods, Technology, Engineering (General). Civil engineering (General), TA1-2040, Biology (General), QH301-705.5, Physics, QC1-999, Chemistry, QD1-999

Abstract

High-resolution light distributions are lately in demand for vehicle headlamp systems as an innovative lighting approach. This lighting approach can realize functionalities, such as precise glare avoidance and on-road projection, which are useful for improving traffic comfort and safety. For achieving the required high-resolution light distribution, area-based projection technologies, such as DMD, LCD, and LCoS, are considered to be integrated into such headlamps. These projection devices demand rectangular illumination areas with specific light distributions to fulfill the requirements for illumination efficiency and performance in headlamp systems. Lenslet arrays, based on the principle of Köhler illumination, can effectively homogenize the light and shape it into rectangular shapes simultaneously. Such components are widely used in projection applications. However, they also show functional potentialities to be applied in high-resolution headlamps. This paper explains the design principles and methods of lenslet arrays for beam pre-shaping in headlamp systems. It validates the homogenization using a self-designed and manufactured lenslet array in a demonstrator in the first place. Afterward, this paper introduces two new methods for the centralized beam shaping required by some headlamps. These methods are validated by optical simulations.

Published

2020

11. Full Parallax Integral 3D Display and Image Processing Techniques

Author

Byung-Gook Lee, Seokmin Hong, Han Yuan Dong, and Donghak Shin

Subjects

integral imaging, lenslet array, elemental images, Kinect, Information technology, T58.5-58.64

Abstract

Purpose – Full parallax integral 3D display is one of the promising future displays that provide different perspectives according to viewing direction. In this paper, the authors review the recent integral 3D display and image processing techniques for improving the performance, such as viewing resolution, viewing angle, etc.Design/methodology/approach – Firstly, to improve the viewing resolution of 3D images in the integral imaging display with lenslet array, the authors present 3D integral imaging display with focused mode using the time-multiplexed display. Compared with the original integral imaging with focused mode, the authors use the electrical masks and the corresponding elemental image set. In this system, the authors can generate the resolution-improved 3D images with the n×n pixels from each lenslet by using n×n time-multiplexed display. Secondly, a new image processing technique related to the elemental image generation for 3D scenes is presented. With the information provided by the Kinect device, the array of elemental images for an integral imaging display is generated.Findings – From their first work, the authors improved the resolution of 3D images by using the time-multiplexing technique through the demonstration of the 24 inch integral imaging system. Authors’ method can be applied to a practical application. Next, the proposed method with the Kinect device can gain a competitive advantage over other methods for the capture of integral images of big 3D scenes. The main advantage of fusing the Kinect and the integral imaging concepts is the acquisition speed, and the small amount of handled data.Originality / Value – In this paper, the authors review their recent methods related to integral 3D display and image processing technique.Research type – general review.

Published

2015

12. A Concept for a Sensitive Micro Total Analysis System for High Throughput Fluorescence Imaging

Author

Yosi Shacham and Arthur Rabner

Subjects

Fluorescence, imaging, lab-on-chip, μfluidic, lenslet array, μLED chip, image sensor, biosensor., Chemical technology, TP1-1185

Abstract

This paper discusses possible methods for on-chip fluorescent imaging forintegrated bio-sensors. The integration of optical and electro-optical accessories, accordingto suggested methods, can improve the performance of fluorescence imaging. It can boostthe signal to background ratio by a few orders of magnitudes in comparison to conventionaldiscrete setups. The methods that are present in this paper are oriented towards buildingreproducible arrays for high-throughput micro total analysis systems (μTAS). The firstmethod relates to side illumination of the fluorescent material placed into micro-compartments of the lab-on-chip. Its significance is in high utilization of excitation energyfor low concentration of fluorescent material. The utilization of a transparent μLED chip,for the second method, allows the placement of the excitation light sources on the sameoptical axis with emission detector, such that the excitation and emission rays are directedcontroversly. The third method presents a spatial filtering of the excitation background.

Published

2006

13. FULL PARALLAX INTEGRAL 3D DISPLAY AND IMAGE PROCESSING TECHNIQUES.

Author

Byung-Gook Lee, Seokmin Hong, Han Yuan Dong, and Donghak Shin

Subjects

IMAGE processing, THREE-dimensional display systems, IMAGE analysis, PIXELS, OPTICAL resolution

Abstract

Purpose - Full parallax integral 3D display is one of the promising future displays that provide different perspectives according to viewing direction. In this paper, the authors review the recent integral 3D display and image processing techniques for improving the performance, such as viewing resolution, viewing angle, etc. Design/methodology/approach - Firstly, to improve the viewing resolution of 3D images in the integral imaging display with lenslet array, the authors present 3D integral imaging display with focused mode using the time-multiplexed display. Compared with the original integral imaging with focused mode, the authors use the electrical masks and the corresponding elemental image set. In this system, the authors can generate the resolution-improved 3D images with the n×n pixels from each lenslet by using n×n time-multiplexed display. Secondly, a new image processing technique related to the elemental image generation for 3D scenes is presented. With the information provided by the Kinect device, the array of elemental images for an integral imaging display is generated. Findings - From their first work, the authors improved the resolution of 3D images by using the time-multiplexing technique through the demonstration of the 24 inch integral imaging system. Authors' method can be applied to a practical application. Next, the proposed method with the Kinect device can gain a competitive advantage over other methods for the capture of integral images of big 3D scenes. The main advantage of fusing the Kinect and the integral imaging concepts is the acquisition speed, and the small amount of handled data. Originality / Value - In this paper, the authors review their recent methods related to integral 3D display and image processing technique. [ABSTRACT FROM AUTHOR]

Published

2014

14. Optimized microlens-array geometry for Hartmann–Shack wavefront sensor.

Author

Oliveira, O.G., de Lima Monteiro, D.W., and Costa, R.F.O.

Subjects

*MICROLENSES, *OPTICAL instruments, *WAVEFRONT sensors, *FABRICATION (Manufacturing), *HOLOGRAPHY, *OPHTHALMIC lenses

Abstract

Abstract: This work presents the fabrication and test of microlens arrays for Hartmann–Shack wavefront sensor, which were optimized, in terms of geometry, to be applied to the ophthalmic context. The optimization procedure was previously proposed by the authors and comprised the minimization of the wavefront reconstruction error through the use of genetic algorithm. The results indicated that arrays with 10 and 16 suitably located lenses could perform as good as those with a larger number of microlenses (25 or 36) in a rectangular geometry. In the present work, the sequence consisted in fabricating molds in silicon of the optimized array geometries; replicating the molds on polymer; and testing the final arrays on an optical bench, to comparatively assess the performance of the fabricated arrays. In general, final results corroborate with the ones predicted by simulations. [Copyright &y& Elsevier]

Published

2014

15. Orthoscopic integral imaging display by use of the computational method based on lenslet model.

Author

Piao, Yongri, Zhang, Miao, Lee, Joon-Jae, Shin, Donghak, and Lee, Byung-Gook

Subjects

*IMAGING systems, *ARBITRARY constants, *FLEXIBILITY (Mechanics), *IMAGE reconstruction, *FEASIBILITY studies

Abstract

Abstract: In this paper, we propose a computational depth conversion method based on the lenslet model to display the orthoscopic 3D images in 3D integral imaging display. The proposed method permits the synthesis of elemental images for the orthoscopic 3D images at any arbitrary position without any restrictions and requires no additional procedure during the depth conversion process. Due to the lenslet model involved in the depth conversion procedure, the proposed method can broaden the flexibility of 3D image reconstruction in the integral imaging display system. We carry out the preliminary experiments to prove the feasibility of the proposed method. The experimental results reveal that the proposed method is an effective depth conversion method that allows the reconstruction of the orthoscopic 3D images at any arbitrary position. [Copyright &y& Elsevier]

Published

2014

16. Depth extraction for 3D objects via windowing technique in computational integral imaging with a lenslet array

Author

Yoo, Hoon

Subjects

*IMAGING systems, *INFORMATION theory, *DATA extraction, *OPTICS, *IMAGE analysis, *PHOTOGRAPHS

Abstract

Abstract: This paper describes a novel depth extraction method for 3D objects using the windowing technique in computational integral imaging with a lenslet array. The proposed method includes pickup through a lenslet array with a snapshot, introduction of slice image pairs obtained from the windowing technique, and extraction of depth information using block matching between the slice image pairs. Also, this paper presents a theory of how the windowing technique works for depth extraction and an analysis of how it enables us to have a depth image from low-resolution elemental images. A preliminary optical experiment indicates that the proposed method provides a substantial improvement on the depth extraction technique in computational integral imaging with a lenslet array. [Copyright &y& Elsevier]

Published

2013

17. Three-dimensional image correlator using fast computational integral imaging reconstruction method based on pixel-to-pixel mapping

Author

Yoo, Hoon and Kim, Dong Keun

Subjects

*THREE-dimensional imaging, *IMAGE reconstruction, *PIXELS, *CORRELATORS, *INTEGRALS, *PHYSICS experiments, *LENSES

Abstract

Abstract: In this paper, a three-dimensional (3D) image correlator using a fast computational integral imaging reconstruction (CIIR) method based on a pixel-to-pixel mapping is proposed. In order to implement the fast CIIR method, we replace the magnification process in the conventional CIIR by a pixel-to-pixel mapping. The proposed fast CIIR method reconstructs two sorts of plane images; a plane image whose quality is sufficient, and a dot pattern plane image insufficient to view. This property is very useful to enhance the performance of a CIIR-based image correlator. Thus, we apply the fast CIIR method to a CIIR-based image correlator. To show the feasibility of the proposed method, some preliminary experiments on both pattern correlation and computational cost are carried out, and the results are presented. Our experimental results indicate that the proposed image correlator is superior to the previous method in terms of both correlation performance and complexity. [Copyright &y& Elsevier]

Published

2011

18. Simulation of the sensing performance of a Shack-Hartmann wavefront sensor related to the lenslet array.

Author

Guo, Wenjiang, Zhao, Liping, and Chen, I-Ming

Subjects

DETECTORS, SIMULATION methods & models, CHARGE coupled devices, IMAGE reconstruction, EXPERIMENTS, SURFACES (Physics)

Abstract

Abstract: A Shack-Hartmann wavefront sensor (SHWS) uses a lenslet array to sample incoming wavefront onto a CCD. By comparing the focal spots images of the sample and a reference, wavefront profile is reconstructed and therefore the sample shape is revealed. Various factors affect the performance of SHWS. In order to study how and to which extend does each factor affect the reconstruction result, we established a simulation platform in MATLAB. Detailed properties, especially the configuration of the lenslet array related issues, were analyzed through this system-oriented platform, and by doing so we obtained some guidance in surface measurement experiment. [Copyright &y& Elsevier]

Published

2011

19. Optimization of the Hartmann–Shack microlens array

Author

de Oliveira, Otávio Gomes and de Lima Monteiro, Davies William

Subjects

*LENSES, *ADAPTIVE optics, *OPTICAL detectors, *OPTICAL aberrations, *OPHTHALMOLOGY, *NUMERICAL analysis, *GENETIC algorithms

Abstract

Abstract: In this work we propose to optimize the microlens-array geometry for a Hartmann–Shack wavefront sensor. The optimization makes possible that regular microlens arrays with a larger number of microlenses are replaced by arrays with fewer microlenses located at optimal sampling positions, with no increase in the reconstruction error. The goal is to propose a straightforward and widely accessible numerical method to calculate an optimized microlens array for a known aberration statistics. The optimization comprises the minimization of the wavefront reconstruction error and/or the number of necessary microlenses in the array. We numerically generate, sample and reconstruct the wavefront, and use a genetic algorithm to discover the optimal array geometry. Within an ophthalmological context, as a case study, we demonstrate that an array with only 10 suitably located microlenses can be used to produce reconstruction errors as small as those of a 36-microlens regular array. The same optimization procedure can be employed for any application where the wavefront statistics is known. [Copyright &y& Elsevier]

Published

2011

20. Enhanced computational integral imaging system for partially occluded 3D objects using occlusion removal technique and recursive PCA reconstruction

Author

Lee, Byung-Gook, Liliana, and Shin, Dong-Hak

Subjects

*IMAGING systems, *THREE-dimensional imaging, *IMAGE processing, *INTEGRALS, *PRINCIPAL components analysis, *RECURSIVE functions

Abstract

Abstract: In this paper, we propose an enhanced computational integral imaging system by both eliminating the occlusion in the elemental images recorded from the partially occluded 3D object and recovering the entire elemental images of the 3D object. In the proposed system, we first obtain the elemental images for partially occluded object using computational integral imaging system and it is transformed to sub-images. Then we eliminate the occlusion within the sub-images by use of an occlusion removal technique. To compensate the removed part from occlusion-removed sub-images, we use a recursive application of PCA reconstruction and error compensation. Finally, we generate the entire elemental images without a loss from the newly reconstructed sub-images and perform the process of object recognition. To show the usefulness of the proposed system, we carry out the computational experiments for face recognition and its results are presented. Our experimental results show that the proposed system might improve the recognition performance dramatically. [Copyright &y& Elsevier]

Published

2010

21. Computational integral imaging reconstruction method of 3D images using pixel-to-pixel mapping and image interpolation

Author

Shin, Dong-Hak and Yoo, Hoon

Subjects

*IMAGE reconstruction, *INTERPOLATION, *PIXELS, *THREE-dimensional imaging, *ANALYTIC mappings, *DIGITAL communications

Abstract

Abstract: In this paper, we propose a novel computational integral imaging reconstruction (CIIR) method to improve the visual quality of the reconstructed images using a pixel-to-pixel mapping and an interpolation technique. Since an elemental image is magnified inversely through the corresponding pinhole and mapped on the reconstruction output plane based on pinhole-array model in the conventional CIIR method, the visual quality of reconstructed output image (ROI) degrades due to the interference problem between adjacent pixels during the superposition of the magnified elemental images. To avoid this problem, the proposed CIIR method generates dot-pattern ROIs using a pixel-to-pixel mapping and substitutes interpolated values for the empty pixels within the dot-pattern ROIs using an interpolation technique. The interpolated ROIs provides a much improved visual quality compared with the conventional method because of the exact regeneration of pixel positions sampled in the pickup process without interference between pixels. Moreover, it can enable us to reduce a computational cost by eliminating the magnification process used in the conventional CIIR. To confirm the feasibility of the proposed system, some experiments are carried out and the results are presented. [Copyright &y& Elsevier]

Published

2009

22. Depth-controlled reconstruction of 3D integral image using synthesized intermediate sub-images

Author

Hwang, Dong-Choon, Park, Jae-Sung, Shin, Dong-Hak, and Kim, Eun-Soo

Subjects

*THREE-dimensional imaging, *PHOTOGRAPHIC lenses, *STEREOGRAPHS, *OPTICAL images, *OPTICS

Abstract

Abstract: In this paper, we propose a method that controls the depth of the three-dimensional (3D) object existing over the depth-of-focus in integral imaging. The depth control method is performed only in a computer by synthesizing the intermediate sub-images between original sub-images obtained by transforming the captured elemental images. In the reconstruction process, we can obtain reconstructed 3D images with the better image quality within depth-of-focus than that reconstructed over the depth-of-focus. To demonstrate the feasibility of our method, optical and computational experiments are carried out and its results are presented. [Copyright &y& Elsevier]

Published

2008

23. Spectroscopic Measurements of Oxygen Saturation in the Retina.

Author

Ramella-Roman, J.C. and Mathews, S.A.

Abstract

We introduce a new type of retinal oximeter able to capture multiple spectroscopic sensitive images of the retina in a single snapshot. The core of our apparatus is a multiaperture camera that can be easily interfaced with a fundus camera system. A lenslet array divides the image collected by a fundus camera into identical subimages. A bandpass filter array in front of the lens system is used to collect the subimages only at the wavelengths of interest. Two different instruments were designed based on this simple principle. The first system can collect six different images, while the second system can collect up to 18 different images in a single snapshot. [ABSTRACT FROM PUBLISHER]

Published

2007

24. New imaging modes for lenslet-array tandem scanning microscopes.

Author

Watson, T. F, Ju&sbreve;kaitis, R, and Wilson, T

Subjects

*LIGHTING, *CONFOCAL microscopy

Abstract

Summary The tandem scanning microscope permits confocal images to be obtained in real time and viewed directly by eye. The light budget of these instruments may be increased from a few percent to a few tens of percent by incorporating an array of microlenses so as to increase the amount of illumination light that reaches the specimen. These instruments are configured for fluorescence imaging together with laser illumination. We describe how the versatility of the instrument may be enhanced to permit the use of incoherent light sources as well as extending the imaging modes to include bright-field reflection. [ABSTRACT FROM AUTHOR]

Published

2002

25. Second-order optical neural network with free-space interconnections.

Author

Wang, Dong-Xue, Anderson, Wallace L., and Karim, Mohammad A.

Subjects

*ARTIFICIAL neural networks, *OPTICAL interconnects, *INTEGRATED optics, *COMPUTER science

Abstract

The realization of a second-order neural network using a lenslet array is proposed. A method of generalization of matrix from a vector is considered such that the second-order neural network with a vector input can be considered as a first-order neural network with two-dimensional matrix input. Retrieval performances of both first-order and second-order neural networks as content-addressable memories are verified with computer simulations. © 1998 John Wiley & Sons, Inc. Microwave Opt Technol Lett 19: 451–455, 1998. [ABSTRACT FROM AUTHOR]

Published

1998

26. Surface micromachined segmented mirrors for adaptive optics.

Author

Cowan, W.D., Lee, M.K., Welsh, B.M., Bright, V.M., and Roggemann, M.C.

Abstract

This paper presents recent results for aberration correction and beam steering experiments using polysilicon surface micromachined piston micromirror arrays. Microfabricated deformable mirrors offer a substantial cost reduction for adaptive optic systems. In addition to the reduced mirror cost, microfabricated mirrors typically require low control voltages (less than 30 V), thus eliminating high-voltage amplifiers. The greatly reduced cost per channel of adaptive optic systems employing microfabricated deformable mirrors promise high-order aberration correction at low cost. Arrays of piston micromirrors with 128 active elements were tested. Mirror elements are on a 203-μm 12×12 square grid (with 16 inactive elements, four in each corner of the array). The overall array size is 2.4 mm square. The arrays were fabricated in a commercially available surface micromachining process. The cost per mirror array in this prototyping process is less than $200. Experimental results are presented for a hybrid correcting element comprised of a lenslet array and piston micromirror array, and for a piston micromirror array only. Also presented is a novel digital deflection micromirror that requires no digital to analog converters, further reducing the cost of adaptive optics systems [ABSTRACT FROM PUBLISHER]

Published

1999

27. Optical design of a high-resolution spectrometer with a wide field of view.

Author

Zeng, Chaobin, Han, Yan, Liu, Bin, Sun, Peng, Li, XianJing, and Chen, Ping

Subjects

*SPECTROMETERS, *SPECTRAL imaging

Abstract

• This optical system is a new type of integrated field of view imaging spectrometer. • The structure can simultaneously obtain high resolution with a wide field of view. • This new structure has the characteristics of simple structure, easy debugging. The currently available area array imaging spectrometer fails to provide high spectral resolution and fast imaging under a wide field of view (FOV). Therefore, this study proposes an integral field imaging spectrometer (IFIS) that uses an image-space telecentric lens (ISTL), a mask, and lenslet array (MLA) as the front structure of the system. The influence of their structural parameters on the optical performance of the system is analyzed by establishing ISTL and MLA models. We selected suitable structural parameters to establish the imaging spectrometer, and provided an experimental demonstration of the system. Our system can achieve a 1.6 nm spectral resolution in a wide FOV of 48.8°. Compared with other spectrometer designs, our system is characterized by a simple structure, wider FOV, and higher spectral resolution. [ABSTRACT FROM AUTHOR]

Published

2021

28. Light field image compression based on quality aware pseudo‐temporal sequence.

Author

Liu, Yu Yang, Zhu, Ce, and Mao, Min

Abstract

Currently, a raw light field image can be captured by a light field camera and decomposed into multi‐views with different perceptual quality. A novel light field compression approach for a light field image is proposed based on this observation, where the raw light field image is decomposed into multi‐views as pseudo‐sequencing frames and reordered according to their perceptual quality. The resulting pseudo‐temporal sequence is then compressed by high‐efficiency video coding (HEVC) encoder. Experimental results show that the proposed method can achieve a better coding performance (up to 28% Bjontegaard delta bit rate reduction (BDBR) savings) compared with state‐of‐the‐art reordering techniques using HEVC. [ABSTRACT FROM AUTHOR]

Published

2018