Your search keyword '"HOLOGRAPHIC interferometry"' showing total 8,820 results

1. Holographic Beam Measurements of the Canadian Hydrogen Intensity Mapping Experiment (CHIME).

Author

Amiri, Mandana, Chakraborty, Arnab, Foreman, Simon, Halpern, Mark, Hill, Alex S, Hinshaw, Gary, Landecker, T. L., MacEachern, Joshua, Masui, Kiyoshi W., Mena-Parra, Juan, Milutinovic, Nikola, Newburgh, Laura, Ordog, Anna, Pen, Ue-Li, Pinsonneault-Marotte, Tristan, Reda, Alex, Siegel, Seth R., Singh, Saurabh, Wang, Haochen, and Wulf, Dallas

Subjects

*HOLOGRAPHIC interferometry, *CROSS correlation, *OSCILLATIONS, *CALIBRATION, *HYDROGEN

Abstract

We present the first results of the holographic beam-mapping program for the Canadian Hydrogen Intensity Mapping Experiment (CHIME). We describe the implementation of a holographic technique as adapted for CHIME, and introduce the processing pipeline which prepares the raw holographic timestreams for analysis of beam features. We use data from six bright sources across the full 400–800 MHz observing band of CHIME to provide measurements of the copolar and cross-polar beam response in both amplitude and phase for all 1024 dual-polarized feeds in the array. In addition, we present comparisons with independent probes of the CHIME beam, which indicate the presence of polarized beam leakage. Holographic measurements of the beam have already been applied in science with CHIME, e.g., in estimating the detection significance of far-sidelobe fast radio bursts, and in validating the beam models used for CHIME's first detections of 21 cm emission (in cross-correlation with measurements of large-scale structure from galaxy surveys and the Ly α forest). Measurements presented in this paper, and future holographic results, will provide a unique data set to characterize the CHIME beam and improve the experiment's prospects for a detection of the baryon acoustic oscillation signal. [ABSTRACT FROM AUTHOR]

Published

2024

2. A Review: Phase Measurement Techniques Based on Metasurfaces.

Author

Zhao, Zhicheng, Hu, Yueqiang, and Chen, Shanyong

Subjects

LIGHT propagation, OPTICAL elements, TRANSPORT equation, PHOTOMETRY, INTERFEROMETRY, HOLOGRAPHIC interferometry

Abstract

Phase carries crucial information about the light propagation process, and the visualization and quantitative measurement of phase have important applications, ranging from ultra-precision metrology to biomedical imaging. Traditional phase measurement techniques typically require large and complex optical systems, limiting their applicability in various scenarios. Optical metasurfaces, as flat optical elements, offer a novel approach to phase measurement by manipulating light at the nanoscale through light-matter interactions. Metasurfaces are advantageous due to their lightweight, multifunctional, and easy-to-integrate nature, providing new possibilities for simplifying traditional phase measurement methods. This review categorizes phase measurement techniques into quantitative and non-quantitative methods and reviews the advancements in metasurface-based phase measurement technologies. Detailed discussions are provided on several methods, including vortex phase contrast, holographic interferometry, shearing interferometry, the Transport of Intensity Equation (TIE), and wavefront sensing. The advantages and limitations of metasurfaces in phase measurement are highlighted, and future research directions are explored. [ABSTRACT FROM AUTHOR]

Published

2024

3. Heterodyne background-oriented schlieren for the measurement of thermoacoustic oscillations in flames.

Author

Tasmany, Sami, Kaiser, Daniel, Woisetschläger, Jakob, Gürtler, Johannes, Kuschmierz, Robert, and Czarske, Jürgen

Subjects

*DIFFRACTION patterns, *COMBUSTION chambers, *AIRPLANE motors, *OSCILLATIONS, *FLAME, *HOLOGRAPHIC interferometry

Abstract

In aircraft engines, thermoacoustic oscillations in the combustion chamber contribute significantly to noise emissions, which, like all other emissions, must be drastically reduced. Thermoacoustic oscillations are not only a concern, they can also be beneficial in hydrogen combustion. This work demonstrates that thermoacoustic density oscillations with amplitudes at least an order of magnitude smaller than those resulting from density gradients in a turbulent flame can be detected using laser interferometric vibrometry. This improvement was made possible by heterodyning a carrier fringe system in background-oriented schlieren (BOS) recordings, which were subsequently analyzed using techniques commonly used for holographic interferometry. In comparison with other BOS evaluation techniques, the filtering of the individual frames in the Fourier domain offers a more efficient computational approach, as it allows for phase averaging of a high number of single recordings to reduce noise from turbulence. To address fringe pattern distortions and cross talk in the Fourier domain, which both have been observed by other authors, we propose background subtraction methods and an optimized background pattern. Additionally, the procedure provides a visualization tool for marking the high turbulence regions of heat release by the variations in fringe amplitude. Finally, the line-of-sight data are reconstructed using the inverse Abel transform, with the data calibrated by laser interferometric techniques, resulting in local values for density oscillations. [ABSTRACT FROM AUTHOR]

Published

2024

4. Experimental study of thermoconcentration convection in air–water and air–undecane mixtures.

Author

Somov, Sergey A. and Ivanov, Aleksey S.

Subjects

*NUSSELT number, *RAYLEIGH number, *HOLOGRAPHIC interferometry, *HEAT exchangers, *PHASE transitions

Abstract

A quantitative experimental comparison was conducted between thermal convection in dry air and thermoconcentration convection in two gas mixtures: air–water vapor and air–undecane vapor, within the temperature range of 0–80 ° C at normal atmospheric pressure. Convection in these mixtures is driven by temperature and concentration gradients of water (or undecane) vapor in the air. The stationary thermoconcentration convection is accompanied by continuous phase transitions of the fluids. The quantitative results of the experiments are represented in terms of the Nusselt number Nu and the effective Rayleigh number R a E , which is the sum of the thermal R a T and concentration R a C Rayleigh numbers. Quantitative laboratory measurements were performed using the thermocouple method and were supplemented with qualitative data from visual monitoring of transparent fluid flows using holographic interferometry. The cubic and quadratic temperature dependencies of R a C R a T − 1 were determined experimentally for moist air and for the air–undecane vapor mixture, respectively. The significant role of moisture phase transitions in air convection is established. Neglecting these effects at 25 ° C and using the ordinary R a T instead of actual R a E would result in an error exceeding 30%. At 38 ° C, this error would increase to nearly 100%. At around 80 ° C, thermoconcentration convection becomes almost entirely concentration-driven, as the high molecular disordered thermal motion is suppressed by the ordered convective motion generated by evaporation and condensation of water on the opposite heat exchangers of the convective cell. [ABSTRACT FROM AUTHOR]

Published

2024

5. Comparative studies of diffusion coefficients of sucrose, lactose, and fructose using double exposure digital holographic interferometry (DEDHI) technique.

Author

Chikode, P. P., Patil, S. D., Nikam, G. H., Mahajan, S. S., Kamble, R. J., Banne, S. K., and Vhatkar, R. S.

Subjects

*HOLOGRAPHIC interferometry, *SUCROSE, *FRUCTOSE, *DIFFUSION coefficients, *DISTILLED water

Abstract

This research paper presents a comprehensive comparative analysis of sucrose, fructose, and lactose diffusion behaviors in pure distilled water at ambient temperature using the double-exposure digital holographic interferometry (DEDHI) technique. Diffusion coefficients of these common sugars were determined with high precision, revealing insights into their respective transport properties using digital interferograms. The non-invasive and label-free nature of digital holographic interferometry allows for real-time monitoring of diffusion processes, providing valuable data for applications in food science, pharmaceuticals, and biotechnology. The double-exposure digital interferograms were recorded for 0.6 N solutions with pure distilled water from 11000 s to 14700 s on a CCD chip and processed with numerical H-digital reconstruction software. It is observed that the average values of diffusion coefficient (D) of sucrose, lactose and fructose with pure distilled water are slightly different. They are increasing from lactose, sucrose, and fructose respectively 3.710 to 6.854 × 10-6 cm2 / s. The average D value of fructose solution is greater than lactose and sucrose, it is 6.854 × 10-6cm2 / s. The results offer a deeper understanding of sugar diffusion phenomena and underscore the versatility of the holographic approach. [ABSTRACT FROM AUTHOR]

Published

2024

6. Temperature fields in liquids: A comparison of CFD simulations with Digital Holographic Interferometry and thermocouples.

Author

Çubreli, Gramoz, Elbarghthi, Anas F.A., Dančová, Petra, and Kouta, Ahmad

Subjects

*COMPUTATIONAL fluid dynamics, *HOLOGRAPHIC interferometry, *THERMOCOUPLES, *TEMPERATURE effect, *OPTICAL measurements

Abstract

This paper presents temperature estimations via two simple CFD simulations of a dynamic phenomenon in a transparent tank (cylindrical heater rod submerged into water in a glass tank) with ANSYS Fluent and comparison with the optical measurement results obtained via the Digital Holographic Interferometry (DHI) method and thermocouples. Our CFD simulations predict temperature values in good agreement (within 5% error limit) compared to thermocouples and DHI. Furthermore, the great advantages of DHI technique for such kind of reliable, fast, in time, accurate and contactless measurements were highlighted. Data validations of our simulations could lead to further investigations through the CFD simulating technique for a wide range of applications. [ABSTRACT FROM AUTHOR]

Published

2024

7. Holographic thermal mapping in volumes using acoustic lenses.

Author

Cengiz, Ceren and Shahab, Shima

Subjects

*VOLUMETRIC analysis, *ACOUSTIC radiators, *INTERNAL friction, *HOLOGRAPHIC interferometry, *TEMPERATURE control, *PRESSURE measurement, *INVERSE problems

Abstract

Acoustic holographic lenses (AHLs) show great potential as a straightforward, inexpensive, and reliable method of sound manipulation. These lenses store the phase and amplitude profile of the desired wavefront when illuminated by a single acoustic source to reconstruct ultrasound pressure fields, induce localized heating, and achieve temporal and spatial thermal effects in acousto-thermal materials like polymers. The ultrasonic energy is transmitted and focused by AHL from a transducer into a particular focal volume. It is then converted to heat by internal friction in the polymer chains, causing the temperature of the polymer to rise at the focus locations while having little to no effect elsewhere. This one-of-a-kind capability is made possible by the development of AHLs to make use of the translation of attenuated pressure fields into programmable heat patterns. However, the impact of acousto-thermal dynamics on the generation of AHLs is largely unexplored. We use a machine learning-assisted single inverse problem approach for rapid and efficient AHLs' design to generate thermal patterns. The process involves the conversion of thermal information into a holographic representation through the utilization of two latent functions: pressure phase and amplitude. Experimental verification is performed for pressure and thermal measurements. The volumetric acousto-thermal analyses of experimental samples are performed to offer a knowledge of the obtained pattern dynamics, as well as the applicability of holographic thermal mapping for precise volumetric temperature control. Finally, the proposed framework aims to provide a solid foundation for volumetric analysis of acousto-thermal patterns within thick samples and for assessing thermal changes with outer surface measurements. [ABSTRACT FROM AUTHOR]

Published

2024

8. The Application of Digital Holographic Speckle Pattern Interferometry to the Structural Condition Study of a Plaster Sample.

Author

Kosma, Kyriaki and Tornari, Vivi

Subjects

DIFFRACTION patterns, SPECKLE interferometry, INFRARED radiation, NONDESTRUCTIVE testing, HEAT radiation & absorption, HOLOGRAPHIC interferometry, SPECKLE interference

Abstract

We use non-destructive Digital Holographic Speckle Pattern Interferometry (DHSPI), post-processing image analysis and one-dimensional exponential analysis to visualize, map and describe the structural condition of a plaster-based material. The body is heated by infrared radiation for two different time windows and the cooling process that follows is monitored in time by the so-called interferograms that are developed and are the result of the superposition of the holographic recordings of the sample prior to the thermal load and at variable time intervals during the cooling process. The fringe patterns in the interferometric images reveal features and characteristics of the interior of the material, with the experimental method and the post-process analysis adopted in this work offering accuracy, sensitivity and full-field diagnosis, in a completely non-destructive manner, without the need of sampling. [ABSTRACT FROM AUTHOR]

Published

2024

9. Digital Holographic Interferometry for Micro-Deformation Analysis of Morpho Butterfly Wing.

Author

Mardan Dezfouli, Ali, Demoli, Nazif, Abramović, Denis, Rakić, Mario, and Skenderović, Hrvoje

Subjects

NUMERICAL analysis, BUTTERFLIES, LASERS, HOLOGRAPHIC interferometry, LIGHTING

Abstract

In this study, we present an analysis of deflections in a Morpho butterfly wing using digital holographic interferometry (DHI). Our methodology revolves around an off-axis lensless Fourier holographic setup, using laser excitation to induce deflections in the object. The implementation of a DHI setup, tailored for rapid monitoring of micro-deformation, is a central aspect of our research. We offer an overview of the theoretical foundations of this technique, complemented by both experimental and numerical results aimed at validating our findings. We designed an optical setup that enhanced both laser illumination and hologram reconstruction for the sample. The experimental findings decisively show that the proposed method is effective for rapid deformation analysis. The deformation of the wing can be measured with micro-meter accuracy thanks to numerical analysis. [ABSTRACT FROM AUTHOR]

Published

2024

10. High‐Quality Micropattern Printing by Complex‐Amplitude Modulation Holographic Femtosecond Laser.

Author

Li, Taoyong, Jiang, Lan, Wang, Zhipeng, Yi, Peng, Li, Min, Zhang, Leyi, Li, Xibiao, Li, Luqi, Huang, Lingling, Wang, Zhi, Zhang, Xiangyu, Wang, Andong, Li, Jiafang, and Li, Xiaowei

Subjects

*SPECKLE interference, *LASER printing, *PHASE modulation, *AMPLITUDE modulation, *ENERGY density, *HOLOGRAPHIC interferometry, *FEMTOSECOND lasers

Abstract

Holographic femtosecond laser printing technology is widely used in the fabrication of micropatterns because of its high efficiency and flexibility. However, speckle noise and energy fluctuations limit the quality of the printed structure. In this study, an improved complex‐amplitude modulation holographic femtosecond laser printing method for high‐quality micropattern fabrication is proposed. The holographic light field is divided into a signal area and a surrounding noise area. To improve laser uniformity, phase modulation is applied in the signal region to eliminate the speckle noise caused by unconstrained phase interference, and weighted amplitude modulation is introduced in the signal area to improve the calculation accuracy. To precisely control laser energy density, weighted energy efficiency modulation is introduced in the noise region to disperse the energy that exceeds the material damage threshold. Under the synergistic control of laser uniformity and energy density, high‐quality micro‐pattern structures are printed efficiently. A high‐quality millimeter‐sized multifocal zone plate with micron accuracy is fabricated with the splicing printing method, demonstrating the potential of micropattern processing and the fabrication of functional devices such as binary optics. [ABSTRACT FROM AUTHOR]

Published

2024

11. Lensless multi-spectral holographic interferometry for optical inspection.

Author

Agour, Mostafa, Thiemicke, Fabian, Müller, André F., Bergmann, Ralf B., and Falldorf, Claas

Subjects

INTERFEROMETRY, TUNABLE lasers, SEMICONDUCTOR manufacturing, VIBRATION (Mechanics), HOLOGRAPHIC interferometry, HOLOGRAPHY, SHAPE measurement

Abstract

We explore the principles, implementation details, and performance characteristics of a lensless multi-spectral digital holographic sensor and demonstrate its potential for quality assurance in semiconductor manufacturing. The method is based on capturing multi-spectral digital holograms, which are subsequently utilized to evaluate the shape of a reflective test object. It allows for a compact setup satisfying high demands regarding robustness against mechanical vibrations and thus overcomes limitations associated with conventional optical inspection setups associated with lens-based white light interferometry. Additionally, the tunable laser source enhances the versatility of the system and enables adaptation to various sample characteristics. Experimental results based on a wafer test specimen demonstrate the effectiveness of the method. The axial resolution of the sensor is ± 2.5 nm, corresponding to 1σ. [ABSTRACT FROM AUTHOR]

Published

2024

12. Detection and characterization of defects in the Brancacci Chapel wall paintings via holographic interferometry and microwave reflectometry.

Author

Rocco, Alessandra, Bertasa, Moira, Chaban, Antonina, Sarno, Valentina Di, Fontana, Raffaella, Grifoni, Emanuela, Impallaria, Anna, Striova, Jana, Penoni, Sara, and Riminesi, Cristiano

Subjects

*MICROWAVE reflectometry, *HOLOGRAPHIC interferometry, *CONSERVATION & restoration, *CLINICAL pathology, *PRESERVATION of painting, *FRESCO painting, *MURAL art

Abstract

• Combined microwave/optic approach for detection and characterization of detachments of wall paintings. • Risk falling assessment of the detachments and their classification in "stable", "almost-stable" and "unstable". • Reconstruction of wall painting stratigraphy by non-destructive techniques. • Proof of concept of the proposed tool on the wall paintings masterpiece of Masolino, Masaccio and Filippino Lippi in the Brancacci chapel in Florence, with the support of laboratory tests on proper mock-ups. This paper evaluates the improvements in wall paintings diagnostic achievable by the synergistic combination of DHSPI, SIRT and MWR techniques. These innovative portable and non-destructive techniques for in-situ diagnostic were tested in laboratory on mock-ups mimicking the real conditions of wall painting defects (such as detachments, cavities and cracks), and on the frescoes painted by Masolino, Masaccio and Filippino Lippi (between 1422 and 1475) in the Brancacci Chapel in the church of Santa Maria del Carmine in Florence, Italy. This research activity was part of the Brancacci Chapel diagnostic and monitoring project, where the assessment of the state of conservation is a mandatory prerequisite for planning the subsequent restoration work. In common practice, restorers make the preliminary evaluation on the state of conservation of the wall paintings by visual and tactile inspection, without the use of any special scientific instrumentation. Cracks, cavities, lack of material, detachments, out-of-plumb and deformation of (non-)structural elements are reported in a condition report to document the state of conservation at a given point in time. In particular, the detachments are recognized by the tap test, but this is a discretionary and highly subjective method. Thus, there is a strong demand for the development of a portable and non-destructive approach that refines this preliminary survey with objective data. Here, we present the results produced by the combination of MWR (useful for the dimensional characterization of hidden defects in the wall) and DHSPI-SIRT to identify the extent of deformations induced by thermal stimulus, providing an objective confirmation of the preliminary investigation performed by restorers, in which the detachments were indicated as "stable", "not very stable" and "unstable", i.e. , close to falling. The integrated use of these techniques in situ , supported by a laboratory study on ad-hoc prepared mock-ups, proved to be suitable for a quantitative evaluation of damage risk to guide restoration strategy accordingly. [ABSTRACT FROM AUTHOR]

Published

2024

13. Design of Holographic Condenser Lens for Visible Light Lithography.

Author

Yadav, Shweta, Sinha, Rashmi, Deo, Nirmalendu, and Nath, Vijay

Subjects

*VISIBLE spectra, *LITHOGRAPHY, *HOLOGRAPHY, *REFRACTIVE index, *PHOTOLITHOGRAPHY, *HOLOGRAPHIC interferometry, *RESEARCH personnel

Abstract

Photolithography with visible light at λ = 405 nm utilizing the concept of nonlinear saturable absorption effect where the size of the spot is diminished to the nanometer scale as proposed by several researchers is an alluring proposition for cost-effective projection lithography. Costly conventional condenser lenses can be replaced by monochromatic aberration-free and cost-effective volume phase holographic lenses for visible light photolithography with enhanced resolution utilizing the concept of off-axis illumination. However, the diffraction efficiency of holographic lenses depends on the wavelength of illuminating light and the angle of illumination. Angular and spectral characteristics of volume phase holograms can be controlled by optimizing processing parameters. The results on the theoretical optimization of three important processing parameters, namely fringe spacing ( $ \wedge $ ∧), thickness of the film ( $ d $ d), and refractive index modulation ( $ \Delta n $ Δn) in the light of coupled wave theory for recording holographic lenses of high diffraction efficiency at $ \lambda = 405 \,\textrm{nm} $ λ=405nm are presented. It is pointed out that a properly designed single holographic lens can be used for off-axis illumination of a photomask with a parallel beam of light, whereas a system of two identical holographic lenses cemented together has to be used to realize a condenser lens similar to a converging lens. [ABSTRACT FROM AUTHOR]

Published

2024

14. Camera-based ultrasound-modulated optical tomography with isometric resolution.

Author

Lin, Guangzhong, Wu, Daixuan, Zhao, Jiayu, Xu, Yiyun, Shen, Yuecheng, and Shao, Lijie

Subjects

*OPTICAL tomography, *LIGHT absorption, *IMAGING systems, *OPTICAL images, *PROOF of concept, *HOLOGRAPHIC interferometry

Abstract

Ultrasound-modulated optical tomography (UOT) leverages the strengths of light and sound, enabling deep-tissue imaging with optical absorption contrast and acoustic resolution. Camera-based UOT, with its parallel detection capability, excels at handling weak light–sound interactions. However, the limited frame rate of the camera typically results in poor axial resolution and poses challenges for holographic measurements. In this study, we introduced intersected ultrasonic modulation to address these limitations, thereby achieving equal resolution in both lateral and axial dimensions through referenceless measurements. As a proof of concept, we constructed an imaging system and demonstrated two-dimensional imaging for absorptive targets buried inside a scattering medium. This approach opens avenues for improved imaging resolutions, showcasing the potential for future diagnostic endeavors. [ABSTRACT FROM AUTHOR]

Published

2024

15. Effect of Near Ultraviolet Radiation on Varroa Destructor Using Digital Holographic Interferometry.

Author

Silva-Acosta, José Luis, Saucedo-Anaya, Tonatiuh, Mendoza-Santoyo, Fernando, Hernández-Montes, María Del Socorro, Guerrero-Mendez, Carlos, Gaytán-Saldaña, Daniel, and Saucedo-Orozco, Bruno

Subjects

VARROA destructor, ULTRAVIOLET radiation, HOLOGRAPHIC interferometry, BEE colonies, RADIATION damage, MITES

Abstract

The incessant threat posed by the Varroa destructor mite to bee colonies has spurred extensive research into control strategies. One of these strategies involves ultraviolet radiation, aiming to harness the damaging effects that this type of radiation induces in arthropods. This study focuses on investigating the potential influence of near ultraviolet (UVA) radiation on the surface damage incurred by Varroa destructor. To address this inquiry, multiple specimens were continuously irradiated with UVA while digital holograms were recorded. To assess surface damage, these holographic records were processed and analyzed. It was found that exposure to radiation induces subtle swelling, around a few tenths of micrometers, which is more pronounced around the anal shield and genital shield of the mite. These alterations could impact the health and viability of this parasitic mite. This is the first time that the measurement and quantification of this superficial damage is reported, contributing to the understanding of the impact of UVA irradiation on the external structure of the mite. [ABSTRACT FROM AUTHOR]

Published

2024

16. High-resolution imaging for in-situ non-destructive testing by quantitative lensless digital holography.

Author

Ruiz-Cadalso, Daniel and Furlong, Cosme

Subjects

HOLOGRAPHY, ACOUSTIC vibrations, PHENOMENOLOGICAL theory (Physics), HOLOGRAPHIC interferometry, NONDESTRUCTIVE testing, QUALITY control, REAL-time control

Abstract

Quantitative imaging technologies for in-situ non-destructive testing (NDT) demand high-resolution, wide-field, and stable metrology capabilities. Moreover, live processing and automation are vital for real-time quality control and inspection. Conventional methods use complex optical setups, resulting in large, immobile systems which can solely operate within controlled environmental conditions due to temporal instabilities, rendering them unsuitable for in-situ measurements of micro-to nano-scale physical phenomena. This article delves into the multiphysics application of lensless digital holography, emphasizing its metrological capacity for various in-situ scenarios, while acknowledging and characterizing the differing constraints imposed by various physical phenomena, both transient and steady-state. The digital reconstruction of holograms is computed in real-time, and numerical focusing capabilities allow for instantaneous retrieval of the optical phase at various working distances without the need of complex optical setups, making lensless digital holography well-suited for in-situ quantitative imaging under various types of environments. Current NDT capabilities are demonstrated, including high-resolution and real-time reconstructions, simultaneous measurements for comparative metrology, and practical applications ranging from vibrations and acoustics to thermo-mechanics. Furthermore, methodologies to enhance overall metrology capabilities are exploited, addressing the study of existing physical phenomena, thereby expanding the applicability of holographic techniques across diverse industrial sectors. [ABSTRACT FROM AUTHOR]

Published

2024

17. The Formation of 2D Holograms of a Noise Source and Bearing Estimation by a Vector Scalar Receiver in the High-Frequency Band.

Author

Pereselkov, Sergey, Kuz'kin, Venedikt, Ehrhardt, Matthias, Matvienko, Yurii, Tkachenko, Sergey, and Rybyanets, Pavel

Subjects

SOUND pressure, NOISE, WATER depth, ANGULAR distribution (Nuclear physics), HOLOGRAPHY, EXTREME value theory, HOLOGRAPHIC interferometry

Abstract

The holographic signal-processing method for a single vector scalar receiver (VSR) in the high-frequency band in shallow water is developed in the paper. The aim of this paper is to present the results of the theoretical analysis, numerical modeling, and experimental verification of holographic signal processing for a noise source by the VSR. The developed method is based on the formation of the 2D interferogram and 2D hologram of a noise source in a shallow-water waveguide. The 2D interferograms and 2D holograms for different channels of the VSR (P sound pressure and V X and V Y vibration velocity components) are considered. It is shown that the 2D interferogram consists of parallel interference fingers in the presence of a moving noise source. As a result, the 2D hologram contains focal points located on a straight line, and the angular distribution of the holograms has the main extreme value. It is shown in the paper that the holographic signal-processing method allows detecting the source, estimating the source bearing, and filtering the useful signal from the noise. The results of the source detection, source bearing estimation, and noise filtering are presented within the framework of experimental data processing and numerical modeling. [ABSTRACT FROM AUTHOR]

Published

2024

18. Conceptual Project for Diagnostics of Erosion of the First Wall and Divertor of the Tokamak with Reactor Technologies TRT.

Author

Razdobarin, A. G., Shubin, Ya. R., Belokur, A. A., Bogachev, D. L., Elets, D. I., Medvedev, O. S., Mukhin, E. E., Snigirev, L. A., and Alekseenko, I. V.

Subjects

*FUSION reactor divertors, *HOLOGRAPHIC interferometry, *TOKAMAKS, *OPTICAL radar, *LASER interferometry, *LASER beams, *DIAGNOSTIC equipment

Abstract

A conceptual design for diagnosing erosion of the first wall and divertor plates of a tokamak with reactor technologies TRT is proposed. The principles of constructing a diagnostic complex based on the following systems are developed: laser radar, dual-wavelength digital holographic interferometry and active laser IR thermography. An optical scheme is developed for combining the optical paths to input laser radiation and collect scattered light from diagnostic systems. To view the maximum area of the first wall, a scheme for optical scanning of the surface of the first wall and divertor is proposed. Based on optical simulation, the spatial distribution of the power density and phase of interferometry laser radiation in the illuminated region of the first wall is constructed, and the dimensions of the light fields and power density for IR thermography and laser radar diagnostics are determined. An image formation scheme is proposed and the spatial resolution is determined for interferometry and IR thermography methods. The light scattering function on models of the ITER divertor cladding is studied experimentally. The energy of the collected signal is calculated on the basis on the experimental data for all three diagnostic methods and the requirements for the diagnostic equipment are formulated. [ABSTRACT FROM AUTHOR]

Published

2024

19. Real-time pollen identification using holographic imaging and fluorescence measurements.

Author

Erb, Sophie, Graf, Elias, Zeder, Yanick, Lionetti, Simone, Berne, Alexis, Clot, Bernard, Lieberherr, Gian, Tummon, Fiona, Wullschleger, Pascal, and Crouzy, Benoît

Subjects

*HOLOGRAPHY, *POLLEN, *HOLOGRAPHIC interferometry, *FLUORESCENCE, *PALYNOLOGY, *FLUORESCENCE spectroscopy, *RESPIRATORY allergy

Abstract

Over the past few years, a diverse range of automatic real-time instruments has been developed to respond to the needs of end users in terms of information about atmospheric bioaerosols. One of them, the SwisensPoleno Jupiter, is an airflow cytometer used for operational automatic bioaerosol monitoring. The instrument records holographic images and fluorescence information for single aerosol particles, which can be used for identification of several aerosol types, in particular different pollen taxa. To improve the pollen identification algorithm applied to the SwisensPoleno Jupiter and currently based only on the holography data, we explore the impact of merging fluorescence spectra measurements with holographic images. We demonstrate, using measurements of aerosolised pollen, that combining information from these two sources results in a considerable improvement in the classification performance compared to using only a single source (balanced accuracy of 0.992 vs. 0.968 and 0.878). This increase in performance can be ascribed to the fact that often classes which are difficult to resolve using holography alone can be well identified using fluorescence and vice versa. We also present a detailed statistical analysis of the features of the pollen grains that are measured and provide a robust, physically based insight into the algorithm's identification process. The results are expected to have a direct impact on operational pollen identification models, particularly improving the recognition of taxa responsible for respiratory allergies. [ABSTRACT FROM AUTHOR]

Published

2024

20. Features of Application of Adaptive Interferometric Fiber Optic Sensors of Acoustic Emission to Monitor the Condition of Polymer Composite Materials.

Author

Romashko, R. V., Bashkov, O. V., Efimov, T. A., Bezruk, M. N., Bobruyko, D. A., and Makarova, N. V.

Subjects

*OPTICAL fiber detectors, *COMPOSITE materials, *ACOUSTIC emission, *HOLOGRAPHIC interferometry, *MECHANICAL loads, *FAULT tolerance (Engineering), *POLYMER structure, *AUTOMATIC speech recognition

Abstract

The results of an experimental study of the operation of fiber optic sensors (FOS) of acoustic emission introduced into the structure of polymer composite materials (PCM) are presented. The reliability and fault tolerance of FOS under critical mechanical loads on PCM was assessed, and the influence of the presence of FOS embedded into the structure of PCM on the mechanical characteristics of the material was investigated. For demodulation of FOS output signals, the principles of adaptive holographic interferometry based on two-wave mixing at dynamic hologram formed in a photorefractive crystal are used. [ABSTRACT FROM AUTHOR]

Published

2024

21. Holographic interferometer sensitivity estimation in optical measurements.

Author

Prygunov, A. G., Kornev, A. S., and Lazarenko, S. V.

Subjects

*HOLOGRAPHIC interferometry, *OPTICAL measurements, *INTERFEROMETERS, *COHERENCE (Optics), *LIGHT sources, *OPTICAL interferometers, *DRONE aircraft

Abstract

Interferometers used for high-precision spectroscopic measurements are considered. The choice of a holographic interferometer is supported because of it implements the spatial-spectral method of holographic interferometry. With this holographic interferometer one can measure in real time the displacements of the phase center of a coherent light flux over a wide dynamic range and record the measured data in digital form. Based on the mathematical relations elucidated by the authors in previous publications, and based on the results of experimental studies, we have been able to numerically estimate the sensitivity of a holographic interferometer to spatial movements of phase centers (focus points) of light fluxes—point light sources that form a holographic interferogram. We establish the dependence of the normalized level of light flux intensity in the central region of the holographic interferogram on the displacement of a real point light source along the normal to the plane of the Fourier hologram. From the results of mathematical simulation we show that the sensitivity of a holographic interferometer to the movements of a real point light source normal to the plane of the Fourier hologram depends on the optical circuit parameters of the holographic interferometer when exposing the hologram and on the measurement parameters. In this case, the sensitivity of a holographic interferometer to specific movements of a real point light source can only be estimated experimentally. We propose to increase the sensitivity of a holographic interferometer by using a thin converging lens in its optical design. A mathematical relation has been obtained and studied for the gain coefficient of the phase advance of a light flux with a spherical wavefront. Given the known parameters of the thin converging lens in the optical circuit, we can use this relationship to numerically estimate the increase in sensitivity of a holographic interferometer that implements the spatial-spectral method of holographic interferometry. It is shown that the sensitivity of the holographic interferometer to the displacement of an imaginary point light source normal to the plane of the Fourier hologram is 2.86 times greater than its sensitivity to the same movement of a real point light source. It has been established that the sensitivity of holographic interferometer with a volumetric Fourier hologram and a thin converging lens in its design can be increased by no less than an order of magnitude compared with the sensitivity of known optical interferometers. The results of assessing the sensitivity of the holographic interferometer implementing the spatial-spectral method of holographic interferometry to displacement of point sources of real and imaginary light fluxes, as well as the resulting ratio for the gain coefficient of the phase advance of the light flux by the thin converging lens, will be useful for high-precision measurements of linear and angular movement of objects, as well as in the construction of photonic device structures. From the results of the study based on the holographic interferometer, an experimental sample of an acousto-electric transducer has been developed and manufactured, which has high sensitivity over wide dynamic and frequency ranges and is intended for use in acoustic locations of unmanned aerial vehicles. [ABSTRACT FROM AUTHOR]

Published

2024

22. Imaging Convective Phenomena inside Highly Refractive Cylindrical Enclosures.

Author

Sinha, Gulshan Kumar, Utadiya, Subhash K., Patel, Arjun, Narayan, Surya, Anand, Arun, and Srivastava, Atul

Subjects

*HOLOGRAPHIC interferometry, *RAYLEIGH number, *HEAT transfer coefficient, *NATURAL heat convection, *HEAT transfer, *TEMPERATURE distribution, *FOURIER transforms

Abstract

The conventional refractive index-based optical techniques show limitations in measuring the thermal field inside refractive surfaces due to the curvature effects. The present work reports on the application of lensless Fourier transform digital holographic interferometry for mapping heat transfer phenomena inside highly refracting axisymmetric enclosures. Experiments have been performed to characterize the buoyancy-driven natural convection heat transfer around a vertically oriented heated cylinder placed concentrically inside a relatively large cylindrical enclosure filled with de-ionized water. The experiments were performed under various heating conditions, and the corresponding holograms were analyzed in real-time to show the transients of the temperature field. Quantitative results were obtained in the form of a two-dimensional temperature distribution field and local heat transfer coefficients along the heated surface. Experimental results were validated by comparing the values of the surface temperatures obtained from the analysis with that obtained from the thermocouple data. The work presented highlights the ability of the lensless Fourier transform digital holographic technique to map the real-time temperature field inside a highly refracting enclosure. [ABSTRACT FROM AUTHOR]

Published

2024

23. Effect of the displacement field on dynamic domain structures.

Author

Rusinov, A. A. and Rusinova, E. A.

Subjects

*INDUCTIVE effect, *NONDESTRUCTIVE testing, *HOLOGRAPHIC interferometry, *TRANSPORTATION safety measures, *MAGNETIC control, *DISPLACEMENT (Mechanics), *DELAMINATION of composite materials

Abstract

The priority task of the transport complex has always been to ensure the safety of the transportation process. To solve it, cooperation of scientists and specialists in various fields of activity is required. Non-destructive testing is one of the key methods of monitoring the reliability and safety of rolling stock. There are several methods that allow you to detect defects in material or structures without violating the integrity of the objects under study: 1. Phase-contrast method of optical radiation, which is based on the transformation of the phase difference of optical radiation. 2. The magneto-optical method of optical radiation, which is based on an additional effect on the objects of control of the magnetic field; 3. Holographic interferometry is also widely used in non-destructive testing - detection of material or structural defects without violating the integrity of the objects under study. New types of interferometers on zone plates have appeared for controlling the shape of parts, determining straightness and flatness. Typically, the purpose of such studies is to detect the location and size of cracks, voids, non-adhesives, delamination, inhomogeneities in material properties, etc. In this work, we study garnet-ferrite films, in particular, the domain structures of the Leading Center, which can be considered as a zone plate on the basis of which devices for non-destructive testing are created. [ABSTRACT FROM AUTHOR]

Published

2023

24. The Application of Digital Holographic Speckle Pattern Interferometry to the Structural Condition Study of a Plaster Sample

Author

Kyriaki Kosma and Vivi Tornari

Subjects

holographic interferometry, optical metrology, non-destructive testing, Applied optics. Photonics, TA1501-1820

Abstract

We use non-destructive Digital Holographic Speckle Pattern Interferometry (DHSPI), post-processing image analysis and one-dimensional exponential analysis to visualize, map and describe the structural condition of a plaster-based material. The body is heated by infrared radiation for two different time windows and the cooling process that follows is monitored in time by the so-called interferograms that are developed and are the result of the superposition of the holographic recordings of the sample prior to the thermal load and at variable time intervals during the cooling process. The fringe patterns in the interferometric images reveal features and characteristics of the interior of the material, with the experimental method and the post-process analysis adopted in this work offering accuracy, sensitivity and full-field diagnosis, in a completely non-destructive manner, without the need of sampling.

Published

2024

25. Determination of Optimal Directions of the Wave Vector of a Phase Holographic Grating in Cubic Photorefractive Crystal.

Author

Naunyka, V. N.

Subjects

*HOLOGRAPHIC gratings, *PIEZOELECTRICITY, *HOLOGRAPHY, *CRYSTALS, *AMPLITUDE modulation, *HOLOGRAPHIC interferometry, *REFRACTIVE index, *PERMITTIVITY

Abstract

The dependence of the change in the components of the inverse permittivity tensor of a cubic photorefractive Bi12SiO20 crystal on the direction of the wave vector of holographic grating in the crystal coordinate system has been studied. It is shown that, when recording a phase hologram, the largest change in the refractive index of Bi12SiO20 crystal is attained when the holographic grating wave vector is oriented along symmetrically equivalent 〈111〉 directions. The maximum possible modulation amplitude of the refractive index of a holographic grating with the wave vector oriented along the 〈110〉 directions is found to exceed that in the case of orientation along the 〈100〉 directions. The components of the inverse permittivity tensor of Bi12SiO20 crystal were calculated taking into account that a phase hologram is recorded under linear electro-optic, photoelastic, and inverse piezoelectric effects. [ABSTRACT FROM AUTHOR]

Published

2023

26. Flexible Measurement of High-Slope Micro-Nano Structures with Tilted Wave Digital Holographic Microscopy.

Author

Ma, Xinyang, Xiong, Rui, Wang, Wei, and Zhang, Xiangchao

Subjects

*DIGITAL holographic microscopy, *HOLOGRAPHIC interferometry, *MULTISENSOR data fusion, *SURFACE topography, *OPTICAL measurements

Abstract

Digital holographic microscopy is an important measurement method for micro-nano structures. However, when the structured features are of high-slopes, the interference fringes can become too dense to be recognized. Due to the Nyquist's sampling limit, reliable wavefront restoration and phase unwrapping are not feasible. To address this problem, the interference fringes are proposed to be sparsified by tilting the reference wavefronts. A data fusion strategy including region extraction and tilt correction is developed for reconstructing the full-area surface topographies. Experimental results of high-slope elements demonstrate the validity and reliability of the proposed method. [ABSTRACT FROM AUTHOR]

Published

2023

27. Parallel Phase-Shifting Digital Holographic Phase Imaging of Micro-Optical Elements with a Polarization Camera.

Author

Liu, Bingcai, Fang, Xinmeng, Tian, Ailing, Wang, Siqi, Zhang, Ruixuan, Wang, Hongjun, and Zhu, Xueliang

Subjects

HOLOGRAPHY, HOLOGRAPHIC interferometry, DIGITAL holographic microscopy, MEASUREMENT errors, DIGITAL cameras, INTERPOLATION algorithms, SURFACE topography, CAMERAS

Abstract

In this paper, we propose a measurement method of micro-optical elements with parallel phase-shifting digital holographic phase imaging. This method can record four phase-shifting holograms with a phase difference of π/2 in a single shot and correct the pixel mismatch error of the polarization camera using a bilinear interpolation algorithm, thereby producing high-resolution four-step phase-shifting holograms. This method reconstructs the real phase information of the object to be measured through a four-step phase-shifting algorithm. The reproduced image eliminates the interference of zero-order images and conjugate images, overcoming the problem that traditional phase-shifting digital holography cannot be measured in real time. A simulation analysis showed that the relative error of this measurement method could reach 0.0051%. The accurate surface topography information of the object was reconstructed from an experimental measurement through a microlens array. Multiple measurements yielded a mean absolute error and a mean relative error for the vertical height of the microlens array down to 5.9500 nm and 0.0461%, respectively. [ABSTRACT FROM AUTHOR]

Published

2023

28. The Mechanism of Droplet Thermocapillary Migration Coupled with Multi-Physical Fields.

Author

Ye, Zhijun, Chen, Yi, Yang, Chao, Wu, Di, Wang, Jia, Hu, Liang, Duan, Li, and Kang, Qi

Subjects

*PARTICLE image velocimetry, *HOLOGRAPHIC interferometry, *PHYSICAL laws

Abstract

In this paper, the coupling effect of multiphysical fields of droplet migration is deeply studied by constructing a physical model of droplet migration with multiphysical fields. Digital holographic interferometry and particle image velocimetry are used to simultaneously measure the temperature and velocity fields of the mother liquor in the process of droplet migration for the first time. Due to the advancements of measuring, the zero-velocity region is also in the region where the thermal wake appears, four vortexes appear in the droplet migration and the off-axis behavior of double-droplet migration is found. The aim of this work is to analyze the coupling relationship of multiphysical fields, so as to reveal the physical laws of thermocapillary migration of single droplet and multiple droplets with the same phase and heterophase and to study the driving mechanism of the thermocapillary force and the flow of the mother liquor. [ABSTRACT FROM AUTHOR]

Published

2023

29. Peculiarities of Formation of Plasma Structures in Working Mixtures of Electrochemical HF (DF) Lasers and Methods for Their Study.

Author

Kazantsev, S. Y., Pchelkina, N. V., and Smolsky, A. A.

Subjects

*GAS lasers, *ELECTRIC discharges, *LASER plasmas, *PLASMA gases, *GLOW discharges, *PULSED lasers, *HOLOGRAPHIC interferometry, *LASER interferometry

Abstract

The features of the formation of pulsed volume discharge in working mixtures of non-chain wide-aperture HF (DF) lasers are considered. It is shown that the spatial structure of the volume discharge in these lasers is characterized by several spatial dimensions. To register such plasma structures, the Talbot interferometry method is proposed, and a simple experimental setup capable of recording the fine microstructure of plasma channels in the gas discharge plasma of electrochemical lasers, as well as disturbances in the optical density of transparent media, is described. [ABSTRACT FROM AUTHOR]

Published

2023

30. Single-Chip Switchable Dual-Wavelength Vertical External-Cavity Surface-Emitting Laser.

Author

Zhang, Zhuo, Zhang, Jianwei, Du, Ziye, Bai, Haopeng, Zhang, Jiye, Liu, Tianjiao, Zhou, Yinli, Zhang, Xing, Chen, Chao, Qin, Li, Ning, Yongqiang, and Wang, Lijun

Subjects

SURFACE emitting lasers, HOLOGRAPHIC interferometry, QUANTUM wells, LASER beams, SEMICONDUCTOR lasers, FIBER lasers

Abstract

Dual-wavelength output devices have a wide range of applications in mid-infrared band difference frequency generation, anti-interference lidar, dual-wavelength holographic interferometry, and other applications. Vertical external cavity surface-emitting lasers (VECSELs) are a type of semiconductor laser that can achieve single-chip dual-wavelength output by designing the chip structure. In this paper, we present a single-chip VECSEL that can switch between dual-wavelength and single-wavelength output modes. The VECSEL can simultaneously emit coaxial laser beams at 967 nm and 1013 nm, with a wavelength spacing of about 45 nm. The degree of mismatch between the gain peaks of the two quantum wells in the gain chip and the corresponding cavity modes is different. By adjusting the pump power, the temperature of the active region can be changed, which alters the matching relationship between the gain peaks and the cavity modes and controls the output mode of the VECSEL. The dual-wavelength output mode maintains a stable wavelength spacing at different operating temperatures. The laser output mode can be switched between single-wavelength and dual-wavelength, and the beam divergence angle is less than 8°. The dual-wavelength output power can exceed 400 mW, and the long-wavelength output power can reach up to 700 mW. [ABSTRACT FROM AUTHOR]

Published

2023

31. Recent Advances on High‐Speed and Holographic Two‐Photon Direct Laser Writing.

Author

Balena, Antonio, Bianco, Marco, Pisanello, Ferruccio, and De Vittorio, Massimo

Subjects

*LASER beams, *LASERS, *LITHOGRAPHY, *PHYSICAL distribution of goods, *HOLOGRAPHY, *HOLOGRAPHIC interferometry

Abstract

Two‐Photon Lithography, thanks to its very high sub‐diffraction resolution, has become the lithographic technique par excellence in applications requiring small feature sizes and complex 3D pattering. Despite this, the fabrication times required for extended structures remain much longer than those of other competing techniques (UV mask lithography, nanoimprinting, etc.). Its low throughput prevents its wide adoption in industrial applications. To increase it, over the years different solutions have been proposed, although their usage is difficult to generalize and may be limited depending on the specific application. A promising strategy to further increase the throughput of Two‐Photon Lithography, opening a concrete window for its adoption in industry, lies in its combination with holography approaches: in this way it is possible to generate dozens of foci from a single laser beam, thus parallelizing the fabrication of periodic structures, or to engineer the intensity distribution on the writing plane in a complex way, obtaining 3D microstructures with a single exposure. Here, the fundamental concepts behind high‐speed Two‐Photon Lithography and its combination with holography are discussed, and the literary production of recent years that exploits such techniques is reviewed, and contextualized according to the topic covered. [ABSTRACT FROM AUTHOR]

Published

2023

32. Holographic Encryption of Color Video Stream with 4k Resolution Using Phase Liquid Crystal Light Modulators.

Author

Rymov, D. A., Shifrina, A. V., Cheremkhin, P. A., Rodin, V. G., and Krasnov, V. V.

Subjects

*STREAMING video & television, *LIGHT modulators, *LIQUID crystal states, *HOLOGRAPHY, *DIGITAL holographic microscopy, *HOLOGRAPHIC interferometry, *DIGITAL video, *VIDEO coding

Abstract

This study examines the use of optical encoding to prevent unauthorized access to various categories of information (including video) during operational transmission. Experimentally implemented holographic coding in spatially incoherent radiation of a 4K color video stream with digital input of information and dynamically changing coding elements-holograms was used to improve the quality of video stream coding and ensure high throughput of the coding system. High-resolution liquid-crystal spatial-temporal light modulators were used to input encoded video information and display holograms. The encoding method is based on registering an optical convolution of the input scene image with the encoding response of the hologram. In this case, individual color channels of each frame of the video stream are encoded in turn. Numerical methods of inverse filtering and regularization were used for decoding. The results of the present studies will be useful in creating a new generation of secure high-resolution video communication systems. [ABSTRACT FROM AUTHOR]

Published

2023

33. The Flipping-Free Full-Parallax Tabletop Integral Imaging with Enhanced Viewing Angle Based on Space-Multiplexed Voxel Screen and Compound Lens Array.

Author

Peiren Wang, Jinqiang Bi, Zilong Li, Xue Han, Zhengyang Li, and Xiaozheng Wang

Subjects

THREE-dimensional imaging, INTEGRALS, HOLOGRAPHIC interferometry, ANGLES, PARALLAX, DIAGNOSIS

Abstract

Tabletop integral imaging display with a more realistic and immersive experience has always been a hot spot in three-dimensional imaging technology, widely used in biomedical imaging and visualization to enhance medical diagnosis. However, the traditional structural characteristics of integral imaging display inevitably introduce the flipping effect outside the effective viewing angle. Here, a full-parallax tabletop integral imaging display without the flipping effect based on space-multiplexed voxel screen and compound lens array is demonstrated, and two holographic functional screens with different parameters are optically designed and fabricated. To eliminate the flipping effect in the reconstruction process, the space-multiplexed voxel screen consisting of a projector array and the holographic functional screen is presented to constrain light beams passing through the corresponding lens. To greatly promote imaging quality within the viewing area, the aspherical structure of the compound lens is optimized to balance the aberrations. It cooperates with the holographic functional screen to modulate the light field spatial distribution. Compared with the simulation results, the distortion rate of the imaging display is reduced to less than 9% from more than 30%. In the experiment, the floating high-quality reconstructed three-dimensional image without the flipping effect can be observed with the correct 3D perception at 96°×96° viewing angle, where 44,100 viewpoints are employed. [ABSTRACT FROM AUTHOR]

Published

2023

34. Digital holographic interferometry for diagnosing the density profile of laser-produced collisionless shock.

Author

Si, Hua-chong, Tang, Hui-bo, Liu, Wei, Yuan, Peng, and Hu, Guang-yue

Subjects

*HOLOGRAPHIC interferometry, *ELECTRON distribution, *ELECTRON density, *SEPARATION of variables, *DENSITY

Abstract

A digital holographic interferometry based on Fresnel biprism has been developed to measure the electron density profile of laser-produced collisionless shocks in laboratory, which used the Fourier transform method to solve the wrapped phase. The discontinuous surfaces of shocks will produce the break and split of the interference fringes, which cannot be processed by the conventional path-following phase unwrapping algorithm when reconstructing the real phase of the plasma. Therefore, we used a least-squares method to extract the real phase, which is proportional to the line-integrated electron density. We obtained fine density profiles of collisionless shocks in the line-integrated density region around 1018 cm−2 with a density resolution of 3.38 × 1016 cm−2. The shock structure is in well agreement with that measured by the dark-field schlieren methods and that predicted by shock jump condition. Synthetic holograms are used to confirm the effectiveness of our algorithm, and it is shown that correct results can still be obtained even if part of the diagnostic light is refracted out of the optical system by the shock. [ABSTRACT FROM AUTHOR]

Published

2023

35. Nonclassical cosserat bending deformation of foams via holographic interferometry.

Author

Lakes, R. S.

Subjects

*FOAM, *DEFORMATION of surfaces, *DEFORMATIONS (Mechanics), *ELASTIC constants, *HOLOGRAPHIC interferometry, *URETHANE foam, *FOAM cells

Abstract

Nonclassical bending deformation in two foams was investigated using holographic interferometry. Sigmoid bulge deformation of the lateral surface of square cross-sectional bars was observed. Cosserat elastic constants inferred are consistent with values obtained via size effect experiments for dense polyurethane foam. For open cell copper foam, both bulge measurements and size effects implied a large Cosserat characteristic length and a large coupling number. Limitations of the available fourth-order bending analysis were encountered in this regime of strong effects. [ABSTRACT FROM AUTHOR]

Published

2023

36. Special Issue on Intelligent Processing on Image and Optical Information II.

Author

Yeom, Seokwon

Subjects

IMAGE processing, OPTICAL information processing, DIGITAL image correlation, THRESHOLDING algorithms, TEXT recognition, HOLOGRAPHIC interferometry, CONVOLUTIONAL neural networks, PATTERN recognition systems, THREE-dimensional imaging

Abstract

Intelligent image and optical information processing have paved the way for the recent epoch of new intelligence and information. Three-Dimensional Imaging Advances in three-dimensional imaging have enabled the capture and reconstruction of three-dimensional information. This Special Issue focuses on the intelligent processing of images and optical information such as object detection and classification and three-dimensional imaging. [Extracted from the article]

Published

2023

37. Constraining the bounce realization with holographic background and analytical exploration of the consequences in a modified gravity framework.

Author

Ghosh, Moli and Chattopadhyay, Surajit

Subjects

*GRAVITY, *DARK energy, *HOLOGRAPHY, *TAYLOR'S series, *HOLOGRAPHIC interferometry

Abstract

The work reported in this paper explores holographic bounce. In the first phase of the study, we chose a non-singular bouncing scale factor. Then we reconstructed f (T) gravity and analytically derived constraints on the bouncing parameter σ. These constraints helped us understand the scale factor's quintessence or phantom behavior. Furthermore, we also explored the statefinder parameters for reconstructed f (T) and observed the attainment of Λ CDM fixed point. Next, we considered the multiplicative bouncing scale factor inspired by S. D. Odintsov and V. K. Oikonomou Phys. Rev. D 94, (2016) 064022. For this choice, we discussed the types of singularities realizable for different cases. Through the Talyor series expansion, we analytically presented cases and subcases for different ranges of α of the scale factor. In the last phase of the study, we demonstrated holographic bounce with the choice of the multiplicative scale factor. In this case, we considered holographic Ricci dark energy and Barrow holographic dark energy. We concluded that it is possible to generate constraints on the bouncing parameter for its feasibility for the EoS parameter. We concluded that the realization of holographic bounce is possible, and different suitable constraints can be derived for this multiplicative bouncing scale factor focusing on the realization of cosmic bounce. [ABSTRACT FROM AUTHOR]

Published

2023

38. Temperature Sensing in Space and Transparent Media: Advancements in Off-Axis Digital Holography and the Temperature Coefficient of Refractive Index.

Author

Khodadad, Davood, Tayebi, Behnam, Saremi, Amin, and Paul, Satyam

Subjects

REFRACTIVE index, HOLOGRAPHY, HOLOGRAPHIC interferometry, PHASE transitions, TEMPERATURE

Abstract

An off-axis digital holographic interferometry technique integrated with a Mach–Zehnder interferometer based setup is demonstrated for measuring the temperature and temperature profile of a transparent medium. This technique offers several advantages: it does not require precise optomechanical adjustments or accurate definition of the frequency carrier mask, making it simple and cost-effective. Additionally, high-quality optics are not necessary. The methodology relies on measuring the phase difference between two digitally reconstructed complex wave fields and utilizing the temperature coefficient of the refractive index. In this way, we presented an equation of the temperature as a function of phase changes and the temperature coefficient of refractive index. This approach simplifies the calculation process and avoids the burden of complicated mathematical inversions, such as the inverse Abel transformation. It also eliminates the need for additional work with the Lorentz–Lorentz equation and Gladstone–Dale relation and can be extend for 3D measurements. [ABSTRACT FROM AUTHOR]

Published

2023

39. Multiplexing Perfect Optical Vortex for Holographic Data Storage.

Author

Zhu, Jialong, Zou, Fucheng, Wang, Le, Lu, Xiaodong, and Zhao, Shengmei

Subjects

OPTICAL vortices, MULTIPLEXING, HOLOGRAPHY, CLOUD storage, DATA warehousing, HOLOGRAPHIC interferometry, ERROR rates, PROOF of concept

Abstract

Holographic data storage (HDS) has emerged as a promising technology for high-capacity data storage. In this study, we propose a novel approach to enhance the storage density in HDS through a multiplexing perfect optical vortex (POV) hologram. By utilizing the orthogonality property of POV, different POV-recording holograms can be multiplexed to store multiple data pages within the single hologram. Compared with the conventional optical vortex, the better storage density of POV through proof-of-principle experiments is demonstrated. For the POV-multiplexing hologram of six data pages, each one can be reconstructed successfully. In addition, we investigate the impact of axicon periods and multiplexing numbers on the storage performance. Our results reveal that an appropriate selection of axicon periods and multiplexing numbers is crucial to balance storage density and bit error rate (BER). The proposed multiplexing approach offers a valuable solution for achieving high-density and secure holographic data storage systems. [ABSTRACT FROM AUTHOR]

Published

2023

40. 3D dynamic observation of human sperm by parallel phase-shifting digital holographic microscopy based on pixelated polarization.

Author

Bai, Chuanbiao, Jiang, Zhaoxiang, Zhao, Jiangcheng, Wu, Shangquan, and Zhang, Qingchuan

Subjects

DIGITAL holographic microscopy, HOLOGRAPHY, SPERMATOZOA, HOLOGRAPHIC interferometry, STOKES parameters, SPERM motility

Abstract

Morphology and motility are essential criteria for assessing sperm viability. However, the human sperm head is small (∼3–4 μm) and requires a relatively high-magnification microscope objective, while the sperm flagella (∼45 μm) are poorly visible with complex 3D properties. Microscopic dynamic observation of intact sperm in 3D is challenging. Conventional inspection methods with a limited depth of field are inadequate for this issue. To provide a solution to this critical need, we develop pixelated polarization-based parallel phase-shifting digital holographic microscopy for the 3D dynamic observation of human sperm. Compared to conventional holographic imaging, this approach can effectively separate the object wavefront and avoid image quality degradation while fully exploiting the spatial bandwidth of the camera. We propose the use of the Stokes parameter reconstruction method to reconstruct the object wavefront and investigate the effect of the sampling interval on the system resolution by spectral analysis. The methodology achieves the retrieval of the 3D trajectory and motion parameters of sperm and reconstructs the sperm head orientation and the thin, highly-dynamic flagellum. The system allows for more comprehensive information on sperm motility and morphology, which is significant for male reproductive research. It also has significant potential for 3D dynamic observation of micro-organisms. [ABSTRACT FROM AUTHOR]

Published

2023

41. Optical profiler.

Author

Belkin, E. A., Poyarkov, V. N., and Markov, O. I.

Subjects

*GEOMETRIC approach, *GEOMETRIC surfaces, *SURFACE topography, *NONDESTRUCTIVE testing, *ELECTROMAGNETIC waves, *MEASUREMENT errors, *GEOMETRIC modeling, *HOLOGRAPHY, *HOLOGRAPHIC interferometry

Abstract

No modern non-destructive testing device, due to its design features, makes it possible to make metrological measurements necessary to build a three-dimensional geometric model of the surface of the part, which is a superposition of the geometric image of the surface and the topography of its microrelief. A device for non-destructive passive control over the formation of the geometry and topography of the microrelief of the surface for metrological measurements of the holographic image of an object in the optical frequency range of electromagnetic waves has been developed. The device does not have probes interacting with the real object under study and, accordingly, the error of metrological measurements decreases. The principle of operation of a profilograph operating in the optical frequency range of electro-magnetic waves is that it is not the object itself that is being studied, but its holographic image. The device provides a modular geometric approach for modeling the surface of the part, which allows structuring a three-dimensional geometric model of the surface, which is a superposition of the geometry and topography of the microrelief. The device has better functional characteristics compared to prototypes in terms of measurement accuracy, resolution, and versatility of application. [ABSTRACT FROM AUTHOR]

Published

2023

42. Experimental analysis of elasto-plastic deformations using contact holographic interferometry.

Author

Gerasimov, S. I.

Subjects

*HOLOGRAPHIC interferometry, *STRESS concentration, *DEFORMATIONS (Mechanics), *DEAD loads (Mechanics), *ENGINEERING plastics, *PLASTICS engineering

Abstract

A full understanding of the plastic zone formation in a stress concentration region of homogeneous and polycrystalline bodies, has long been a goal of researchers in experimental mechanics. Although some analytical and numerical models have been proposed to predict the formation of plastic zones, no satisfactory correlation has been obtained with experimental results due to the complexity of measurement procedures. The purpose of this paper is to develop a simple experimental technique to investigate strains and stresses in a plastic zone in engineering materials by using contact holographic interferometers. Contact holographic interferometers are used effectively to solve some elasto-plastic deformation measurement problems of isotropic and polycrystalline materials. It is specially designed to permit the accurate measurement of the in-plane component of strain in the immediate vicinity of stress concentrators in plates. Some research results of plane static and signvariable load elasto-plastic problems are considered. [ABSTRACT FROM AUTHOR]

Published

2023

43. Implementation of digital holographic interferometry for pulsed plasma studies

Author

Anastasiia M. Kozhevnikova, Anton S. Ivankov, Dmitry V. Schitz, and Igor V. Alekseenko

Subjects

digital holographic interferometry, holographic interferometry, nonthermal plasma, plasma electron concentration, experiment automation, Optics. Light, QC350-467, Electronic computers. Computer science, QA75.5-76.95

Abstract

The study of low-temperature plasma generated in pulsed mode at atmospheric pressure was carried out. The purpose of the presented research is to develop a method of digital holographic interferometry for registration and evaluation of parameters of low-temperature plasma at atmospheric pressure in pulsed mode. This type of plasma is currently applied in medicine and biology. Thus, there is a need to control the exposure dose and plasma environment formation regimes. As plasma parameters, it can be considered its electron concentration which can be calculated through the estimation of the refractive index of plasma pulse in relation to unperturbed state. The plasma pulses were activated in Helium. The plasma pulse frequency was 5 kHz and its duration was 750 ns. During an investigation a laboratory set-up for recording holographic images of plasma pulses was developed. Holograms are acquired on a digital camera and a pulsed laser INNOLAS SpitLight Hybrid II at a wavelength of 532 nm with pulse duration of 10 ns is used as a source of coherent radiation. In order to record plasma pulses, the laser, plasma generator and digital camera were strictly synchronized to each other. During the experiment, a series of about 500 holograms were acquired, and the reconstruction of the phase of the object field was calculated. Analysis of the sequence of holograms allowed calculations of phase difference (interferograms) related to the refractive index of low-temperature pulsed plasma in Helium. It is known that lowtemperature plasma leads to low phase delay which forms low phase contrast of the evaluated interferograms. For this purpose, we carried out preliminary experiments with plasma-arc that has similar temporary parameters, however, with a higher phase contrast of the interferograms. The paper presents experimental results obtained by studying the phase contrast of the refractive index of pure Helium, plasma-arc and plasma pulses in Helium. Thus, the effectiveness of both the experimental set-up and the method to evaluate the interferograms related to the refractive index of the plasma pulse was verified. The data obtained can then be used to estimate the electron concentration of the plasma. However, it needs to increase the sensitivity of the method in order to enhance phase contrast. Increase of sensitivity can be done by means of extension of the spectral range, for example, toward to infra-red.

Published

2022

44. Micro-Weighing Based Biosensor with Adaptive Interferometry †.

Author

Efimov, Timofey, Kumeiko, Vadim, Romashko, Roman, Shmelev, Mikhail, and Rassolov, Evgeni

Subjects

BIOSENSORS, INTERFEROMETERS, MICROMECHANICS, SERUM albumin, PHOTOREFRACTIVE effect

Abstract

In this work, an adaptive holographic interferometer was implemented for the measurement of a micromechanical oscillator frequency. A silicon micro-cantilever mounted on a piezoquartz plate was used as the sensing element. Out-of-plane vibrations of the cantilever were excited using a sinusoidal electrical signal. The cantilever vibrations were measured with the adaptive interferometer using two waves coupling in a semi-insulating photorefractive CdTe:V crystal. In the experiment, the mass of absorbed molecules of bovine serum albumin (BSA) was measured at various concentrations of water solution. The biosensor demonstrated the ability to measure the concentration of BSA in water solutions with a concentration of 0.2 mg/mL. The result shows the possibility of using adaptive interferometry to detect the vibration of micromechanical sensors and the potential prospects for building biosensors based on them. [ABSTRACT FROM AUTHOR]

Published

2023

45. Cálculo del coeficiente de difusión en líquidos por interferometría holográfica de doble exposición: estudio teórico.

Author

Calvo-De Armas, Yailinn Yadiana, Alonso Arias-Hernández, Néstor, and Lucía Molina-Prado, Martha

Subjects

*DIFFUSION measurements, *HOLOGRAPHIC interferometry, *DIFFUSION coefficients, *HOLOGRAPHY, *SUBSTANCE abuse, *CONCENTRATION gradient, *REFRACTIVE index

Abstract

This work is carried out with the purpose of studying theoretically the measurement of the diffusion coefficient (DC) in liquid substances using double exposure holographic interferometry (DEHI). Diffusion has been defined, throughout history, as the phenomenon in which matter moves in a system, from regions with high concentrations to those regions where the concentration is lower, as a consequence of the random movements of its molecules. Diffusion proceeds gradually in the mixture of substances, ending just when the concentrations are equalized; in the case of liquid phase substances, the diffusion of a solute in a solvent. For the study of this process, multiple techniques have been used, among which the optical ones stand out, specifically holographic interferometry, which associates the precision of interferometric measurements with the advantages of holography; by implementing IHDE, it is possible to compare the wavefronts, which in principle were separated in time, thus allowing any type of variation in the analyzed object, however small, to be determined by knowing the characteristic wavelength of the light used. In this article, the theoretical development is presented to obtain the mathematical expression from which the CD in liquids can be calculated, using IHDE, highlighting that this is found through the comparison between interferential fringes of the same order recorded at different times, taking into account the distances, measured from the interface between the two liquids, at which they appear. Finally, an analysis of the expression found and how it is applied from experimentally obtained data is carried out. [ABSTRACT FROM AUTHOR]

Published

2023

46. Digital Holographic Interferometry for Temperature Measurement of Flame without Phase Unwrapping.

Author

Jabeen, Nusrat and Nirala, A. K.

Subjects

*HOLOGRAPHIC interferometry, *FLAME temperature, *TEMPERATURE measurements, *FIRE risk assessment

Abstract

Fast and precise measuring technique is required for vigilant monitoring of risk assessment of fire. In the present work, digital holographic interferometry has been applied for temperature profile measurement of single and coalesced candle flames without undergoing the tedious phase unwrapping procedure. Hence, it has also reduced time and effort. The impact of wick thickness on the temperature profile of single and coalesced candle flames has also been investigated. It is inferred that the peak temperature of the single and coalesced candle flame diminishes with an increase in the wick thickness of the candle. It has also been deduced that the coalescence of flame enhances the peak temperature of the flame. Maximum enhancement of peak temperature (103 K) on the coalescence of flame has been observed in the merged flames of the thinnest wick. The experimentally calculated value of temperature is in proximity to the temperature measured through the thermocouple. [ABSTRACT FROM AUTHOR]

Published

2023

47. Axial multi-focus stealth cutting method based on the fractional Fourier transform for quartz glass.

Author

Jiang, Mingming, Sun, Shufeng, Wang, Jin, Zhang, Fengyun, Wang, Xi, Shao, Jing, and Wang, Pingping

Subjects

*FUSED silica, *FOURIER transforms, *OPTICAL materials, *OPTIMIZATION algorithms, *MANUFACTURING processes, *HOLOGRAPHIC gratings, *HOLOGRAPHIC interferometry

Abstract

Aiming at the problems of quality defects, low efficiency, and insufficient flexibility in the traditional glass cutting process, this paper proposes a holographic ultrafast laser axial multi-focus stealth cutting method. By changing the fractional Fourier transform order, combined with the 3D-GSW iterative optimization algorithm, the spatial position and energy of the axial multi-focus can be flexibly adjusted. Focusing the axial multi-focus inside the quartz glass not only improves cutting efficiency but also eliminates the defects such as chipping and microcracks. This processing method has good prospects for applications in optical material processing and optical manipulation. A holographic ultrafast laser parallel processing system was built, and the diffraction efficiency and light intensity uniformity of the axial multi-focus were simulated and analyzed. Using this stealth cutting method, a single scanning cutting of quartz glass (200 μm) was successfully achieved with intact glass edges and no microcracks. The minimum roughness of the cutting section is 2.21 μm. [ABSTRACT FROM AUTHOR]

Published

2023

48. 52‐5: Late‐News Paper: Thin and Lightweight Head‐Mounted Displays with Holographic Optics and Polarized Laser Backlights Using an Inverted Wedge‐Shaped Light Guide Plate.

Author

Hirosawa, Jin, Okuda, Koichi, Kijima, Hiroaki, Takahashi, Yasuhiro, and Komura, Shinichi

Subjects

HEAD-mounted displays, HOLOGRAPHIC displays, OPTICS, LASERS, HOLOGRAPHIC interferometry

Abstract

Thin and lightweight head‐mounted displays with polarized laser backlights and holographic optics were proposed. To make the distance between the eyes and the displays even shorter, we propose the backlight with an inverted wedge‐shaped light guide plate. We confirmed that it has luminous uniformity and a high degree of polarization. [ABSTRACT FROM AUTHOR]

Published

2023

49. Improved Algorithms of Data Processing for Dispersive Interferometry Using a Femtosecond Laser.

Author

Liu, Tao, Wu, Jiucheng, Suzuki, Amane, Sato, Ryo, Matsukuma, Hiraku, and Gao, Wei

Subjects

*ELECTRONIC data processing, *INTERFEROMETRY, *FEMTOSECOND lasers, *ALGORITHMS, *LASER interferometry, *HOLOGRAPHIC interferometry

Abstract

Two algorithms of data processing are proposed to shorten the unmeasurable dead-zone close to the zero-position of measurement, i.e., the minimum working distance of a dispersive interferometer using a femtosecond laser, which is a critical issue in millimeter-order short-range absolute distance measurement. After demonstrating the limitation of the conventional data processing algorithm, the principles of the proposed algorithms, namely the spectral fringe algorithm and the combined algorithm that combines the spectral fringe algorithm with the excess fraction method, are presented, together with simulation results for demonstrating the possibility of the proposed algorithms for shortening the dead-zone with high accuracy. An experimental setup of a dispersive interferometer is also constructed for implementing the proposed data processing algorithms over spectral interference signals. Experimental results demonstrate that the dead-zone using the proposed algorithms can be as small as half of that of the conventional algorithm while measurement accuracy can be further improved using the combined algorithm. [ABSTRACT FROM AUTHOR]

Published

2023

50. Interferometric Data Analysis of Convective Heat Transfer under a Downward-Facing Horizontal Circular Plate.

Author

Said, A. Ait Haj, Elfagrich, M., and Dahani, Y.

Subjects

*HEAT convection, *NUSSELT number, *RAYLEIGH number, *FREE convection, *WAVELET transforms, *HEAT transfer

Abstract

Interferometric data are analyzed to investigate heat transfer under a heated horizontal circular plate suspended in air at ambient temperature. To achieve an accurate reconstruction of the axisymmetric temperature field, the two-dimensional continuous wavelet transform and the Chebyshev wavelet method are used in the fringe shift process and in the Abel inversion, respectively. The results obtained are evidence for good agreement with the Nusselt number correlation given in the previous work. For the investigated Rayleigh numbers, the medium is axisymmetric and stratified in the vicinity of the plate. The accuracy of interferometric techniques is very sensitive to the methods used in the post-processing of the interferometric data. [ABSTRACT FROM AUTHOR]

Published

2023