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587,066 results on '"Optics"'

1. Fabrication of medium scale 3D components using a stereolithography system for rapid prototyping

Author

Suhas Deshmukh, Baban Suryatal, and Sunil S. Sarawade

Subjects
Rapid prototyping, Environmental Engineering, Materials science, 020209 energy, General Chemical Engineering, 0211 other engineering and technologies, 02 engineering and technology, Ball screw, Slicing, Catalysis, law.invention, Optics, law, 021105 building & construction, 0202 electrical engineering, electronic engineering, information engineering, Light beam, Electrical and Electronic Engineering, Stereolithography, Curing (chemistry), Civil and Structural Engineering, business.industry, Mechanical Engineering, General Engineering, Lens (optics), Digital Light Processing, business
Abstract

A cost-effective stereolithography for medium-scale components is developed to fabricate 3D components with high build speed and resolution from photo-curable resin. The developed SLA utilizes a focused light beam of wavelength range (300 nm–700 nm) coming from the DLP projector and passes through the objective lens and finally imposed on the platform containing a layer of photo-curable resin. After focusing the light beam on the liquid resin layer, the photo-polymerization reaction occurs and the liquid resin becomes solid. Thus, the 3D object is fabricated layer by layer curing of liquid resin. The photopolymer used in this experimentation is polyethylene glycol di-acrylate and Irgacure 784 as photo-initiator. The Creo 3.0 software is used for modelling of 3D objects. A special MATLAB code is developed for slicing of the 3D model and displaying the sliced image one by one through DLP projector. The Arduino microcontroller with stepper motor and ball screw is used to control the motion of Z-stage platform. The Creation workshop software is also used to control motion of the Z-stage and period to display the sliced images through DLP projector. The medium-scale 3D objects with rectangular, square, and circular cross-sections are obtained by curing the aforementioned photo-curable resin. It is observed that the 3D objects are best cured for two seconds curing time with 0.1 mm curing depth along Z-axis.

Published
2023

2. Computer-aided design of free rotation and distortion doublet electromagnetic lenses

Author

Talib M. Abbas and Zena H. Edan

Subjects
Physics, business.industry, Distortion (optics), Magnification, Astrophysics::Cosmology and Extragalactic Astrophysics, General Medicine, Electron, computer.software_genre, law.invention, Magnetic field, Lens (optics), Optics, Projector, law, Computer Aided Design, Focal length, business, computer
Abstract

In this research, a free rotation and distortion projector doublet electromagnetic lens was designed by computer-aided using electron optical design (EOD) program. This lens consists of two identical lenses. This lens's focal and projector characteristics were calculated in the two max magnification regions by changing the axial magnetic flux density in one of the two single lenses by changing its axial bore diameter. The results showed the possibility of obtaining a free rotation and distortion projector doublet electromagnetic lens in the first max magnification regions, and it has the min magnitude for the projector focal length.

Published
2023

3. Electron cryomicroscopy of biological macromolecules

Author

Richard Henderson and Timothy S. Baker

Subjects
Conventional transmission electron microscope, Materials science, business.industry, Icosahedral symmetry, Cryo-electron microscopy, Scanning confocal electron microscopy, Nanotechnology, Astrophysics::Cosmology and Extragalactic Astrophysics, Iterative reconstruction, law.invention, Crystallography, Optics, Electron tomography, law, Energy filtered transmission electron microscopy, Molecule, Electron beam-induced deposition, Electron microscope, business, High-resolution transmission electron microscopy, Electron scattering, Macromolecule
Abstract

This chapter gives a complete but concise introduction to electron cryomicroscopy. The theoretical and practical background is discussed together with a review of applications to the three-dimensional structural analysis of biological macromolecules or macromolecular assemblies. It includes basic descriptions of how to analyse the structures of molecules arranged in the form of two-dimensional crystals, helical arrays or as single particles with or without symmetry. The chapter concludes by anticipating trends towards increased automation, development of better electronic cameras and increasing use of electron tomography for analysis of cell structure. Keywords: cryoTEM; electron cryomicroscopy; electron microscopy; electron scattering; helical particles; icosahedral particles; image processing in cryoTEM; phasing; radiation damage; three-dimensional image reconstruction; two-dimensional crystals

Published
2023

4. Investigations on 2D photonic crystal based cross waveguide structure consisting of resonant cavity

Author

Man Mohan Gupta

Subjects
010302 applied physics, Materials science, business.industry, Finite-difference time-domain method, Physics::Optics, 02 engineering and technology, General Medicine, 021001 nanoscience & nanotechnology, 01 natural sciences, Rod, law.invention, Wavelength, Nonlinear system, Optics, Transmission (telecommunications), law, 0103 physical sciences, Point (geometry), 0210 nano-technology, business, Waveguide, Photonic crystal
Abstract

Two dimensional (2D) Photonic crystals (PhCs) based cross waveguide structure (CWs) consisting of resonant cavity is investigated in this paper. Investigations are done using Two Dimensional Finite Difference Time Domain (2DFDTD) method. Transmission characteristics have been obtained for different radii of central rod placed at crossing point of two waveguides and number of regular rods surrounding central rod. Nonlinear behavior is also studied for different operating wavelengths.

Published
2023

5. Tunable Soft Lens of Large Focal Length Change

Author

Jianyong Ouyang, Li Pengcheng, Jian Zhu, Yuzhe Wang, and Ujjaval Gupta

Subjects
Materials science, business.industry, ComputingMethodologies_IMAGEPROCESSINGANDCOMPUTERVISION, Biophysics, Optical Devices, Robotics, law.invention, Lens (optics), Dielectric elastomers, medicine.anatomical_structure, Optics, Elastomers, Artificial Intelligence, Control and Systems Engineering, law, Lens, Crystalline, medicine, Humans, Focal length, Human eye, business, Lenses
Abstract

Tunable lens technology inspired by the human eye has opened a new paradigm of smart optical devices for a variety of applications due to unique characteristics such as lightweight, low cost, and facile fabrication over conventional lens assemblies. The fast-growing demands for tunable optical lenses in consumer electronics, medical diagnostics, and optical communications require the lens to have a large focal length modulation range and high compactness. Herein, for the first time, an all-solid tunable soft lens driven by highly transparent dielectric elastomer actuators (DEAs) based on poly(3,4-ethylenedioxythiophene):poly(styrenesulfonate) and waterborne polyurethane (PEDOT:PSS/WPU) transparent electrodes is developed. The deformation of the tunable soft lens is achieved by the actuation of DEAs, mimicking the change of the surface profile of the human eye to achieve remarkable focal length variations. Upon electrical activation, this tunable soft lens can vary its original focal length by 209%, which is one of the highest among current tunable soft lenses and far beyond that of the human eye. This study demonstrates that transparent DEAs are capable of achieving focus-variation functions, and potentially useful in artificial robotic vision, visual prostheses, and adjustable glasses, which will induce significant effects on the future development of tunable optics.

Published
2022

6. A line laser detection screen design and projectile echo power calculation in detection screen area

Author

Xuewei Zhang, Hanshan Li, Quan-min Guo, and Xiaoqian Zhang

Subjects
Physics, 0209 industrial biotechnology, Projectile, business.industry, Mechanical Engineering, Echo (computing), Metals and Alloys, Computational Mechanics, 02 engineering and technology, Photoelectric effect, Laser, 01 natural sciences, Intersection (Euclidean geometry), 010305 fluids & plasmas, law.invention, Power (physics), 020901 industrial engineering & automation, Optics, law, 0103 physical sciences, Ceramics and Composites, Line (text file), business, Laser detection
Abstract

A line laser with high power as the background light source for the design of a new photoelectric detection target is proposed in this paper, aiming to improve the detection ability of the traditional photoelectric detection target under low background illumination. The laser emitted pulse waveform function and the laser echo pulse response function were used to establish the mathematical model of the reflected echo power of projectile in the detection area and derive the calculation function of minimum detectable echo power in the line laser detection screen, according to information of the line laser emitted power, incident angle of projectile, duration time and detection distance of projectile passing through the line laser detection screen. Calculations and experimental results showed that the design method of line laser detection screen and calculation model of laser echo power are reasonable, and the detection ability of line laser detection screen is obviously higher than that of traditional photoelectric detection screen, especially in low background illumination; at the same time, the designed line laser detection screen was used to combine a six line laser detection screen intersection test system, based on live ammunition for shooting. The test system is stable and able to obtain the dynamic parameters of the flying projectile, verifying that the design of the line laser detection screen in new photoelectric detection target can be suitable for shooting range test applications.

Published
2022

7. Experimental measurements for attenuation recovery in optical fiber cables under gamma and neutron irradiation

Author

Adel Zaghloul, Moteaa A. Nassar, Imbaby I. Mahmoud, Mohamed S. El_Tokhy, and Magdy M. Zaky

Subjects
Optical fiber, Materials science, business.industry, Attenuation, Fiber Cable, General Engineering, Single-mode optical fiber, Radiation, Neutron radiation, Single Mode, Engineering (General). Civil engineering (General), law.invention, Wavelength, Optics, Gamma Rays, law, Neutron, Research reactor, TA1-2040, business, Neutron Irradiation, Power Meter
Abstract

The influence of neutron and gamma radiation on single mode fiber cables is experimentally conducted. Attenuation due to incident radiation is measured. Attenuation is determined by laser source and power meter in Africa Teleco Company, besides attenuation recovery is attained. The Gamma experiment is carried out within Egypt Mega Gamma1 in National Center for Radiation Research and Technology of Egyptian Atomic Energy Authority (EAEA). In this experiment, the cable is degraded by gamma radiation of doses 5KGy, 10KGy, 15KGy and 25KGy and dose rate of 1KGy/26.4 min. However the attenuation based on neutron degradation is executed in the second Egyptian Training Research Reactor (ETRR-2), in front of neutron beam facility (NBF) in ETRR-2 which has a flux of 1.5x107(n/cm2.sec). For both experiments, the experimental measurements are done at two different spectral wavelengths of 1310 nm and 1550 nm. A comparison between obtained results is investigated.

Published
2022

8. The Prospect of Spatially Accurate Reconstructed Atom Probe Data Using Experimental Emitter Shapes

Author

Paul van der Heide, Brian P. Geiser, Wilfried Vandervorst, Jeroen E. Scheerder, Claudia Fleischmann, JH Bunton, Robert M. Ulfig, David Larson, and Jonathan Op de Beeck

Subjects
Optics, Materials science, law, business.industry, Atom probe, business, Instrumentation, Common emitter, law.invention
Abstract

Reliable spatially resolved compositional analysis through atom probe tomography requires an accurate placement of the detected ions within the three-dimensional reconstruction. Unfortunately, for heterogeneous systems, traditional reconstruction protocols are prone to position some ions incorrectly. This stems from the use of simplified projection laws which treat the emitter apex as a spherical cap, although the actual shape may be far more complex. For instance, sampled materials with compositional heterogeneities are known to develop local variations in curvature across the emitter due to their material phase specific evaporation fields. This work provides three pivotal precursors to improve the spatial accuracy of the reconstructed volume in such cases. First, we show scanning probe microscopy enables the determination of the local curvature of heterogeneous emitters, thus providing the essential information for a more advanced reconstruction considering the actual shape. Second, we demonstrate the cyclability between scanning probe characterization and atom probe analysis. This is a key ingredient of more advanced reconstruction protocols whereby the characterization of the emitter topography is executed at multiple stages of the atom probe analysis. Third, we show advances in the development of an electrostatically driven reconstruction protocol which are expected to enable reconstruction based on experimental tip shapes.

Published
2022

9. Effect of tilt angle on the performance and electrical parameters of a PV module: Comparative indoor and outdoor experimental investigation

Author

Md. Hasanuzzaman, Md. Monirul Islam, M.A.A. Mamun, and Jeyraj Selvaraj

Subjects
Materials science, Maximum power principle, Renewable Energy, Sustainability and the Environment, business.industry, Drop (liquid), Photovoltaic system, Transportation, Building and Construction, Power (physics), law.invention, Tilt (optics), Optics, law, Solar cell, business, Intensity (heat transfer), Civil and Structural Engineering, Voltage
Abstract

Photovoltaic (PV) system's performance is significantly affected by its orientation and tilt angle. Experimental investigation (indoor and outdoor) has been carried out to trace the variation in PV performance and electrical parameters at varying tilt angles in Malaysian conditions. There were two experimental modus: 1) varying module tilt under constant irradiation level, 2) varying irradiation intensity at the optimum tilt set up. For the former scheme, the irradiation level was maintained at 750 W/m2, and for the later arrangement, the module tilt angle was varied from 0o to 80o by means of a single-axis tracker. Results show that under constant irradiation of 750 W/m2, every 5o increase in tilt angle causes a power drop of 2.09 W at indoor and 3.45 W at outdoor. In contrast, for the same condition, efficiency decreases by 0.54% for indoor case and by 0.76% at outdoor. On the other hand, for every 100 W/m2 increase in irradiation, solar cell temperature rises by 7.52°C at indoor and by 5.67°C at outdoor. As of module electrical parameters, open-circuit voltage, short-circuit current, maximum power point voltage and maximum power point current drops substantially with increasing tilt angle, whereas fill factor drops rather gradually. Outdoor experimental investigation confirms that the optimum tilt angle at Malaysian conditions is 15o and orienting a PV module this angle will maximize the sun's energy captured and thereby enhance its performance.

Published
2022

10. Thermal effect on the optical signal of fiber optics networks

Author

Ghassan A. QasMarrogy and Abdulrazak A. S. Mohammed

Subjects
Environmental Engineering, Materials science, Optical fiber, business.industry, Materials Science (miscellaneous), General Engineering, Thermal effect, Physics::Optics, Management Science and Operations Research, Signal, law.invention, Optics, law, Architecture, business, Information Systems
Abstract

Fiber Optic Network is an advanced and modern system technology, which is used in sending pulses of laser light inside a glass of fiber over long distances, widely used in every environment with various sorts of applications in a different field. It is well-known that the main material of fiber optics is glass, therefore it is typical that the temperature can affect the glass during the thermal expansion. This effect will be applied to the properties of the optical components such as refractive index, radius curvature of the fiber optics layers, and also there is an effect on the data transfer through the fiber optics network units. In this paper, the effect of temperature degree on the optical signal and the functions of the fiber optic network will be simulated, measured, and analyzed. The result will be discussed and the conclusion will show the serious points of thermal effects on the optical signal of a fiber-optic network.

Published
2022

11. Super-Regenerative Oscillator Integrated Metamaterial Leaky Wave Antenna for Multi-Target Vital Sign and Motion Detection

Author

Yichao Yuan and Chung-Tse Michael Wu

Subjects
Physics, Radiation, business.industry, Leaky wave antenna, Transistor, Metamaterial, Motion detection, Signal, law.invention, Voltage-controlled oscillator, Radar engineering details, Optics, law, Radiology, Nuclear Medicine and imaging, Sensitivity (control systems), business, Instrumentation
Abstract

A new kind of metamaterial (MTM) leaky wave antenna (LWA) integrated with a super-regenerative oscillator (SRO) architecture is proposed for the first time. As a proof of concept, the proposed radar sensor, including a one-dimensional (1D) MTM LWA and a tunable voltage-controlled oscillator (VCO), is designed to perform frequency-dependent space mapping with the main-beam angle sweeping from −50 $^\circ $ to +30 $^\circ $ with respect to the varying frequency from 1.85 to 2.85 GHz. The proposed SRO-integrated MTM LWA system is operated in the logarithmic mode with a quench signal imposed at the drain port of transistor. Experiments have been conducted to show that vital sign information for two human targets can be successfully detected when they are located along different scanning angles of −10 $^\circ $ and −30 $^\circ $ , respectively. Furthermore, compared with MTM LWA radar sensor based on the self-injection-locked (SIL) architecture, vibrating motion at a farther distance can be detected accurately using the proposed radar sensor, indicating a higher sensitivity with reduced system complexity.

Published
2022

13. Dual Core Ytterbium Doped Fiber as a Gain Medium for a High Powered Swept Source Laser for Use in Multi-Channel Optical Coherence Tomography

Author

Mark K. Harduar

Subjects
Optical amplifier, Ytterbium, Materials science, Active laser medium, medicine.diagnostic_test, business.industry, Scattering, chemistry.chemical_element, Laser, law.invention, Resonator, Optics, chemistry, Optical coherence tomography, law, medicine, Coherence (signal processing), business
Abstract

Optical coherence tomography (OCT) is a novel imaging modality that provides volumetric in-vivo high-resolution (1-15μm) images in real-time. Multi-channel OCT (MOCT) imaging utilizes many imaging channels simultaneously yielding several advantages over single-channel OCT. The benefits of MOCT are at the cost of the added requirement of several imaging beams, which demands high power output from the laser source. Dual-core Ytterbium (Yb) doped fiber was used in two configurations to demonstrate its use as a MOCT light source gain medium: 1) within a ring cavity resonator and 2) in a post-amplification regime with a low powered seed-laser. The amplification wavelength range was tailored to be centered at ~1060nm, where light absorption and scattering is at a minimum in water. In the post-amplification configuration, the output power was increased from 5mW to >200mW, with the axial resolution reducing from 10μm to 12μm. We also present initial in-vivo MOCT imaging of a tadpole.

Published
2023

14. Second order add/drop filter with a single ring resonator

Author

Fei Sun, Timo Aalto, Matteo Cherchi, Markku Kapulainen, Mikko Harjanne, Tapani Vehmas, Knights, Andrew P., and Reed, Graham T.

Subjects
multimode interference splitters, FOS: Physical sciences, Physics::Optics, 02 engineering and technology, Applied Physics (physics.app-ph), Mach–Zehnder interferometer, photonic integrated circuits, law.invention, Resonator, Finesse, 020210 optoelectronics & photonics, Optics, law, 0202 electrical engineering, electronic engineering, information engineering, ta216, Physics, ta113, Silicon photonics, flat-top filters, ta114, ta213, silicon photonics, business.industry, Photonic integrated circuit, Physics - Applied Physics, OtaNano, ring resonators, WDM filters, Filter (video), integrated optics, Optoelectronics, Power dividers and directional couplers, business, Waveguide, Optics (physics.optics), Physics - Optics
Abstract

We show theoretically and experimentally how a flat-top second-order response can be achieved with a self-coupled single add-drop ring resonator based on two couplers with different splitting ratios. The resulting device is a 1x1 filter, reflecting light back in the input waveguide at resonating wavelengths in the passbands, and transmitting light in the output waveguide at all other non-resonating wavelengths. Different implementations of the filter have been designed and fabricated on a micron-scale silicon photonics platform. They are based on compact Euler bends - either U-bends or L-bends - and Multi-Mode Interferometers as splitters for the ring resonators. Different finesse values have been achieved by using either 50:50 MMIs in conjunction with 85:15 MMIs or 85:15 MMIs in conjunction with 95:05 double MMIs. Unlike ordinary lowest order directional couplers, the MMIs couple most of the power in the cross-port which make them particularly suitable for the topology of the self-coupled ring, which would otherwise require a waveguide crossing. Experimental results are presented, showing good agreement with simulations. The proposed devices can find applications as wavelength-selective reflectors for relatively broad-band lasers or used as 2x2 add-drop filters when two exact replicas of the device are placed on the arms of a Mach-Zehnder interferometer., 9 pages, 17 references, 12 figures

Published
2023

15. Non-contact monitoring of the depth temperature profile for medical laser scanning technologies

Author

Jure Kosir, Matija Jezeršek, and Daniele Vella

Subjects
udc:61:543.572.3(045), termografija, Materials science, Laser scanning, Infrared, engineering, lcsh:Medicine, 01 natural sciences, Article, law.invention, 010309 optics, 03 medical and health sciences, 0302 clinical medicine, Optics, Engineering, law, biomedical engineering, 0103 physical sciences, Thermal, Miniaturization, prenos toplote v tkivu, lcsh:Science, Overheating (electricity), Reproducibility, Multidisciplinary, business.industry, lcsh:R, Laser, thermography, depth temperatur profile, heat transfer in biological tissue, 030220 oncology & carcinogenesis, Thermography, lcsh:Q, temperaturni profil, business, Biomedical engineering
Abstract

Medical treatments such as high-intensity focused ultrasound, hyperthermic laser lipolysis or radiofrequency are employed as a minimally invasive alternatives for targeted tissue therapies. The increased temperature of the tissue triggers various thermal effects and leads to an unavoidable damage. As targeted tissues are generally located below the surface, various approaches are utilized to prevent skin layers from overheating and irreparable thermal damages. These procedures are often accompanied by cooling systems and protective layers accounting for a non-trivial detection of the subsurface temperature peak. Here, we show a temperature peak estimation method based on infrared thermography recording of the surface temperature evolution coupled with a thermal-diffusion-based model and a time-dependent data matching algorithm. The performance of the newly developed method was further showcased by employing hyperthermic laser lipolysis on an ex-vivo porcine fat tissue. Deviations of the estimated peak temperature remained below 1 °C, as validated by simultaneous measurement of depth temperature field within the tissue. Reconstruction of the depth profile shows a good reproducibility of the real temperature distribution with a small deviation of the peak temperature position. A thermal camera in combination with the time-dependent matching bears the scope for non-contact monitoring of the depth temperature profile as fast as 30 s. The latest demand for miniaturization of thermal cameras provides the possibility to embed the model in portable thermal scanners or medical laser technologies for improving safety and efficiency.

Published
2023

16. Design, characterization, and first field deployment of a novel aircraft-based aerosol mass spectrometer combining the laser ablation and flash vaporization techniques

Author

Johannes Schneider, Thomas Böttger, Sergej Molleker, Frank Drewnick, Stephan Borrmann, Andreas Hünig, Oliver Appel, Frank Helleis, Thomas Klimach, Hans-Christian Clemen, Franziska Köllner, and Antonis Dragoneas

Subjects
624 Civil engineering, 540 Chemistry and allied sciences, Atmospheric Science, Laser ablation, Materials science, business.industry, 530 Physics, 624 Ingenieurbau und Umwelttechnik, Laser, Mass spectrometry, 530 Physik, 620 Ingenieurwissenschaften und Maschinenbau, Aerosol, law.invention, Optics, law, 540 Chemie, Vaporization, 620 Engineering and allied operations, Particle, Vacuum chamber, Particle size, 600 Technik, business, 600 Technology (Applied sciences)
Abstract

In this paper, we present the design, development, and characteristics of the novel aerosol mass spectrometer ERICA (ERC Instrument for Chemical composition of Aerosols; ERC – European Research Council) and selected results from the first airborne field deployment. The instrument combines two well-established methods of real-time in situ measurements of fine particle chemical composition. The first method is the laser desorption and ionization technique, or laser ablation technique, for single-particle mass spectrometry (here with a frequency-quadrupled Nd:YAG laser at λ = 266 nm). The second method is a combination of thermal particle desorption, also called flash vaporization, and electron impact ionization (like the Aerodyne aerosol mass spectrometer). The same aerosol sample flow is analyzed using both methods simultaneously, each using time-of-flight mass spectrometry. By means of the laser ablation, single particles are qualitatively analyzed (including the refractory components), while the flash vaporization and electron impact ionization technique provides quantitative information on the non-refractory components (i.e., particulate sulfate, nitrate, ammonia, organics, and chloride) of small particle ensembles. These techniques are implemented in two consecutive instrument stages within a common sample inlet and a common vacuum chamber. At its front end, the sample air containing the aerosol particles is continuously injected via an aerodynamic lens. All particles which are not ablated by the Nd:YAG laser in the first instrument stage continue their flight until they reach the second instrument stage and impact on the vaporizer surface (operated at 600 ∘C). The ERICA is capable of detecting single particles with vacuum aerodynamic diameters (dva) between ∼ 180 and 3170 nm (d50 cutoff). The chemical characterization of single particles is achieved by recording cations and anions with a bipolar time-of-flight mass spectrometer. For the measurement of non-refractory components, the particle size range extends from approximately 120 to 3500 nm (d50 cutoff; dva), and the cations are detected with a time-of-flight mass spectrometer. The compact dimensions of the instrument are such that the ERICA can be deployed on aircraft, at ground stations, or in mobile laboratories. To characterize the focused detection lasers, the ablation laser, and the particle beam, comprehensive laboratory experiments were conducted. During its first deployments the instrument was fully automated and operated during 11 research flights on the Russian high-altitude research aircraft M-55 Geophysica from ground pressure and temperature to 20 km altitude at 55 hPa and ambient temperatures as low as −86 ∘C. In this paper, we show that the ERICA is capable of measuring reliably under such conditions.

Published
2022

17. Vibration insensitive single-shot interferometry using a wide-field laser microscope

Author

Isami Nitta and Yosuke Tsukiyama

Subjects
Materials science, Microscope, business.industry, General Engineering, Linear stage, Interference (wave propagation), Laser, law.invention, Vibration, Interferometry, Optics, law, Distortion, Wafer, business
Abstract

Here, we report measurements made with an external vibration-insensitive single-shot interferometer, which is applicable for on-machine measurement. Previously, we developed a simple single-shot interferometry method in which the optical intensities of interference fringes appear not as sinusoidal distributions but have a sawtooth-like distribution, and the peak distortion direction depicts the slope of the measured surfaces. These properties allow use of this method in vibration-insensitive interferometry. In this study, we have experimentally confirmed this concept through measurement of a quarter of a Si wafer specimen 50 mm in diameter. The vibration source was a motorized linear stage the surface of which fluctuated between ±400 nm in height. The obtained surface profiles of the Si wafer were consistent with measurements made with a commercial interferometer within 30 nm.

Published
2022

18. Experimental study on the accumulative effect of multiple pulses on acceleration sensor

Author

Fang Zhong, Yong He, Xuchao Pan, Hong Chen, Jie Shen, Wan-li Zhang, and Yun-lei Shi

Subjects
0209 industrial biotechnology, Materials science, business.industry, Mechanical Engineering, Amplifier, Metals and Alloys, Computational Mechanics, 02 engineering and technology, 01 natural sciences, Electromagnetic interference, 010305 fluids & plasmas, Pulse (physics), law.invention, Threshold voltage, Acceleration, 020901 industrial engineering & automation, Optics, Optical microscope, law, 0103 physical sciences, Ceramics and Composites, Electronics, business, Electromagnetic pulse
Abstract

Intentional electromagnetic interference is a serious threat to the safety of electronic devices. Multiple electromagnetic pulses will be coupled and transmitted to electronic devices through the cables. Accumulative effects are generated, which make it easier for damage to occur in the electronic devices. In this article, the working principle of micro-silicon acceleration sensors is introduced. The accumulative effects of multiple pulses on acceleration sensors is studied by a large number of injection experiments. The accumulation trends of multiple pulses with different pulse numbers and intervals are analyzed. The damaged structures inside abnormal sensor amplifiers were observed via optical microscopy and scanning electron microscopy. The experimental results show that the accumulative effect is strengthened with increased pulse number or decreased pulse interval, and the threshold voltage for multiple pulses on the acceleration sensor decreases. The threshold voltage for a single pulse is 321.57 V. When the pulse interval is 1 μs and the pulse number is 5, the threshold voltage for multiple pulses is 163.42 V, which is reduced by 49.12% compared with a single pulse. These results provide a reference for the damage design of electromagnetic pulse weapons.

Published
2022

20. Performance Improvement of LC-Based Beam-Steering Leaky-Wave Holographic Antenna Using Decoupling Structure

Author

Sangwook Nam and Hyungcheol Kim

Subjects
Coupling, Physics, business.industry, Beam steering, Astrophysics::Instrumentation and Methods for Astrophysics, Holography, Phase (waves), law.invention, Optics, Liquid crystal, law, Electrical and Electronic Engineering, Performance improvement, Antenna (radio), business, Decoupling (electronics), Computer Science::Information Theory
Abstract

A liquid crystal-based beam-steering leaky-wave holographic antenna is designed with decoupling structure. Since the distance between elements in holographic antennas is inevitably small (< λ /5), the mutual coupling is strong and should be compensated for the accurate implementation of the excitation amplitude and phase of each element. The performance degradation of a holographic antenna due to mutual coupling is estimated and a decoupling structure is proposed, fabricated, and inserted into the designed antenna. The operating principle of the decoupling structure is explained with circuit model and the simulation confirms the enhanced gain and sidelobe performance when steered from -60° to 60° in 20° intervals. Compared to the antenna without the decoupling structure, the maximum improvement of the gain and the sidelobe level are 3.93 dB and 7.7 dB, respectively, in the simulation. The experimental results are consistent with the simulation results.

Published
2022

21. Sparse Coding-Enabled Low-Fluence Multi-Parametric Photoacoustic Microscopy

Author

Song Hu, Yifeng Zhou, and Zhuoying Wang

Subjects
Microscopy, Materials science, Radiological and Ultrasound Technology, Image quality, business.industry, Pulse (signal processing), Lasers, Spectrum Analysis, Noise reduction, Laser, Fluence, Article, Computer Science Applications, law.invention, Photoacoustic Techniques, Reduction (complexity), Optics, Sampling (signal processing), law, Electrical and Electronic Engineering, Neural coding, business, Software
Abstract

Uniquely capable of simultaneous imaging of the hemoglobin concentration, blood oxygenation, and flow speed at the microvascular level in vivo, multi-parametric photoacoustic microscopy (PAM) has shown considerable impact in biomedicine. However, the multi-parametric PAM acquisition requires dense sampling and thus a high laser pulse repetition rate (up to MHz), which sets a strict limit on the applicable pulse energy due to safety considerations. A similar limitation is shared by high-speed PAM, which also uses lasers with high pulse repetition rates. To achieve high quantitative accuracy besides good structural visualization at low levels of laser fluence in PAM, we have developed a new, sparse coding-based two-step denoising technique. In the setting of intravital brain imaging, we demonstrated that this unsupervised learning approach enabled the reduction of the laser fluence in PAM by 5 times without compromise of the image quality (structural similarity index measure or SSIM: >0.92) and the quantitative accuracy (errors

Published
2022

22. Wideband Omnidirectional Circularly Polarized Antenna for Millimeter-Wave Applications Using Conformal Artificial Anisotropic Polarizer

Author

Chen Ding and Kwai-Man Luk

Subjects
Wavefront, Physics, business.industry, Physics::Optics, Polarizer, law.invention, Lens (optics), Optics, law, Electrical and Electronic Engineering, Wideband, Antenna (radio), Anisotropy, Omnidirectional antenna, business, Circular polarization
Abstract

A wideband omnidirectional circularly polarized (CP) antenna using a conformal artificial anisotropic polarizer is proposed for millimeter-wave applications. The antenna consists of three parts: an omnidirectional linearly polarized (LP) radiator, an annular hyperbolic lens, and a conformal anisotropic polarizer. The annular hyperbolic lens regulates the spherical wavefront from the LP radiator into a cylindrical shape prior to propagating into the conformal artificial anisotropic polarizer. Each curved slab of the polarizer is conformally tilted 45 degrees to the incident electric field. Therefore, the conformal polarizer is the three-dimensionalization of the two-dimensional planar artificial anisotropic polarizer. The polarizer designing methodology is the first of its kind to generate wideband CP wave omnidirectionally. The hyperbolic lens and the conformal polarizer are fabricated together using stereolithography (SLA) 3D printing technology. Measurement results show that the antenna has a wide operating bandwidth of 45% (from 24 to 38 GHz), which completely covers potential 5G 28-GHz spectra. The proposed design has a low fabrication complexity and brings possibilities for high-speed wireless communications utilizing circular polarization.

Published
2022

23. Whistler-Mode Radiation From a Dipole Antenna in Cold Magnetized Plasma

Author

Jiannan Tu, W. R. Johnston, Bodo W. Reinisch, Ivan Galkin, and Paul Song

Subjects
Physics, Fresnel zone, business.industry, Plasma, Interference (wave propagation), law.invention, Magnetic field, Optics, law, Group velocity, Dipole antenna, Electrical and Electronic Engineering, Antenna (radio), business, Radiation resistance, Computer Science::Information Theory
Abstract

We treat whistler mode radiation from a dipole antenna in a cold magnetized plasma based on the Fresnel zone construction theory. Radiated waves from the antenna with different propagation directions interfere in space. Regions of enhanced waves are formed when the interference is predominantly constructive at the observing point. The coherently enhanced wave propagates at the group velocity. If the antenna is perpendicular to the background magnetic field, the regions of strong waves form two back-to-back Fresnel zones that are parabolic-shaped cones along the background magnetic field from the antenna. The power within each cone drops with distance at a rate of 1/r much more slowly than the 1/r2 thinning of a spherical wave as in vacuum. The total radiation can be approximately derived by the total energy flux integrated over the Fresnel zone. The derived radiation resistance is much greater than that in vacuum. It is proportional to frequency as 1/f2 and proportional to the antenna length as d2. To radiate more power a longer antenna is preferred, a result that is opposite to some previous theoretical studies.

Published
2022

24. Realization of High-Gain Low-Sidelobe Wide-Sector Beam Using Inductive Diaphragms Loaded Slotted Ridge Waveguide Antenna Array for Air Detection Applications

Author

Tao Su, Jinshan Ding, Yu-Tong Zhao, Jianzhong Chen, Min Bao, Tian Hu, and Liang Li

Subjects
Beamforming, Physics, business.industry, law.invention, Antenna array, Beamwidth, Optics, law, Radar imaging, Equivalent circuit, Power dividers and directional couplers, Electrical and Electronic Engineering, Radar, Antenna (radio), business
Abstract

This paper presents a high-gain slotted ridge waveguide array antenna (SRWAA) with inductive diaphragms, which can realize a wide-sector beam with a low sidelobe simultaneously. The proposed antenna can cover a wide detection range and avoid interference from other directions. The expected excitation distribution for the antenna array is extracted through a beamforming method. To reduce the influence of the dispersion phenomenon on signal quality, inductive diaphragms are inserted into the sidewall of the ridge waveguide, which is fully analyzed from the point of the equivalent circuit. A cut-off-mode power divider is utilized, which can control the power ratio flexibly. A SRWAA working at 24.125 GHz, including a six-way feeding network, and a 6×24 slot array with the size of 330 mm × 66.8 mm is designed and fabricated. The measured sidelobe level (SLL) and half-power beamwidth (HPBW) in the elevation plane are -19.6 dB and 54.41°, with the counterparts in the azimuth plane -29.8 dB and 3.15°, respectively. The measured peak gain is 22.3 dBi at 24.125 GHz. The measured results are in good agreement with the simulated ones. This work has the potential to be applied in air detection, anti-unmanned aerial vehicles (UAVs), meteorological radar, and imaging radar.

Published
2022

26. On-chip classification of micro-particles using laser light scattering and machine learning

Author

Zeeshan Ali, Yongjun Tang, Jun Zou, Mubashir Hussain, Xiaolong Liu, Jianguo Dai, Jian Yang, Hamood Ur Rehman, and Nongyue He

Subjects
Range (particle radiation), Materials science, Optical fiber, business.industry, Photodetector, Ranging, General Chemistry, Laser, Light scattering, law.invention, Support vector machine, Optics, law, Particle, business
Abstract

The rapid detection of microparticles exhibits a broad range of applications in the field of science and technology. The proposed method differentiates and identifies the 2 µm and 5 µm sized particles using a laser light scattering. The detection method is based on measuring forward light scattering from the particles and then classifying the acquired data using support vector machines. The device is composed of a microfluidic chip linked with photosensors and a laser device using optical fiber. Connecting the photosensors and laser device using optical fibers makes the device more diminutive in size and portable. The prepared sample containing microspheres was passed through the channel, and the surrounding photosensors measured the scattered light. The time-domain features were evaluated from the acquired scattered light, and then the SVM classifier was trained to distinguish the particle's data. The real-time detection of the particles was performed with an overall classification accuracy of 96.06%. The optimum conditions were evaluated to detect the particles with a minimum concentration of 0.2 µg/mL. The developed system is anticipated to be helpful in developing rapid testing devices for detecting pathogens ranging between 2 µm to 10 µm.

Published
2022

27. A Wide-Angle Coverage and Low Scan Loss Beam Steering Circularly Polarized Folded Reflectarray Antenna for Millimeter-Wave Applications

Author

Guo-Qiang Zhu, Yun-Hua Zhang, Huo-Tao Gao, Hai-Tao Chen, Si-Yuan He, and Zhen-Yu Yu

Subjects
Waveguide (electromagnetism), Materials science, business.industry, Beam steering, Antenna aperture, Reflector (antenna), Polarizer, law.invention, Optics, law, Radar imaging, Electrical and Electronic Engineering, Antenna (radio), business, Beam (structure)
Abstract

In this paper, a compact and low-profile beam steering circularly polarized folded reflectarray antenna (CPFRA) with low scan loss for wide-angle coverage is proposed and designed. In order to obtain lower scan loss over a wider beam coverage range (BCR), a multibeam optimization method considering the illumination weighting factor is introduced to obtain minimum phase errors for the designed beam direction. To improve antenna compactness and alleviate the mutual couplings among multiple feeding sources, small-size substrate integrated waveguide (SIW) cavity-backed slot antennas are employed as the feeding sources, which are integrated with the single-layer reflector board. An incident angle insensitive circular polarizer is designed and integrated over the antenna aperture to achieve circularly polarized (CP) radiation over a wide BCR. At last, a 15-beam CPFRA working at Ka-band, with size 140 mm × 140 mm is designed, manufactured, and measured to validate the proposed design method. Measurement results show that the designed CPFRA can achieve a rather flat gain, with only a 2.1 dB scan loss, across the wide 3-dB BCR of ±29°. The good CP beams are formed over the entire coverage range without any blind zone. With the advantages of wide-angle coverage, low scan loss, and high integration, the proposed beam steering antenna is promising in applications such as 5G communication, radar imaging, and target recognition.

Published
2022

28. Power control of CiADS core with the intensity of the proton beam

Author

Wenjuan Cui, Shiwu Dang, Kai Yin, Feng Yang, Zhiyong He, Yikai Hou, Yuhui Guo, Xinxin Li, Wenjing Ma, Li-Min Duan, and Meng Li

Subjects
Materials science, Aperture, business.industry, Control rod, Particle accelerator, law.invention, Intensity (physics), Core (optical fiber), Optics, Nuclear Energy and Engineering, law, Physics::Accelerator Physics, Neutron source, Spallation, business, Beam (structure)
Abstract

This paper reports the control method for the core power of the China initiative Accelerator Driven System (CiADS) facility. In the CiADS facility, an intense external neutron source provided by a proton accelerator coupled to a spallation target is used to drive a sub-critical reactor. Without any control rod inside the sub-critical reactor, the core power is controlled by adjusting the proton beam intensity. In order to continuously change the beam intensity, an adjustable aperture is considered to be used at the Low Energy Beam Transport (LEBT) line of the accelerator. The aperture size is adjusted based on the Proportional Integral Derivative (PID) controllers, by comparing either the setting beam intensity or the setting core power with the measured value. To evaluate the proposed control method, a CiADS core model is built based on the point reactor kinetics model with six delayed neutron groups. The simulations based on the CiADS core model have indicated that the core power can be controlled stably by adjusting the aperture size. The response time in the adjustment of the core power depends mainly on the adjustment time of the beam intensity.

Published
2022

29. Low-Profile Circularly Polarized Staircase Curl Antenna Array With 2:1 Impedance and 50% AR Bandwidths for 5G mmW Communications

Author

Jie Tian, Zhewang Ma, Xiao Dong Chen, Jing-Ya Deng, Haiwen Liu, Junsheng Yu, and Zhijiao Chen

Subjects
Curl (mathematics), Physics, business.industry, Axial ratio, Microstrip, law.invention, Antenna array, Optics, law, Bandwidth (computing), Electrical and Electronic Engineering, Wideband, business, Transformer, Electrical impedance
Abstract

In this communication, a low-profile circularly polarized (CP) staircase curl antenna array with 2:1 impedance bandwidth and 50% axial ratio bandwidth is proposed for 5G millimeter-wave (mmW) communications. It overcomes a vital drawback of complex multi-layer structure of the wideband CP antenna array. By fully taking advantage of 3D staircase layout, the curl element achieves 2:1 impedance bandwidth, 57.9% axial ratio (AR) bandwidth, and a maximum gain of 7.4 dBic. Accordingly, benefiting from the tapered matching transformer, a singlelayer full-corporate microstrip feeding network with 111.4% impedance bandwidth is constructed. For demonstration, an 8 × 8 staircase curl antenna array is designed on three-layer PCB laminates. The proposed antenna array is measured with impedance bandwidth of 76.9% (20.0-45.0 GHz), AR bandwidth of 53.6% (23.1-40.0 GHz), demonstrating a promising candidate to be used in 5G mmW communications.

Published
2022

30. Asymmetric Iris Structures for Dual-Polarization Waveguide Slot Arrays for E-Band Wireless Backhaul Systems

Author

Gangil Byun, Young Su Kim, Sion You, and Sang Chul Ahn

Subjects
Physics, Anechoic chamber, business.industry, E band, Effective radiated power, Polarization (waves), law.invention, Optics, Dual-polarization interferometry, law, Standing wave ratio, Electrical and Electronic Engineering, Antenna (radio), business, Waveguide
Abstract

This paper proposes a design of waveguide slot arrays with asymmetric Iris to achieve broadband properties with high polarization isolation for E-band wireless backhaul systems. The proposed subarray of 2 × 2 radiating slots is excited by two-layered feeding networks carrying two orthogonal waves, and the asymmetric Iris is inserted at the intersection where the waves merge. For verification, a prototype with 16 × 16 radiating slots is fabricated, and its antenna characteristics are measured in an anechoic chamber. The fabricated antenna has a bandwidth of 13 GHz at Port 1 and 10.5 GHz at Port 2 for VSWR ≤ 2.6, and the isolation between two ports is greater than 30 dB within the target frequency bands. The average bore-sight gains of the two ports are 30.85 dBi and 31.67 dBi, and the half-power beam widths are 3.5° and 3.25°. We also fabricate another prototype with 64 × 64 radiating slots for a field test. The proposed prototype is capable of maintaining the received power to be greater than 15 dB for an effective isotropic radiated power of 40.7 dBm at 25 m, which demonstrates that the proposed antenna is suitable to replace current parabolic dish antennas with a reduced profile.

Published
2022

31. Time-Domain Eddy Current and Wake Fields Analysis of Pulsed Multipole Magnet Beam Injector in Synchrotron Radiation Ring

Author

Takumi Muramatsu, Masahiro Katoh, Masahito Hosaka, Yoshifumi Takashima, and Hideki Kawaguchi

Subjects
Physics, business.industry, Synchrotron radiation, Injector, Ring (chemistry), Electronic, Optical and Magnetic Materials, law.invention, Optics, law, Magnet, Eddy current, Time domain, Electrical and Electronic Engineering, business, Multipole expansion, Beam (structure)
Published
2022

32. High-Spatial-Resolution High-Temperature Sensor Based on Ultra-Short Fiber Bragg Gratings With Dual-Wavelength Differential Detection

Author

Jun He, He Li, Baijie Xu, Shengzhen Lu, Yiping Wang, Gaixia Xu, Kuikui Guo, Xizhen Xu, and Shen Liu

Subjects
Materials science, business.industry, Grating, Laser, Temperature measurement, Atomic and Molecular Physics, and Optics, law.invention, Core (optical fiber), Full width at half maximum, Optics, Fiber Bragg grating, law, Insertion loss, business, Tunable laser
Abstract

Type II fiber Bragg gratings (FBGs) inscribed with femtosecond (fs) laser possess significant potential for high temperature sensing. In this work, we propose and demonstrate a method for fabricating a parallel-integrated ultra-short type II FBG (PI-US-FBG) by using an fs laser point-by-point technology. The PI-US-FBG, featuring by an ultra-short grating length of 80 m, consists of six identical FBGs parallel-inscribed into a fiber core at different radial positions in the same cross section. The fabricated PI-US-FBG exhibits a broadband Gaussian-shape spectrum with a low reflectivity of ~10%, an ultra-low out-of-band insertion loss of 0.01 dB, and a large full width at half maximum bandwidth of 9.4 nm. Moreover, this PI-US-FBG could be used as a high temperature sensor with a wide measurement range from 25 to 1000 C, and an excellent linearity was achieved with a dual-wavelength differential detection. The temperature sensitivity could be increased from 0.00316 to 0.00945 (dB/C) by enlarging the wavelength spacing of the tunable laser. In addition, two cascaded PI-US-FBGs were used to precisely measure the temperature field distribution in a CO2 laser spot with a very high spatial resolution of 100 m. Hence, the proposed PI-US-FBGs could be used for a large-scale fiber sensor network, especially in future distributed temperature measurement with a high spatial resolution.

Published
2022

33. Overall Non-Mechanical Spectrally Steered LiDAR Using Chirped Amplitude-Modulated Phase-Shift Method

Author

Shinji Yamashita, Chao Zhang, Takuma Shirahata, Zheyuan Zhang, and Sze Yun Set

Subjects
Physics, Signal processing, business.industry, Ranging, Laser, Signal, Atomic and Molecular Physics, and Optics, law.invention, Wavelength, Lidar, Amplitude, Optics, Modulation, law, business
Abstract

We propose and demonstrate an overall non-mechanical spectrally steered laser rangefinder using the dispersion-tuned swept laser (DTSL) and a passive diffractive element. The DTSL has no mechanical moving parts, making it possible to achieve an inertial-free high wavelength sweeping speed. The inherent intensity-modulation characteristic of the DTSL allows the modulation phase-shift method to be applied, similar to that used for an amplitude-modulated continuous-wave (AMCW) rangefinder. Since the pulse repetition rate of the DTSL is chirped, standard signal processing techniques for AMCW are not applicable. In this paper, we propose a novel chirped amplitude-modulated phase-shift (CAMPS) method with a signal processing technique to obtain the phase-shift information from a chirped amplitude-modulated signal. As a proof of concept, we demonstrated the CAMPS LiDAR with an axial ranging resolution of ~50 m at a scanning speed of 10 kHz.

Published
2022

34. Spectral Dependence of Photovoltaic Cell Conversion Efficiency for Monochromatic Radiation

Author

M. Takesawa and T. Saito

Subjects
Physics, business.industry, Energy conversion efficiency, Photovoltaic system, Irradiance, Physics::Optics, Radiation, Photodiode, law.invention, Wavelength, Solar cell efficiency, Optics, law, Optoelectronics, business, Absorption (electromagnetic radiation)
Abstract

Theoretical limit of solar cell conversion efficiency given by Shockley and Queisser is calculated for the case that the cell is illuminated by solar radiation. If the input radiation is monochromatic, the efficiency can exceed the limit. The aim of our study is to experimentally demonstrate this theoretical prediction and to obtain the experimental results of spectral dependence of photovoltaic cell conversion efficiency. Conversion efficiencies of two types of Si photodiodes (equivalent to solar cells) are determined through the measurements of current–voltage characteristics as a function of the wavelength and the incident radiant power. As the theory predicts, it has been confirmed that the conversion efficiency is almost proportional to the wavelength and also to the logarithm of the incident radiant power. Also, it has been experimentally confirmed that the power conversion efficiency for long wavelength monochromatic radiation is higher than that for white radiation.

Published
2022

35. Mantle-Cloak Antenna by Controlling Surface Reactance of Dielectric-Loaded Dipole Antenna

Author

Masato Tadokoro, Teruki Miyazaki, Naobumi Michishita, Hisashi Morishita, and Thanh Binh Nguyen

Subjects
Surface (mathematics), Computer Networks and Communications, business.industry, Computer science, Reactance, Cloak, Dielectric, Mantle (geology), law.invention, Optics, law, Dipole antenna, Electrical and Electronic Engineering, Antenna (radio), business, Software
Published
2022

37. Microsized Graphene Helmholtz Resonator on Circular Dielectric Rod: A Tunable Sub-THz Frequency-Selective Scatterer

Author

Alexander I. Nosich, Vladimir Volski, Guy A. E. Vandenbosch, Sergii V. Dukhopelnykov, and Alexander Ye. Svezhentsev

Subjects
Materials science, Terahertz radiation, Graphene, Scattering, business.industry, Physics::Optics, Resonance, Dielectric, Method of moments (statistics), law.invention, Resonator, Optics, law, Electrical and Electronic Engineering, business, Helmholtz resonator
Abstract

A novel miniature THz resonator consisting of a finite-length slotted graphene cylinder wrapped around an infinite circular dielectric rod is proposed. A full-wave 3D electromagnetic scattering model is built using the method of moments (MoM) solution of the electric-field integral equation (EFIE) in the spectral domain. In order to gain better understanding of the associated physical effects, the obtained results are compared with a 2D model where the slotted graphene cylinder is assumed infinite. A good agreement between the 3D and 2D models if found. The dependence of the backscattering radar cross-section on the frequency is analyzed. It is found that in both cases this scatterer displays quasi-static Helmholtz resonance response in the sub-THz frequency range, a behavior previously known for perfectly electrically conducting (PEC) slotted cylinders. For both models, in-resonance surface current distributions and far-zone radiation patterns are given. The most important innovation is that due to the use of graphene the Helmholtz-mode resonance becomes electrically tunable.

Published
2022

39. Evolution of a C-antidipole or C-dipole passing through an astigmatic lens

Author

Shan Hu, Haitao Chen, and Zenghui Gao

Subjects
Physics, business.industry, Gaussian, Physics::Optics, General Physics and Astronomy, law.invention, Through-the-lens metering, Lens (optics), Dipole, symbols.namesake, Optics, law, Position (vector), symbols, Degree of polarization, business
Abstract

The evolution of a C-antidipole and a C-dipole embedded in Gaussian beams in the presence of an astigmatic lens is studied, respectively. After the passage of the beams carrying a C-antidipole through the lens, four C-points with the same topological charges appear in the fields. Their position and degree of polarization may change, but their number and the handedness don't change with variations of the propagation distance, the off-axis parameter and the astigmatic coefficient. On the other hand, the evolution of the C-dipole passing through the lens is more complicated. In addition to the change of their position and degree of polarization, the handedness of the same C-point may change, and the creation or disappearance of C-dipoles may occur by varying the relevant parameters.

Published
2022

40. Polarization- and Frequency-Reconfigurable Patch Antenna Using Gravity-Controlled Liquid Metal

Author

Lei Li, Hong C. Zhang, Xu Yan, and Qing Wang

Subjects
Physics, Patch antenna, Reconfigurable antenna, business.industry, Linear polarization, Polarization (waves), law.invention, Microstrip antenna, Optics, law, Electrical and Electronic Engineering, Antenna (radio), business, Passband, Circular polarization
Abstract

This letter presents a reconfigurable antenna that uses gravity to control the self-circulation of liquid metal (LM), thereby realizing an adaptive reconstruction method. Then the polydimethylsiloxane (PDMS) structure with a square ring channel is loaded on the microstrip antenna, and the contact position between the liquid metal and the patch is controlled by gravity, which provides conditions for reconfiguration. The antenna has four reconfigurable frequency bands, which can be switched between the dual circle polarization (left-and right-hand circular polarization) mode and the linear polarization (LP) mode without additional mechanical adjustment structures, radio frequency circuits or related components. The measured results show that the proposed antenna has -10 dB impedance band of 1.2-1.6 GHz, 2.5-2.75 GHz, 4.2-4.55 GHz and 5-5.4 GHz and peak gain of 3.6 dBi, 5.07 dBi, 2.68 dBi and 3.25 dBi within passband, which agree well with the simulated results.

Published
2022

41. Simulation accuracy enhancement with automatic parameters identification for femtosecond laser ablation

Author

Hiroyuki Kawakami, Masahiro Ueda, Hideki Aoyama, and Kazuo Yamazaki

Subjects
Materials science, business.industry, medicine.medical_treatment, System of measurement, General Engineering, Physics::Optics, Titanium alloy, Diamond, engineering.material, Ablation, Laser, law.invention, Optics, law, Femtosecond, Absorptance, Piecewise, medicine, engineering, business
Abstract

Femtosecond laser processing is a non-thermal process with less heat effect on a target material and is applied to dielectric and difficult-to-machine materials, such as titanium alloy and diamond. Femtosecond laser processing has been used for 3-dimensional shape generation in recent years, and increasing accuracy and productivity are required for such generation by femtosecond lasers. However, a 2.5-dimensional computer-aided manufacturing (CAM) system, which is mainly used in femtosecond laser processing, does not satisfy the requirement for complicated 3-dimensional shape generation. Therefore, there is a need for the development of a 3-dimensional CAM system for high-precision and productive 3-dimensional processing. Furthermore, for the 3-dimensional CAM system, quantitative identification of a 3-dimensional removal shape through ablation is necessary. This study proposes the development of a simulation method to accurately predict the 3-dimensional removal shape through femtosecond laser processing, including the piecewise approximation of the ablation rate and absorptance correction. At the same time, a similar 3-dimensional shape as that found through the experimental results was obtained during the simulation by considering the mechanical errors of the laser processing machine in the simulation model. Furthermore, an on-machine measurement system was developed to efficiently identify the ablation parameters.

Published
2022

42. Development of an infrared laser absorption sensor for non-intrusive gas temperature measurements

Author

Daxin Wen, Liuhao Ma, Kun Duan, Kin-Pang Cheong, Wei Ren, Yu Wang, and Chaokai Yuan

Subjects
Materials science, Absorption spectroscopy, business.industry, Materials Science (miscellaneous), Far-infrared laser, Combustion, Laser, Temperature measurement, Industrial and Manufacturing Engineering, law.invention, Optics, law, Thermocouple, Materials Chemistry, Chemical Engineering (miscellaneous), Current sensor, business, Absorption (electromagnetic radiation)
Abstract

Energetic materials have extremely high volumetric and specific energy densities, making them attractive and important in combustion systems. To improve their combustion performance, reliable temperature acquirement method is highly demanded. A laser sensor was developed for in situ and quantitative measurements of gas temperature. Scanned-wavelength direct absorption spectroscopy was used for line-of-sight temperature measurements. Multiple absorption features in the near-infrared combination band (v1+v3) and mid-infrared fundamental band (v3) were selected to establish four absorption line pairs with good temperature sensitivity. Three infrared distributed feedback lasers (DFB) were used to cover the selected absorption lines. The accuracy and uncertainty of the sensor were first numerically evaluated in a wide temperature range of 1000–3000 K under different Gaussian white noise levels (5–20%). A free-space optical setup was established to experimentally evaluate the sensor performance by measuring benchmark laminar premixed flames, which were compared with additional thermocouple measurements, chemical kinetic modeling and computational fluid dynamics simulations. The good performance of the current sensor indicates the potential of being used in non-intrusive, in-situ and quantitative diagnostics of the energetic materials combustion.

Published
2022

43. Gain-Equalized Multibeam Antenna Fed by a Compact Dual-Layer Rotman Lens at K a -Band

Author

Chong He, Ronghong Jin, Jianping Li, and Haijun Fan

Subjects
Materials science, Aperture, business.industry, Phase (waves), Equalization (audio), law.invention, Lens (optics), Antenna array, Optics, Electric power transmission, law, Ka band, Electrical and Electronic Engineering, Antenna (radio), business
Abstract

This paper presents a gain-equalized Ka-band Rotman lens-fed antenna by using phase gradient transmission lines (PGTLs). With PGTLs, the variation trend of the output progressive phase differences among the feeding ports are inverted. The aperture loss of the planar antenna array is then partially compensated by the efficiency of the lens when performing a wide-angle beam scanning. Hence, gain equalization is achieved among multiple beams with an acceptable gain degradation. To reduce the total size, the Rotman lens with PGTLs, the feeding networks, and the antenna array are stacked vertically. Meanwhile, the feeding network is implemented with substrate integrated coaxial lines, suppressing the parallel-plate-mode inside the multilayer structure. In order to validate the proposed design, a compact Rotman lens fed antenna operating at 24.75-27.5 GHz (FBW=10.5%) is designed and fabricated. The results show that the gain drop of the Rotman lens-fed multibeam antenna is reduced from 4.4 dB to 1.5 dB at the design frequency of 26 GHz, covering a wide angular range between ±56∘.

Published
2022

44. Research on flexure mounts for large aperture transport mirrors of future ICF facility

Author

Wang Baoxu, Zhu Mingzhi, Fang Ji, Wu Wenkai, Tingfen Cao, and Chen Xiaojuan

Subjects
Surface (mathematics), Physics, business.industry, General Engineering, Large aperture, Residual, Mirror mount, Laser, law.invention, Interferometry, Optics, law, Plate theory, business, Inertial confinement fusion
Abstract

Surface aberrations of transport mirrors within Inertial Confinement Fusion laser facility have significant impacts on system's optical and physical performances. Mounting design of transport mirrors is challenging for the critical specifications of mirror surface aberration under extreme operation environment. This paper presents a novel and general flexure mounting method and structure for transport mirrors with various-axis towards gravity to minimize the mirror surface aberration. Key techniques involved in mirror mounting design, including theoretical modeling, numerical optimization, optomechanical structure design and analysis, and optical testing are explored. The relationship between mirror surface aberration and its use angle θ subject to gravity is clarified using thin elastic plate theory. The mounting configuration is parametrically optimized with a more comprehensive mathematical model. Optomechanical structure design and analysis of the flexure mirror mount are detailed and accomplished. The performance of the proposed mount is experimentally validated by interferometric measurements. Experimental results indicate that the designed mirror mount potentially provides the transport mirrors (with 45° ≤ θ ≤ 90° and no screw pretension) a peak-to-valley aberration level about λ/3 (λ = 632.8 nm) of the total aberration and ∼λ/4 of the residual aberration, respectively. The proposed mounting method and structure provide a feasible and promising method and technique scheme to minimize the transport mirror surface aberrations for the next generation Inertial Confinement Fusion laser facility. The paper work also represents a design effort and a beneficial attempt for analyzing and minimizing gravity aberration for large-aperture, various-axis, and rectangular flat mirrors.

Published
2022

45. Characterization of Broadband Focusing Microwave Metasurfaces at Oblique Incidence

Author

David A. Powell, Toufiq Md Hossain, Yusuf Nur Wijayanto, D. Mahmudin, and Ashif A. Fathnan

Subjects
Physics, business.industry, Phase (waves), FOS: Physical sciences, Resonance, Oblique case, Applied Physics (physics.app-ph), Physics - Applied Physics, law.invention, Dipole, Optics, Amplitude, Achromatic lens, law, Broadband, Electrical and Electronic Engineering, business, Microwave, Optics (physics.optics), Physics - Optics
Abstract

We report the characterization of an achromatic focusing metasurface at oblique incident angles. We show that in addition to the inherent off-axis aberrations that occurs due to the hyperbolic phase profile of the metasurface, the focusing performance is significantly degraded due to the meta-atoms' angular dispersion. To obtain insights into how the angular and spectral bandwidth of meta-atoms relate to the metasurface focusing performance, point-dipole models are used which incorporate different aspect's of the meta-atoms' angular response. It is emphasized that despite the meta-atoms being designed under the assumption that they support a single dipolar resonance, other resonances exist within the meta-atom geometry and become stronger at oblique incidence. These resonances disturb the designed phase and amplitude responses, resulting in lower focusing efficiency at higher incident angles. The modelling of higher order modes leads to good agreement with the experimental measurements, confirming that angular dispersion of the meta-atoms is the dominant mechanism in determining off-axis aberrations.

Published
2022

46. A Low-Profile Beam-Steering Reflectarray With Integrated Leaky-Wave Feed and 2-Bit Phase Resolution for Ka-Band SatCom

Author

Xiaowei Shi, Steven Gao, Wang Xudong, Qi Luo, Lei Chen, Jixiang Wan, Mingtao Zhang, and Qiaoshan Zhang

Subjects
Materials science, business.industry, Aperture, Beam steering, Phase (waves), Polarizer, law.invention, Resonator, Optics, law, Ka band, Electrical and Electronic Engineering, Antenna (radio), business, Beam (structure)
Abstract

A novel reflectarray (RA) with ultra-low-profile and 2-bit phase quantization beam-steering ability is presented in this paper. To reduce the profile, a Leaky-wave feed is used to excite the RA with enhanced illumination efficiency. Moreover, simultaneous sum and difference patterns are also obtained to provide beam flexibility. The entire thickness of the proposed RA is less than 3% of that of the conventional front-fed RA with the same aperture. To increase the efficiency of the RA, a novel unit cell consisting of a polarizer layer and a reflection layer is developed, which is configured to provide polarization rotation and 2-bit phase shifts by using a hybrid of tunable polarization and discrete resonator. The operation principle, theoretical explanation, and implementation of the proposed antenna are elaborated in this work. To prove the design concept and beam scanning performance, an array with 9×7 unit cells operating at Ka-band is designed and simulated firstly. 2-D beam scanning within the range of ±30° has been verified. Then, a passive prototype with 9×67 unit cells is designed, fabricated and measured. Experimental results show aperture efficiency of 35.1% and illumination efficiency of 43.4%. The developed RA is scalable, and it provides a viable low-cost solution to develop low-profile, high-gain and beam-steering array antennas for satellite applications.

Published
2022

47. Solid-state Slow-light Beam Scanner with Ultra large Field of View and High Resolution

Author

Li, Ruixiao, Hu, Shanting, Gu, Xiaodong, and KOYAMA, FUMIO

Subjects
Scanner, Materials science, Fabrication, business.industry, Slow light, Laser, Atomic and Molecular Physics, and Optics, Vertical-cavity surface-emitting laser, law.invention, Flash (photography), Optics, law, Light beam, business, Beam (structure)
Abstract

A light beam scanning technology for 3D sensing has been attracting much interest thanks to its signal-to-noise-ratio merit compared to conventional flash 3D sensing. A Solid-state beam scanner based on a vertical cavity surface emitting laser (VCSEL) with amplification function was invented. In this paper, though enlarging the length of scanner to 6mm, a narrow beam divergence of 4000 was obtained. Its intensity variation is < 40% and could be further improved by better DOE design and fabrication process. The DOE could be simply stacked on the scanner and thus the submodule size of the scanner could be managed within 7mm 1mm 1mm. We also discussed its integrability with a tunable seed laser and its application in 2D beam scanning for better signal to noise ratios.

Published
2022

48. On Cathode Position and Inclination Angle in Magnetically Shielded Hall Thrusters

Author

Yanlin Hu, Liqiu Wei, Yongjie Ding, Li Hong, Daren Yu, Chao Zhong, and Xu Zhang

Subjects
Propellant, Materials science, business.industry, Mechanical Engineering, Aerospace Engineering, Cryopump, Cathode, Hall effect thruster, law.invention, Fuel Technology, Optics, Space and Planetary Science, Position (vector), law, Electromagnetic shielding, Shielded cable, Electron temperature, business
Abstract

This study systematically investigated the influence of the position and inclination angle of an externally mounted hollow cathode in 1.35 kW magnetically shielded Hall thrusters to establish the r...

Published
2022

49. Spectral Model of High-Power Ytterbium-Raman Fiber Amplifiers

Author

Wei Liu, Jiaxin Song, Pu Zhou, and Pengfei Ma

Subjects
Ytterbium, Materials science, Relative intensity noise, business.industry, Physics::Optics, chemistry.chemical_element, Laser, Transfer function, Atomic and Molecular Physics, and Optics, Cutoff frequency, Power (physics), law.invention, Laser linewidth, symbols.namesake, Optics, chemistry, law, symbols, Physics::Atomic Physics, business, Raman spectroscopy
Abstract

In this work, we establish a comprehensive spectral model to realize effective design of high-power ytterbium-Raman fiber amplifiers (YRFAs) employing different types of Raman-pump lasers, and propose an intuitive approach for the optimization of high-power YRFAs. Quantitative comparisons with the experimental results are given in two high-power YRFAs employing Raman-pump lasers with different spectral linewidth. The consistency of measured and simulated power ratios and spectral properties of different components in the two YRFAs confirms the fidelity of the spectral model. Further theoretical analysis reveals that the impact of Raman-pump lasers on YRFAs is mainly determined by the relative intensity noise (RIN) of Raman-pump lasers up to the cutoff frequency of the pump RIN transfer function of the YRFA. Notably, the RIN of Raman-pump lasers could provide a well reference for the superior design of Raman-pump lasers in high-power YRFAs.

Published
2022

50. Polarization-Maintaining Performance of Solid-Core Anti-Resonant Fiber With Nested Circular Tubes in 3 μm Wavelength

Author

Jianquan Yao, Hao Tian, Shuai Sun, Shuai Zhang, Quan Sheng, Wei Shi, and Zhongbao Yan

Subjects
Materials science, Birefringence, business.industry, Physics::Optics, Polarizer, Laser, Polarization (waves), Atomic and Molecular Physics, and Optics, law.invention, Wavelength, Optics, law, Fiber, business, Refractive index, Order of magnitude
Abstract

We present the structural design and polarization-maintaining performance of solid-core anti-resonant fiber with two nested circular tubes in 3 m wavelength for the first time, to the best of our knowledge. Numerical simulation results indicated that laser fundamental mode could be obtained by filling the specially designed fiber model with materials of different refractive indices to form the completely solid configuration. We calculated the bend loss of fiber to demonstrate the preferable birefringence performance and outstanding light-confining ability. With the structural deformations from resonant tubes, the birefringence coefficient was enhanced significantly from 210-5 to 6.9310-5, which was of great importance in the polarization sensitive systems. In particular, when nested circular tubes were moved to introduce deformations, the confined loss difference in two orthogonal polarizations was calculated more than two orders of magnitude, which was the desirable result to promote the fabrication of the linear polarizer in 3 m wavelength.

Published
2022

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