An Elliptically Polarized Wave Injection Technique via Tf/Sf Boundary in Subdomain Level DGTD Method

Han, X. F.; Li, Hang; Zhou, Yifei; Wang, Lin; Liang, Shangqing; Javaid, Fawad

doi:10.2528/pier22022204

Cited by 4 publications

(2 citation statements)

References 37 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…To verify the absorber's performance, we performed a simulation using the finite‐difference time domain method; other numerical algorithm methods are used for verification, and the results are consistent. [ 44–46 ] The material parameters of Ti and Al 2 O 3 were obtained from Rakić [ 47 ] and Querry, [ 48 ] respectively. The light is vertically incident along the negative direction of the z ‐axis, and the electric field propagates along the x ‐axis.…”

Section: Modeling and Simulationmentioning

confidence: 99%

Broadband and Energy‐Concentrated Absorber Based on Hemispherical‐Embedded Structure

Liang

Shi

et al. 2023

Advanced Photonics Research

View full text Add to dashboard Cite

Spatially concentrated absorption is able to form local hotspots and helps to generate hot electrons with higher energy than free electrons, which can be used to improve the performance of hot electron devices. Herein, a broadband, wide‐angle, and highly concentrated metamaterial absorber operating in near‐infrared and midinfrared bands is proposed. The absorptivity of the proposed absorber exceeds 90% in the wavelength range of 2.0–5.4 μm, and the average absorptivity at 2.0–5.4 μm reaches 93.5%. Moreover, the absorber can highly concentrate the energy of the incident light on a point on the bottom surface of the device; the area with concentrated energy only accounts for 1.4% of the total area of the bottom, thus forming a hotspot. Meanwhile, the absorber can still maintain an average absorptivity of more than 85% when the incident light angle of various polarization directions reaches 60°. These characteristics enable the device to provide a solution to improve the performance of hot electrons, energy collection, and imaging devices.

show abstract

Section: Modeling and Simulationmentioning

confidence: 99%

Broadband and Energy‐Concentrated Absorber Based on Hemispherical‐Embedded Structure

Liang

Shi

et al. 2023

Advanced Photonics Research

View full text Add to dashboard Cite

show abstract

“…This makes the NDT technique a complex and time-consuming process. An alternate approach to solve this problem is the Time Domain (TD) method in which field distribution is assumed as a general function of time [16]. The notable advantage of the TD method is its applicability to a wide range of frequencies and the ability to detect the small defects in the specimen by observing the changes in the received signals.…”

Section: Introductionmentioning

confidence: 99%

Non-Destructive Detection of Pipe Line Cracks Using Ultra Wide Band Antenna with Machine Learning Algorithm

Venkatesan

Kalimuthu

2023

ACES Journal

View full text Add to dashboard Cite

In this article, an Ultra-Wide Band (UWB) antenna for the pipeline crack detection process is proposed. A UWB antenna has been designed with the dimension of 32 x 32 mm2 and it resonates from 3 GHz to 10.8 GHz. The designed antenna produces a peak gain of 4.36 dB. A pair of UWB antennas are employed in various pipeline scenarios and the received pulse from antenna 1 to antenna 2 is used for further processing and detection of pipeline cracks. Through the suitable machine learning data classifier algorithm the dimension of the crack has been detected. The various features such as mean, standard deviation (σ), mean average deviation (mad), skewness, and kurtosis have been extracted from the received pulse. Then the three different machine learning algorithms namely Support Vector Machine (SVM), k-Nearest Neighbor (kNN), and Naïve Bayse (NB) were trained and tested using extracted features, and the dimension of the void has been identified. Out of these three machine learning algorithms, kNN provides better accuracy and precision. It predicts the small cracks with 100% accuracy having a dimension as small as 1 mm width.

show abstract

Magnitude‐Controlled Phase Based on Euler's Formula

Sun

Sima

et al. 2023

Advanced Optical Materials

View full text Add to dashboard Cite

Phase manipulation plays a fundamental role in electromagnetic (EM) and optics research, i.e., the wavefront shaping depends heavily on phase modulation. However, the previous phase manipulation methods are limited to phase‐angle dimensionality, and the magnitude and phase are generally deemed as two distinct characters that should be controlled separately. Herein, a phase manipulation method in which phase is modulated by magnitude is proposed that follows an EM expression of Euler's formula. A rotation phase of linearly‐polarized waves is presented. Using this method, several unique applications in this research are demonstrated. First, a Hall effect of non‐angular‐momentum waves is obtained; second, an interdigital topology model with a unique topological‐charge control strategy is presented; and finally, the method is applied to holographic imaging, of which information of the hologram is recorded as a distribution of magnitude. Furthermore, as this method is applicable to all forms of harmonic waves, it can be potentially applied to other areas of wave phenomena such as acoustics and mechanics.

show abstract

An Elliptically Polarized Wave Injection Technique via Tf/Sf Boundary in Subdomain Level DGTD Method

Cited by 4 publications

References 37 publications

Broadband and Energy‐Concentrated Absorber Based on Hemispherical‐Embedded Structure

Broadband and Energy‐Concentrated Absorber Based on Hemispherical‐Embedded Structure

Non-Destructive Detection of Pipe Line Cracks Using Ultra Wide Band Antenna with Machine Learning Algorithm

Magnitude‐Controlled Phase Based on Euler's Formula

Contact Info

Product

Resources

About