Circular fringe center location based on local gradient direction estimation

Disentangling the cellular anatomy that gives rise to human visual perception is one of the main challenges of ophthalmology. Of particular interest is the foveal pit, a concave depression located at the center of the retina that captures light from the gaze center. In recent years, there has been a growing interest in studying the morphology of the foveal pit by extracting geometrical features from optical coherence tomography (OCT) images. Despite this, research has devoted little attention to comparing existing approaches for two key methodological steps: the location of the foveal center and the mathematical modelling of the foveal pit. Building upon a dataset of 185 healthy subjects imaged twice, in the present paper the image alignment accuracy of four different foveal center location methods is studied in the first place. Secondly, state-of-the-art foveal pit mathematical models are compared in terms of fitting error, repeatability, and bias. The results indicate the importance of using a robust foveal center location method to align images. Moreover, we show that foveal pit models can improve the agreement between different acquisition protocols. Nevertheless, they can also introduce important biases in the parameter estimates that should be considered.

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Principles of adaptive element spacing in linear array antennas

Scientific Reports ◽

10.1038/s41598-021-84874-7 ◽

2021 ◽

Vol 11 (1) ◽

Author(s):

Tanzeela Mitha ◽

Maria Pour

Keyword(s):

Antenna Arrays ◽

Communication Systems ◽

Linear Array ◽

Main Idea ◽

Phase Center ◽

Array Configuration ◽

Array Antennas ◽

Center Location ◽

Novel Approach ◽

Array Performance

AbstractA novel approach to linear array antennas with adaptive inter-element spacing is presented for the first time. The main idea is based upon electronically displacing the phase center location of the antenna elements, which determine their relative coordinates in the array configuration. This is realized by employing dual-mode microstrip patch antennas as a constitutive element, whose phase center location can be displaced from its physical center by simultaneously exciting two modes. The direction and the amount of displacement is controlled by the amplitude and phase of the modes at the element level. This in turn facilitates reconfiguring the inter-element spacing at the array level. For instance, a uniformly-spaced array could be electronically transformed into a non-uniform one without any mechanical means. The proposed idea is demonstrated in two- and three-element linear antenna arrays. The technique has the potential to control the radiation characteristics such as sidelobe levels, position of the nulls, and the beamwidths in small arrays, which are useful for adaptively controlling the array performance in emerging wireless communication systems and radars.

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A Hybrid Strategic Oscillation with Path Relinking Algorithm for the Multiobjective k-Balanced Center Location Problem

Mathematics ◽

10.3390/math9080853 ◽

2021 ◽

Vol 9 (8) ◽

pp. 853

Author(s):

Jesús Sánchez-Oro ◽

Ana D. López-Sánchez ◽

Anna Martínez-Gavara ◽

Alfredo G. Hernández-Díaz ◽

Abraham Duarte

Keyword(s):

Location Problem ◽

State Of The Art ◽

Path Relinking ◽

Multiobjective Evolutionary Algorithms ◽

Demand Point ◽

High Quality ◽

Nondominated Solutions ◽

Center Location ◽

Strategic Oscillation ◽

N Demand

This paper presents a hybridization of Strategic Oscillation with Path Relinking to provide a set of high-quality nondominated solutions for the Multiobjective k-Balanced Center Location problem. The considered location problem seeks to locate k out of m facilities in order to serve n demand points, minimizing the maximum distance between any demand point and its closest facility while balancing the workload among the facilities. An extensive computational experimentation is carried out to compare the performance of our proposal, including the best method found in the state-of-the-art as well as traditional multiobjective evolutionary algorithms.

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Simultaneous Target Classification and Moving Direction Estimation in Millimeter-Wave Radar System

Sensors ◽

10.3390/s21155228 ◽

2021 ◽

Vol 21 (15) ◽

pp. 5228

Author(s):

Jin-Cheol Kim ◽

Hwi-Gu Jeong ◽

Seongwook Lee

Keyword(s):

Millimeter Wave ◽

Radar System ◽

Sensor Data ◽

Test Field ◽

Target Classification ◽

Radar Sensor ◽

Millimeter Wave Radar ◽

Direction Estimation ◽

Wave Radar ◽

Moving Direction

In this study, we propose a method to identify the type of target and simultaneously determine its moving direction in a millimeter-wave radar system. First, using a frequency-modulated continuous wave (FMCW) radar sensor with the center frequency of 62 GHz, radar sensor data for a pedestrian, a cyclist, and a car are obtained in the test field. Then, a You Only Look Once (YOLO)-based network is trained with the sensor data to perform simultaneous target classification and moving direction estimation. To generate input data suitable for the deep learning-based classifier, a method of converting the radar detection result into an image form is also proposed. With the proposed method, we can identify the type of each target and its direction of movement with an accuracy of over 95%. Moreover, the pre-trained classifier shows an identification accuracy of 85% even for newly acquired data that have not been used for training.

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The cardinality constrained inverse center location problems on tree networks with edge length augmentation

Theoretical Computer Science ◽

10.1016/j.tcs.2021.02.026 ◽

2021 ◽

Vol 865 ◽

pp. 12-33

Author(s):

Mehran Hasanzadeh ◽

Behrooz Alizadeh ◽

Fahimeh Baroughi

Keyword(s):

Edge Length ◽

Location Problems ◽

Tree Networks ◽

Center Location

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Electromechanical fields in a hollow piezoelectric cylinder under non-uniform load: flexoelectric effect

Mathematics and Mechanics of Solids ◽

10.1177/10812865211020785 ◽

2021 ◽

pp. 108128652110207

Author(s):

Olha Hrytsyna

Keyword(s):

Analytical Solutions ◽

Point Group ◽

The Body ◽

Small Scale ◽

Gradient Theory ◽

Local Mass ◽

Wide Range ◽

Mass Displacement ◽

Local Mass Displacement ◽

Local Gradient

The relations of a local gradient non-ferromagnetic electroelastic continuum are used to solve the problem of an axisymmetrical loaded hollow cylinder. Analytical solutions are obtained for tetragonal piezoelectric materials of point group 4 mm for two cases of external loads applied to the body surfaces. Namely, the hollow pressurized cylinder and a cylinder subjected to an electrical voltage V across its thickness are considered. The derived solutions demonstrate that the non-uniform electric load causes a mechanical deformation of piezoelectric body, and vice versa, the inhomogeneous radial pressure of the cylinder induces its polarization. Such a result is obtained due to coupling between the electromechanical fields and a local mass displacement being considered. In the local gradient theory, the local mass displacement is associated with the changes to a material’s microstructure. The classical theory does not consider the effect of material microstructure on the behavior of solid bodies and is incapable of explaining the mentioned phenomena. It is also shown that the local gradient theory describes the size-dependent properties of piezoelectric nanocylinders. Analytical solutions to the formulated boundary-value problems can be used in conjunction with experimental data to estimate some higher-order material constants of the local gradient piezoelectricity. The obtained results may be useful for a wide range of appliances that utilize small-scale piezoelectric elements as constituting blocks.

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