• Investigative Magnetic Resonance Imaging
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• 제23권3호
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• pp.179-201
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• 2019

Portable low-cost magnetic resonance imaging (MRI) systems have the potential to enable "point-of-care" and timely MRI diagnosis, and to make this imaging modality available to routine scans and to people in underdeveloped countries and areas. With simplicity, no maintenance, no power consumption, and low cost, permanent magnets/magnet arrays/magnet assemblies are attractive to be used as a source of static magnetic field to realize the portability and to lower the cost for an MRI scanner. However, when taking the canonical Fourier imaging approach and using linear gradient fields, homogeneous fields are required in a scanner, resulting in the facts that either a bulky magnet/magnet array is needed, or the imaging volume is too small to image an organ if the magnet/magnet array is scaled down to a portable size. Recently, with the progress on image reconstruction based on non-linear gradient field, static field patterns without spatial linearity can be used as spatial encoding magnetic fields (SEMs) to encode MRI signals for imaging. As a result, the requirements for the homogeneity of the static field can be relaxed, which allows permanent magnets/magnet arrays with reduced sizes, reduced weight to image a bigger volume covering organs such as a head. It offers opportunities of constructing a truly portable low-cost MRI scanner. For this exciting potential application, permanent magnets/magnet arrays have attracted increased attention recently. A magnet/magnet array is strongly associated with the imaging volume of an MRI scanner, image reconstruction methods, and RF excitation and RF coils, etc. through field patterns and field homogeneity. This paper offers a review of permanent magnets and magnet arrays of different kinds, especially those that can be used for spatial encoding towards the development of a portable and low-cost MRI system. It is aimed to familiarize the readers with relevant knowledge, literature, and the latest updates of the development on permanent magnets and magnet arrays for MRI. Perspectives on and challenges of using a permanent magnet/magnet array to supply a patterned static magnetic field, which does not have spatial linearity nor high field homogeneity, for image reconstruction in a portable setup are discussed.

• 한국전자파학회논문지
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• 제27권1호
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• pp.69-75
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• 2016

본 논문에서는 표적의 관측각도 변화율이 일정하지 않은 표적의 회전운동 성분의 결과로 인한, 역합성 개구면 레이다(Inverse Synthetic Aperture Radar: ISAR) 영상의 초점 저하 현상을 해결하는 회전운동보상(Rotational Motion Compensation: RMC) 기법을 제안한다. 먼저, 하나의 산란원이 존재하는 레인지 빈(range bin)을 선택한다. 다음으로, 퓨리에 변환(Fourier Transform: FT)과 다항식-위상 변환(Polynomial-Phase Transform: PPT)를 활용하여, 선택된 레인지 빈에 대한 위상함수를 추정한다. 마지막으로, 관측 각도의 변화율을 일정하게 하는 새로운 시간 변수를 정의한 후, 보간법(interpolation)을 통해 새롭게 정의된 시간변수에 대한 레이다 신호를 획득한다. 이에 대한 결과로, 관측 각도의 변화율을 일정하지 않게 하는 표적의 회전운동 성분을 제거함으로써, 초점이 맞는 ISAR 영상을 획득할 수 있다. 전함(battleship) 모델을 사용한 시뮬레이션을 통해 본 논문에서 제안된 RMC 기법의 효용성을 검증하였다.

• 비파괴검사학회지
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• 제36권4호
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• pp.259-265
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• 2016

This paper presents a study on the use of pulsed phase thermography in the measurement of thermal barrier coating thickness with a numerical simulation. A multilayer heat transfer model was ussed to analyze the surface temperature response acquired from one-sided pulsed thermal imaging. The test sample comprised four layers: the metal substrate, bond coat, thermally grown oxide and the top coat. The finite element software, ANSYS, was used to model and predict the temperature distribution in the test sample under an imposed heat flux on the exterior of the TBC. The phase image was computed with the use of the software MATLAB and Thermofit Pro using a Fourier transform. The relationship between the coating thickness and the corresponding phase angle was then established with the coating thickness being expressed as a function of the phase angle. The method is successfully applied to measure the coating thickness that varied from 0.25 mm to 1.5 mm.

• Current Optics and Photonics
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• 제7권6호
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• pp.638-654
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• 2023

Holography is generally known as a technology that records and reconstructs 3D images by simultaneously capturing the intensity and phase information of light. Two or more interfering beams and illumination of this interference pattern onto a photosensitive recording medium allow us to control both the intensity and phase of light. Holography has found widespread applications not only in 3D imaging but also in manufacturing. In fact, it has been commonly used in semiconductor manufacturing, where interference light patterns are applied to photolithography, effectively reducing the half-pitch and period of line patterns, and enhancing the resolution of lithography. Moreover, holography can be used for the manufacturing of 3D regular structures (3D photonic crystals), not just surface patterns such as 1D or 2D gratings, and this can be broadly divided into (i) holographic recording and (ii) holographic lithography. In this review, we conceptually contrast two seemingly similar but fundamentally different manufacturing methods: holographic recording and holographic lithography. We comprehensively describe the differences in the manufacturing processes and the resulting structural features, as well as elucidate the distinctions in the diffractive optical properties that can be derived from them. Lastly, we aim to summarize the unique perspectives through which each method can appear distinct, with the intention of sharing information about this field with both experts and non-experts alike.

• Imaging Science in Dentistry
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• 제37권4호
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• pp.211-215
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• 2007

Purpose: The purpose of this study was to evaluate the effect of the kV on fractal dimension of trabecular bone in digital radiographs. Materials and Methods: 16 bone cores were obtained from patients who had taken partial resection of tibia due to accidents. Each bone core along with an aluminum step wedge was radiographed with an occlusal film at 0.08 sec and with the constant film-focus distance (32 cm). All radiographs were acquired at 60, 75, and 90 kV. A rectangular ROI was drawn at medial part, distal part, and the bone defect area of each bone core image according to each kV. The directional fractal dimension was measured using Fourier Transform spectrum, and the anisotropy was obtained using directional fractal dimension. The values were compared by the repeated measures ANOVA. Results : The fractal dimensions increased along with kV increase (p < 0.05). The anisotropy measurements did not show statistically significant difference according to kV change. The fractal dimensions of the bone defect areas of the bone cores have low values contrast to the non-defect areas of the bone cores. The anisotropy measurements of the bone defect areas were lower than those of the non-defect areas of the bone cores, but not statistically significant. Conclusion: Fractal analysis can notice a difference of a change of voltage of x-ray tube and bone defect or not. And anisotropy of a trabecular bone is coherent even with change of the voltage of x-ray tube or defecting off a part of bone.

• 한국산학기술학회논문지
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• 제18권2호
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• pp.398-404
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• 2017

본 연구의 목적은 노인 여성의 약화된 천장관절 안정화를 위하여 비탄력 고정식 벨트를 적용하여 균형 능력과 낙상예방에 미치는 영향을 알아보고자 하였다. 노인 여성들은 출산과 폐경으로 천장관절의 약화 및 골반 주위근육들의 약화로 인하여 균형능력의 감소와 낙상위험률이 증가된다. 그러나 이와 관련된 연구는 불충분하다. 연구 대상자들은 실험군과 대조군으로 각각 20명씩 무작위로 배정하였으며, 비탄력 고정식 벨트를 실험군에게 적용한 후 균형 측정기를 사용하여 균형능력과 낙상 위험률을 평가하였다. 또한 비탄력 고정식 벨트를 적용한 실험군에서 하복부근육의 근두께를 초음파기기를 사용하여 실험 전후에 측정하였다. 통계방법은 연구대상자의 일반적 특성을 위하여 독립 t-검정, 균형 및 낙상지수를 위하여 $2{\times}2$ 반복 측정 분산분석 및 근두께를 위하여 짝비교 t-검정을 사용하였다. 두 그룹의 교호작용 효과는 안정성 지수(F1,38=47.24, p=0.001), 퓨리에 지수(F1,38=88.83, p=0.001), 체중분포 지수(F1,38=50.21, p=0.001) 및 낙상 지수(F1,38=21.59, p=0.001)에서 모두 통계적으로 유의하게 나타났다. 또한 비탄력 고정식 벨트를 적용한 결과 실험 후 복횡근(p=0.001)과 내복사근(p=0.001)의 근두께는 통계적으로 유의하게 증가하였다. 노인 여성들의 약화된 천장관절의 강화 및 안정화 방법으로 비탄력 고정식 벨트는 균형 및 낙상 예방에 긍정적이며 용이성, 보편성 및 경제적으로 효과적임을 알 수 있었다.