• 한국항공우주학회지
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• 제44권5호
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• pp.407-415
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• 2016

본 논문에서는 최적의 항공 영상 융합을 위하여 적응 가이디드 필터 기반 알고리즘을 제안하였다. 제안한 적응 가이디드 필터는 가이디드 필터 설계 요소 중에서 정규화 파라미터 값을 입력된 영상 특성에 따라서 조절하고 PSNR (peak signal to noise ratio)을 미리 정해둔 값으로 유지한다. 제안한 방법은 입력 영상의 특성에 관계없이 미리 정한 PSNR을 유지하는 범위 내에서 잡음을 제거하므로 최적의 영상 융합 성능의 결과를 가져올 수 있다. 필터 성능은 시뮬레이션을 통해 검증하였고, 기존에 많이 사용되고 있는 영상융합 품질 파라미터를 이용하여 분석하였다.

• 품질경영학회지
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• 제34권4호
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• pp.40-50
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• 2006

The authors aimed to analyze the quality improvement efficiency of wound dressing with 2-octyl cyanoacrylate(2-OCA) in stereotactic image guided linear or sigmoid incisions in a cohort of consecutive craniotomy patients, and to compare clinical results with those of iodine-dressing and silk sutured patients underwent conventional craniotomy surgery with large pedicle flap incisions without stereotactic guidance. In methods, 26 patients were involved as the study group at one hospital. We retrospectively compared their results with those of 38 consecutive control patients at the same unit. The suggested new medical material, 2-octyl cyanoacrylate(2-OCA), resultantly decreased or prevented the contaminated fluid influx from scalp outside. The mean infection rate for the control group (7.89%) was relatively higher than that of the study group (3.85%). In addition, the use of stereotactic image guided craniotomy was significant to reduce operation time, to simplify operative procedures and to decrease potential risk factors.

• 방송공학회논문지
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• 제23권4호
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• pp.474-483
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• 2018

본 논문에서는 가이디드 이미지 필터를 이용한 다중 스케일 넓은 동적 영역 톤 매핑 알고리듬을 제안한다. 가이디드 이미지 필터는 이미지를 베이스 레이어와 디테일 레이어로 나누기 위해 사용된다. 이때 디테일 레이어의 동적 영역을 줄이기 위해 압축 함수가 사용된다. 하지만 대부분의 경우의 이미지는 다양한 스케일의 디테일과 에지 정보를 포함하고있다. 즉, 특정 스케일로 디테일 특성을 표현하는 것은 불가능하며 단일 스케일 이미지 분할 방법은 에지 주변에서 열화 현상을 야기시킨다. 이러한 문제를 해결하기 위해 다중 스케일 이미지 분할 방법을 제안한다. 다중 스케일의 디테일 레이어들을 이용하여 에지 보존 정도를 조절한다. 실험 결과를 통해 제안하는 알고리듬이 기존의 알고리듬 보다 에지 보존의 정도가 더 우수함을 보인다.

• Journal of Information Processing Systems
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• 제15권6호
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• pp.1296-1305
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• 2019

To solve the problem of poor noise suppression capability and frequent loss of edge contour and detailed information in current fusion methods, an infrared and visible light image fusion method based on variational multiscale decomposition is proposed. Firstly, the fused images are separately processed through variational multiscale decomposition to obtain texture components and structural components. The method of guided filter is used to carry out the fusion of the texture components of the fused image. In the structural component fusion, a method is proposed to measure the fused weights with phase consistency, sharpness, and brightness comprehensive information. Finally, the texture components of the two images are fused. The structure components are added to obtain the final fused image. The experimental results show that the proposed method displays very good noise robustness, and it also helps realize better fusion quality.

• 한국방송∙미디어공학회:학술대회논문집
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• 한국방송∙미디어공학회 2018년도 하계학술대회
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• pp.59-62
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• 2018

In this paper, we propose a contrast enhancement algorithm using guided image filter (GIF). The GIF is used to divide an HDR image into a base layer and a detail layer. The energy scale of base layer determinate the darkness and brightness of the image. However, the detail information in the base layer is difficult to be displayed because of the high brightness and clusters of low brightness. We propose a contrast enhancement method by adjusting the gray level of base layer by subtracting the mean value of itself. It is combined with the detail layer to preserve the detail information. Experiment results show that the proposed algorithm has better performance in detail preservation and contrast enhancement.

• 한국의학물리학회지:의학물리
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• 제33권4호
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• pp.37-52
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• 2022

Over the past decades, radiation therapy combined with imaging modalities that ensure optimal image guidance has revolutionized cancer treatment. The two major purposes of using imaging modalities in radiotherapy are to clearly delineate the target prior to treatment and set up the patient during radiation delivery. Image guidance secures target position prior to and during the treatment. High quality images provide an accurate definition of the treatment target and the possibility to reduce the treatment margin of the target volume, further lowering radiation toxicity and improving the quality of life of cancer patients. In this review, the various types of image guidance modalities used in radiation therapy are distinguished into ionized (kilovoltage and megavoltage image) and nonionized imaging (magnetic resonance image, ultrasound, surface imaging, and radiofrequency). The functional aspects, advantages, and limitation of imaging using these modalities are described as a subsection of each category. This review only focuses on the technological viewpoint of these modalities and any clinical aspects are omitted. Image guidance is essential, and its importance is rapidly increasing in modern radiotherapy. The most important aspect of using image guidance in clinical settings is to monitor the performance of image quality, which must be checked during the periodic quality assurance process.

• 대한방사선치료학회지
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• 제17권2호
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• pp.95-103
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• 2005

목 적 : 정위적 방사선수술 시 환자의 set up을 정확히 하며 정확한 종양의 위치를 찾아내어 확인하고 평가하는 것은 치료성적을 좌우하는데 매우 중요한 일이다. 특히 체부에 종양이 있는 환자의 경우 호흡 등에 의한 종양의 움직임으로 인하여 정확한 종양위치에 치료를 시행하는데는 많은 어려움이 따르는데 이러한 문제점들을 보완하기 위하여 본원에서 자체 제작한 고정용구를 이용하여 환자의 움직임을 최소화시키고 또한 환자의 호흡에 따른 CT 영상을 획득하였으며 이를 통하여 Image Guided Radiosurgery를 시행함으로써 방사선수술의 정확성을 높이고자 한다. 대상 및 방법 : 본원에서 자체 개발한 Body SRS용 Vacuum cushion (BSRS Vacuum cushion)을 이용하여 환자의 호흡에 따른 CT영상을 세 번에 걸쳐 획득한 후 (shallow, inhalation, exhalation) RTP computer상에서 이들을 fusion하며 Global GTV (PTVsim target)를 찾아내어 가장 적합한 수술계획을 수립한다. 수술 전 위와 같은 방법으로 Global GTV (PTVtx target)를 찾아내어 Posterior Pb ball을 기준으로 처음 수립된 수술계획의 PTVsim target에 PTVtx target을 조합시켜 비교함으로써 환자의 New PTVcenter를 찾아내고 수술을 시행한 후 EPID 영상을 획득하며 환자의 움직임 여부와 정확한 방사선수술이 시행되었는지 확인한다. 결 과 : 환자의 호흡에 따른 target volume의 위치는 Inhalation에서 cranio-caudal 방향으로 최대 10 mm까지 변화되었으며 체적은 Shallow respiration 일 때 $0.93cm^3$로 가장 크게 변화되는 것을 확인할 수 있었다. 수술 전후의 CT 영상을 통하여 New PTVcenter target volume의 위치에 따른 치료 정확성을 DVH로 분석한 결과 100% 전후의 치료 선량이 조사되는 것을 확인할 수 있었다. 결 론 : 체부의 SRS는 환자의 호흡에 따른 종양의 움직임 때문에 환자의 적용에는 회의적인 입장이었으나 고정기구 개발과 IGRT를 접목함으로써 보다 정확한 방사선수술을 시행할 수 있었고 이를 통하여 많은 BSRS에 적용할 수 있을 것으로 사료된다.

• 대한핵의학회:학술대회논문집
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• 대한핵의학회 2003년도 제25차 연수교육
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• pp.55-61
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• 2003

• 한국의학물리학회:학술대회논문집
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• 한국의학물리학회 2005년도 제30회 춘계학술대회
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• pp.68-70
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• 2005

To precisely localize target in prostate cancer, image-guided radiotherapy was performed using the $ExacTrac^{\circledR}$ x-ray system (Brainlab, Germany) with implanted markers. For three prostate cancer patients, three gold markers were implanted into prostate. Orthogonal portal images were acquired every treatment and CT scans were repeated 3～5 times during the course of treatment. After correcting setup errors calculated by the system, the position of the implanted markers and the distance between them were detected in daily portal images and in CT images, and analyzed retrospectively. Deviation of the relative position of the implanted markers and the distance between them were less than 1 mm in lateral, longitudinal, and vertical direction for three patients, both in portal images and CT images. This study reveals that image-guided radiotherapy using the $ExacTrac^{\circledR}$ system is useful to verify positioning errors and localize prostate target with implanted markers, reducing the planning target volume (PTV) margin as well as irradiation to rectum and bladder.

• 한국의학물리학회지:의학물리
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• 제32권2호
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• pp.40-49
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• 2021

Purpose: This study aimed to develop a surface-guided radiosurgery system customized for a neurosurgery clinic that could be used as an auxiliary system for improving the accuracy, monitoring the movements of patients while performing hypofractionated radiosurgery, and minimizing the geometric misses. Methods: RGB-D cameras were installed in the treatment room and a monitoring system was constructed to perform a three-dimensional (3D) scan of the body surface of the patient and to express it as a point cloud. This could be used to confirm the exact position of the body of the patient and monitor their movements during radiosurgery. The image from the system was matched with the computed tomography (CT) image, and the positional accuracy was compared and analyzed in relation to the existing system to evaluate the accuracy of the setup. Results: The user interface was configured to register the patient and display the setup image to position the setup location by matching the 3D points on the body of the patient with the CT image. The error rate for the position difference was within 1-mm distance (min, -0.21 mm; max, 0.63 mm). Compared with the existing system, the differences were found to be as follows: x=0.08 mm, y=0.13 mm, and z=0.26 mm. Conclusions: We developed a surface-guided repositioning and monitoring system that can be customized and applied in a radiation surgery environment with an existing linear accelerator. It was confirmed that this system could be easily applied for accurate patient repositioning and inter-treatment motion monitoring.