• Journal of Multimedia Information System
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• 제6권4호
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• pp.245-250
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• 2019

In this paper, we propose an ellipsoid modeling method for coding of a face depth picture. The ellipsoid modeling is firstly based on a point of a nose tip which is defined as the lowest value of the depth in the picture. The proposed ellipsoid representation is simplified through a difference of depth values between in the nose tip and in left or right boundary point of the face. Parameters of the ellipsoid are calculated through coordinates and depth values to minimize differences from the actual depth pixels. A picture is predicted by the modeled ellipsoid for coding of the face depth picture. In simulation results, an average MSEs between the face depth picture and the predicted picture is measured as 20.3.

• 제어로봇시스템학회논문지
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• 제11권8호
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• pp.688-695
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• 2005

This paper describes dynamic manipulability analysis of robotic arms moving in viscous fluid. The manipulability is a functionality of manipulator system in a given configuration under the limits of joint ability with respect to the task required to be performed. To investigate the manipulability of underwater robotic arms, a modeling and analysis method is presented. The dynamic equation of motion of underwater manipulator is derived based on the Lagrange-Euler equation considering with the hydrodynamic forces caused by added mass, buoyancy and hydraulic drag. The hydrodynamic drag term in the equation is established as analytical form using Denavit-Hartenberg (D-H) link coordination of manipulator. Two analytical approaches based oil manipulability ellipsoid are presented to visualize the manipulability of robotic arm moving in viscous fluid. The one is scaled ellipsoid which transforms the boundary of joint torque to acceleration boundary of end-effector by normalizing the torques in joint space, while the other is shifted ellipsoid which depicts total acceleration boundary of end-effector by shifting the ellipsoid as much as gravity and velocity dependent forces in work space. An analysis example of 2-link manipulator with proposed analysis scheme is presented to validate the method.

• Journal of Korean Neurosurgical Society
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• 제47권2호
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• pp.128-133
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• 2010

Objective : The secondary verification of Leksell Gamma Knife treatment planning system (LGP) (which is the primary verification system) is extremely important in order to minimize the risk of treatment errors. Although prior methods have been developed to verify maximum dose and treatment time, none have studied maximum dose coordinates and treatment volume. Methods : We simulated the skull shape as an ellipsoid with its center at the junction between the mammillary bodies and the brain stem. The radiation depths of the beamlets emitted from 201 collimators were calculated based on the relationship between this ellipsoid and a single beamlet expressed as a straight line. A computer program was coded to execute the algorithm. A database system was adopted to log the doses for $31{\times}31{\times}31$ or 29,791 matrix points allowing for future queries to be made of the matrix of interest. Results : When we compared the parameters in seven patients, all parameters showed good correlation. The number of matrix points with a dose higher than 30% of the maximal dose was within ${\pm}\;2%$ of LGP. The 50% dose volume, which is generally the target volume, differs maximally by 4.2%. The difference of the maximal dose ranges from 0.7% to 7%. Conclusion : Based on the results, the variable ellipsoid modeling technique or variable ellipsoid modeling technique (VEMT) can be a useful and independent tool to verify the important parameters of LGP and make up for LGP.

• 한국해양공학회:학술대회논문집
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• 한국해양공학회 2004년도 학술대회지
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• pp.204-209
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• 2004

This paper describes dynamic manipulability analysis of robotic arms moving in viscous fluid. The Manipulability is a functionality of manipulator system in a given configuration and under the limits of joint ability with respect to the tasks required to bt performed. To investigate the manipulability of underwater robotic arms, a modeling and analysis method are presented. The dynamic equation of motion of underwater manipulator is derived from the Lagrange - Euler equation considering with the hydraulic forces caused by added mass, buoyancy and hydraulic drag. The hydraulic drag term in the equation: is established as analytical form using Denavit - Hartenberg (D-H) link coordination of manipulator. Two analytical approaches based on Manipulability Ellipsoid are presented to visualize the manipulability of robotic arm moving in viscous fluid. The one is scaled ellipsoid which transforms the boundary of joint torque to acceleration boundary of end-effector by normalizing the torque in joint space while the other is shifted ellipsoid which depicts total acceleration boundary of end-effector by shifting the ellipsoid in work space. An analysis example of 2-link manipulator with proposed analysis scheme is presented to validate the method.

• 제어로봇시스템학회:학술대회논문집
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• 제어로봇시스템학회 2002년도 ICCAS
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• pp.104.1-104
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• 2002

$\textbullet$ Proper definition of manipulability ellipsoid $\textbullet$ Volume and directional measures of manipulability $\textbullet$ Kinematic modeling as a serial connection $\textbullet$ Configuration dependent singularity $\textbullet$ Effect of nonholonomy on manipulability $\textbullet$ Effect of end-effector positioning on manipulability $\textbullet$ Effect of serial cooperation on manipulability

• 한국컴퓨터그래픽스학회논문지
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• 제8권4호
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• pp.1-7
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• 2002

본 논문에서는 3차원 인체 형상 스캔 데이터로부터 팔, 다리형상을 복원하는 방법을 제시한다. 이 방법에서는 팔, 다리 스캔 데이터의 대략적인 형상을 나타내는 기반 곡면과 자세한 세부 현상을 나타내는 displacement 맵의 이중구조로 형상을 복원한다. 팔, 다리 부분의 스캔 데이터 형상은 골격을 따라 스윕하는 타원체로 근사되며, 이 타원체 스윕을 부드럽게 감싸는 envelope 곡면으로 기반 곡면을 생성한다. 타원체 스윕의 envelope 곡면은 빠른 계산을 위해 골격을 따라 추출되는 타원의 스윕 곡면으로 근사된다. 기반 곡면에 대한 스캔 데이터 점들의 displacement는 각 단면 타원으로의 매핑을 통해 스칼라 값으로 구해지며, 다단계 스플라인 함수를 이용하여 매개화된 displacement 맵을 구성한다. 이 과정에서 복원된 형상 위의 점들은 해당하는 타원체 상으로 매핑된다. 본 방법을 통하여 팔, 다리의 간결한 형상 표현을 추출할 수 있으며, 매핑된 타원체를 이용하여 형상을 빠르고 사실적으로 변형할 수 있다.

• 한국산업정보학회논문지
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• 제25권1호
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• pp.13-23
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• 2020

본 논문에서는 얼굴 인식 정확도에 미치는 영향을 최소화하면서 효율적으로 깊이 얼굴 영상을 압축하기 위한 양자화 변수 결정 방법을 제안한다. H.264/AVC의 양자화를 적용하여 깊이 얼굴 영상을 압축 할 때 얼굴 특징을 최대한 유지할 수 있도록 타원체 모델링의 예측 정확도와 각각의 양자화 단위 블록의 얼굴 인식에서의 중요도를 이용하여 양자화 인자를 차등적으로 부여한다. 모의실험 결과 제안된 방법을 통해 같은 압축율에서 얼굴 인식 성공률이 최대 6% 개선되었다.

• 한국전자통신학회논문지
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• 제10권2호
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• pp.177-182
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• 2015

어안렌즈의 특성으로 인해 발생하는 왜곡을 보정하는 일반적인 방법은 크게 두 가지 방법으로 분류할 수 있다. 첫 번째 방법은 렌즈의 특성을 고려한 수학적 모델링을 통한 보정 방법이고, 두 번째 방법은 렌즈의 종류와 상관없이 획득되는 영상만을 통한 보정 방법이다. 렌즈의 특성을 고려하는 경우는 렌즈의 파라미터와 실세계에 존재하는 3차원 실세계좌표와 2차원 영상좌표의 관계를 통해 기하학적으로 보정 식을 구할 수 있다. 그러나 기존 어안렌즈 보정에 관한 논문들은 구형태의 어안렌즈를 기준으로 유도되었기 때문에 타원체 형태의 어안렌즈에 대해서는 맞지 않는다. 본 논문에서는 어안렌즈를 타원체로 모델링하여 기하학적으로 보정하는 방법을 제안한다. 보정한 결과를 통해 제안한 방법이 타당한 것을 확인할 수 있다.

• Interaction and multiscale mechanics
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• 제1권1호
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• pp.103-121
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• 2008

This paper presents an optimization-based method for computing a minimal bounding ellipsoid that contains the set of static responses of an uncertain braced frame. Based on a non-stochastic modeling of uncertainty, we assume that the parameters both of brace stiffnesses and external forces are uncertain but bounded. A brace member represents the sum of the stiffness of the actual brace and the contributions of some non-structural elements, and hence we assume that the axial stiffness of each brace is uncertain. By using the $\mathcal{S}$-lemma, we formulate a semidefinite programming (SDP) problem which provides an outer approximation of the minimal bounding ellipsoid. The minimum bounding ellipsoids are computed for a braced frame under several uncertain circumstances.

• Journal of Korean Neurosurgical Society
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• 제53권2호
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• pp.102-107
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• 2013

Objective : The Leksell Gamma Knife$^{(R)}$ (LGK) is based on a single-fraction high dose treatment strategy. Therefore, independent verification of the Leksell GammaPlan$^{(R)}$ (LGP) is important for ensuring patient safety and minimizing the risk of treatment errors. Although several verification techniques have been previously developed and reported, no method has ever been tested statistically on multiple LGK target treatments. The purpose of this study was to perform and to evaluate the accuracy of a verification method (modified variable ellipsoid modeling technique, MVEMT) for multiple target treatments. Methods : A total of 500 locations in 10 consecutive patients with multiple brain tumor targets were included in this study. We compared the data from an LGP planning system and MVEMT in terms of dose at random points, maximal dose points, and target volumes. All data was analyzed by t-test and the Bland-Altman plot, which are statistical methods used to compare two different measurement techniques. Results : No statistical difference in dose at the 500 random points was observed between LGP and MVEMT. Differences in maximal dose ranged from -2.4% to 6.1%. An average distance of 1.6 mm between the maximal dose points was observed when comparing the two methods. Conclusion : Statistical analyses demonstrated that MVEMT was in excellent agreement with LGP when planning for radiosurgery involving multiple target treatments. MVEMT is a useful, independent tool for planning multiple target treatment that provides statistically identical data to that produced by LGP. Findings from the present study indicate that MVEMT can be used as a reference dose verification system for multiple tumors.