• 한국산학기술학회논문지
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• 제22권2호
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• pp.507-513
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• 2021

본 연구는 노면 흔적이 발생하지 않은 충돌 사고 사례를 중심으로 양 차량의 최종 정지 위치 및 자세, 차량 파손 부위, 노면 흔적, 차량의 제원, 충돌 각도. 충돌 속도, 제동 여부, 조향 여부 등의 자료를 토대로 교통 사고 분석을 위해 사용하는 차량 충돌 해석 시뮬레이션 프로그램인 PC-CRASH을 이용하여 시뮬레이션을 수행하였다. 차대 차 사고에서 충격 자세, 제동 여부, 최종 정지 위치, 충격 지점 및 충돌 속도는 사고 재구성을 위한 중요한 요소이다. 특히, 충돌 속도는 가장 중요한 쟁점이다. SM5와 렉서스의 충돌 속도는 각각 131km/h, 74km/h, SM5와 렉서스의 충돌각은 각각 0.91°, -161.07°으로 분석되었다. 사고 원인은 교차로를 통과하는 SM5가 최고 제한 속도를 61km/h 초과하여 렉서스의 좌회전 차로로 진입하였고, 렉서스는 충돌을 회피하기 위한 과정에서 충돌하였다. 시뮬레이션의 충돌 궤적 오차율은 약 1.4%이다. 사고 조사자의 주관적인 경험에서 벗어나 충돌 역학 및 차량 공학 측면과 시뮬레이션을 적극 활용하여 사실에 근접한 원인 규명을 제시하였다.

• 수산해양기술연구
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• 제45권2호
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• pp.106-113
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• 2009

For the safety and cost reduction in the navigation, the automatic and intelligent system has been developed for the vessel, and the most important factor in the system is to decide the collision risk exactly. In this paper, we propose an advanced collision risk decision system for collision avoidance of the system. The conventional researches using DCPA and TCPA for calculating the collision risk have a problem to produce a same collision risk regardless of bearings for the ships, if they are located in the same distance from own ship. To solve this problem, in addition to DCPA and TCPA, we introduce the factor of VCD(variation of compass degree) and constant, CR which derived from COLREG'72(International Regulation for Preventing Collision at Sea, 1972) for evaluating the collision risk including even the burden of own ship navigator due to the encountering angle of each vessels. We decided the collision risk legally by the rule considering the relative situation of vessels. And therefore, the proposed system has two advantages, of which one is to produce more detail collision risk and another is to reflect the real underway situation in conformity with the rule.

• 자동차안전학회지
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• 제5권1호
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• pp.44-49
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• 2013

This paper presents a lateral collision risk index between an ego vehicle and a rear-side vehicle. The lateral collision risk is designed to represent a lateral collision risk and provide the appropriate threshold value of activation of the lateral collision management system such as the Blind Spot Detection(BSD). The lateral collision risk index is designed using the Time to Line Crossing(TLC) and the longitudinal collision index at the predicted TLC. TLC and the longitudinal collision index are calculated with the signals from the exterior sensor such as the radar equipped on the rear-side of a vehicle and a vision sensor which detects the distance and time to the lane departure. For the robust situation assessment, the perception of driving environment determining whether the road is straighten or curved should be determined. The relative motion estimation method has been proposed with the road information via the integrated estimator using the environment sensors and vehicle sensor. A lateral collision risk index was composed with the estimated relative motion considering the relative yaw angle. The performance of the proposed lateral collision risk index is investigated via computer simulations conducted using the vehicle dynamics software CARSIM and Matlab/Simulink.

• 한국자동차공학회논문집
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• 제8권4호
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• pp.177-185
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• 2000

The deformation characteristics is one of the major factors to resume the crash configuration in collision accident reconstruction. Crash analysis are carried out using finite element method and body stiffness equations representing force-deformation relationship are derived, Two different crash conditions : 1) frontal barrier impact 2) frontal impact between cars are given for the derivation of the equations. The stiffness coefficient of equation by method 2) is larger than that by method. 1). Crash analysis between two vehicles is accomplished with three crash angles and three velocities for each angle condition. The deformations are measured for six selected points and deformation energies are calculated using the derived equations. Equation by method 2) results in better estimation of deformation energy than that by method 1) for all crush configurations. The estimated energies can be utilized as one of indices to identify the type of the collision accident result.

• 한국군사과학기술학회지
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• 제15권3호
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• pp.266-271
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• 2012

The rescue methods for the marine casualties are limited due to the characteristics of operation environment of the vessel. Especially the most of marine accidents have been occurred at the bow structure of ship. Moreover the failure of bow structure may lead to catastrophic mishaps. In this paper, the extents of damage of a bow structure fracture subject to collision accident was investigated by using numerical method. The computer simulation approach by using Finite Element Method was employed to accomplish this goal. A finite element model, a 3D model of ship, has been utilized to evaluate damage of bow structure according to collision scenario. In conclusion, we have demonstrated that the plastic deformation occurred at the bow structure. Also it was shown that the collision angle clearly plays a role in determining amount of damage of ship structures.

• Bulletin of the Korean Chemical Society
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• 제29권4호
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• pp.795-798
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• 2008

The formation of complex $XeHCl^+$ in the collision-induced reaction of $Xe^+$ with HCl has been studied by use of classical dynamics procedures using the London-Eyring-Polanyi-Sato empirical potential energy surfaces. A small fraction of trajectories on the $Xe^+$ + HCl and Xe + $HCl^+$ surfaces lead to the formation of complex $XeHCl^+$ with life-times of 1-2 ps which is long enough to survive many rotations before redissociating back to the reactant state. The formation of complex $XeHCl^+$ occurs mainly from collision angle of $\Theta$ = ${45^{\circ}}$.

• 자동차안전학회지
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• 제5권2호
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• pp.32-38
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• 2013

This paper presents collision avoidance using model predictive control algorithm. A model predictive control algorithm determines lateral tire force and yaw moment and steering angle input and differential braking input is determined from lateral tire force and yaw moment. A constraint for model predictive control is designed for obstacle avoidance. A objective function is designed to minimize lateral tire force and yaw moment input and to follow changed lane after collision avoidance. The performance of proposed algorithm has been investigated via computer simulation conducted to vehicle dynamic software CARSIM and Matlab/Simulink.

• 대한산업공학회지
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• 제22권4호
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• pp.579-588
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• 1996

The purpose of this paper is to develop a method of Collision-Free Path Planning (CFPP) for an articulated robot. First, the configuration of the robot is built by a set of robot joint angles derived from robot inverse kinematics. The joint space, that is made of the joint angle set, forms a Configuration space (Cspcce). Obstacles in the robot workcell are also transformed into the Cobstacles using slice projection method. Actually the Cobstacles means the configurations of the robot causing collision with obstacles. Secondly, a connected graph, a kind of roadmap, is constructed by the free configurations in the Cspace, where the free configurations are randomly sampled from a free Cspace immune from the collision. Thirdly, robot paths are optimally determinant in the connected graph. A path searching algorithm based on $A^*$ is employed in determining the paths. Finally, the whole procedures for the CFPP method are shown for a proper articulated robot as an illustrative example.

• 한국자동차공학회논문집
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• 제19권5호
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• pp.82-91
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• 2011

In this paper, a planar model for mechanics of a vehicle/pedestrian collision incorporating road gradient is derived to evaluate the pre-collision speed of vehicle. It takes into account a few physical variables and parameters of popular wrap and forward projection collisions, which include horizontal distance traveled between primary and secondary impacts with the vehicle, launch angle, center-of-gravity height at launch, distance from launch to rest, pedestrian-ground drag factor, the pre-collision vehicle speed and road gradient. The model including road gradient is derived analytically for reconstruction of pedestrian collision accidents, and evaluates the vehicle speed from the pedestrian throw distance. The model coefficients have physical interpretations and are determined through direct calculation. This work shows that the road gradient has a significant effect on the evaluation of the vehicle speed and must be considered in accident cases with inclined road. In additions, foreign/domestic empirical cases and multibody dynamic simulation results are used to construct a least-squares fitted model that has the same structure of the analytical one that provides an estimate of the vehicle speed based on the pedestrian throw distance and the band within which the vehicle speed would be expected to be in 95% of cases.

• 수산해양기술연구
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• 제32권4호
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• pp.363-371
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• 1996

현행 국제해상충돌예방규칙에서는 침로와 속력을 유지할 의무가 있는 피추월선인 유지선, 어로에 종사중인 유지선, 횡단상태의 유지선 등의 유지선이 피항선과 아주 가까이 접근하여 피항선의 피항동작만으로 충돌을 피할 수 없을 때는 급박한 위험을 피하기 위한 조치로서 유지선의 충돌을 피하기 위한 최선의 협력동작에 관하여 규정하고 있으나, 이 규칙에서는 두 선박이 어느 정도의 거리로 접근하였을 때 유지선이 협력동작을 취하여야 하는지 안전한계의 피항개시거리에 대해서는 전혀 언급되지 않고 있다. 그러므로, 본 논문에서는 유지선의 최선의 협력동작을 취할 시점의 기준이 되는 최소피항개시거리를 선체운동학적인 관점에서 해석.연구하고, 실선시험에서 구한 11척의 소형, 중형, 대형 및 초대형 선박의 조종성능수를 이용하여 최소피항개시거리를 산출하고, 이를 검토.고찰하였다. 이 결과를 요약하면 다음과 같다. 1. 소형선, 중형선, 대형선 및 초대형선을 막론하고 어느 선박에서나 유지선이 취하여야 할 최소피항개시거리가 가장 큰 경우는 양 선박이 조우하는 침로교각이 $90^{\circ}$이며, $90^{\circ}$와 $90^{\circ}$부근의 각도(70~$90^{\circ}$)에서 충돌의 위험이 가장 높다. 2. 침로교각이 $90^{\circ}$인 경우에 유지선이 취하여야 할 최소피항개시거리는 소형선(160~650톤급 선박)에서는 그 선박 길이의 약 6.8배 이상, 중형선(2,300~3,500톤급 선박)에서는 약 9.0배 이상, 대형선(22,000~62,000톤급 선박)에서는 약 5.4배 이상, 초대형선(91,000~139,000톤급 선박)에서는 약 6.8배 이상이 되어야 한다. 3. 소형선, 중형선, 대형선 및 조대형선을 막론하고 어느 선박에서나 침로교각이 $90^{\circ}$부근의 각도(70~$90^{\circ}$)에서 유지선이 취하여야 할 안전피항개시거리는 그 선박 길이의 9배 이상이 되어야 한다. 4. 소형선, 중형선, 대형선, 및 초대형선을 막론하고, 어느 선박에서나 침로교각이 크게 둔각인 경우에는 적은 예각인 경우보다 충돌의 위험이 더 크므로 더 큰 거리를 두고 피항동작에 들어가야 한다. 5. 유지선과 피항선간에 유지선이 급박한 위험을 피하기 위하여 침로만으로 최선의 협력동작을 취하는 경우 본 논문에서 계산한 각 침로교각에 대한 최소피항개시거리와 안전피항개시거리을 미리 염두해 두고 피항조선을 하게 되면, 감각에 의한 조선방법으로 야기되는 충돌해난사고를 지양 할 수 있으리라 사료된다.