• 한국ITS학회 논문지
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• 제16권1호
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• pp.90-100
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• 2017

보행자와 승용차의 충돌위치에 따른 전도 거리 변화를 madymo-시뮬레이션을 통하여 분석하였다. 충돌위치를 차량중심으로부터 바깥쪽으로 2.5cm간격마다 충돌하는 경우에 대하여 시뮬레이션하였다. 그 결과 보행자의 전도거리형태가 급격히 변화하는 임계점이 두 곳에서 나타났다. 첫 번째 임계점은 보행자의 어깨가 차량과 접촉되지 않는 위치였다. 두 번째 임계점의 위치는 보행자의 무게중심이 차체의 외곽선상을 벗어나기 직전의 위치였다. 첫째 임계점과 두 번째 임계점의 사이 구간에서는 충돌위치가 차량의 바깥쪽에 가까울수록 전도거리는 급격히 감소하였다. 두 임계점 사이를 벗어난 구간에서는 전도거리 변화가 크지 않은 것으로 나타났다. 충돌위치에 따른 전도거리 변화가 밝혀져서 보다 정확한 교통안전 분석과 보행자 사고해석이 가능해질 것으로 판단된다.

• 한국ITS학회 논문지
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• 제16권5호
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• pp.85-95
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• 2017

본 논문의 목적은 트럭과 보행자의 충돌사고에서 트럭의 중량, 속도와 범퍼 높이가 보행자 전도거리에 미치는 영향을 분석하고, 나아가 이를 이용한 보행자 전도거리에 대한 모형식을 제시하는 데 있다. 이를 위해 교통사고 재현 프로그램인 PC-crash를 이용하여 트럭의 중량을 5t, 15t, 25t으로 적용하고, 각 트럭의 앞 범퍼 하단 높이를 0.3m부터 0.6m까지 0.1m씩 높여감과 동시에 트럭의 속도를 10km/h부터 100km/h까지 10km/h씩 높여가며 실험하였다. 트럭의 속도와 범퍼 높이는 보행자 전도거리에 유의한 변수로 확인되었고, 트럭 중량은 보행자 전도거리에 유의하지 않은 변수로 나타났다. 또한 다중회귀분석을 이용하여 제시한 모형식은 조정된 $R^2$ 값이 93.3%로 매우 우수한 설명력을 가지는 것으로 나타났다.

• 대한교통학회지
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• 제25권4호
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• pp.69-77
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• 2007

본 연구에서는 보행자-차량 충돌사고 분석을 위한 국내외 사고재현모형을 비교하였다. 충돌 후 보행자의 전도거리를 종속변수로, 차량의 충돌속도를 독립변수로 하는 모형을 비교하였으며, 수집된 총 432건의 사고 자료 중 신뢰성 있는 전도거리와 충돌속도 자료의 확보가 가능한 49건을 선정하여 절대평균백분위오차를 산출 후 비교하였다. 또한 전도거리에 영향을 새로운 변수의 도출을 위해 차량의 전면부 형상을 조사하고 이를 변수화하여 모형 구축에 반영하였다. 분석결과 차량의 범퍼높이가 다른 변수에 비해 전도거리에 큰 영향을 미치는 것으로 나타났다. 향후 연구에서는 보다 폭넓고 많은 데이터 수집 및 분석을 통하여 신뢰성을 높은 모형개발이 이루어져야 할 것이다.

• 대한교통학회지
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• 제29권1호
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• pp.125-134
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• 2011

보행자-차량 충돌사고 재구성을 위하여 본 논문에서는 사고 현장에서 수집이 용이한 정보들을 활용하여 차량의 충돌 속도를 정확하게 추정할 수 있는 퍼지 도구를 제시한다. 200건이 넘는 국내외 사고 및 실험 자료와 700건의 다중물체 시뮬레이션 결과에 근거하여 퍼지규칙과 소속함수들을 설정하였다. 개발한 퍼지도구는 4개의 소속함수와 2개의 논리적 규칙을 사용하여 보행자 선회 궤도 유형과 차량의 충돌 속도를 추론한다. 보행자 전도거리의 소속함수는 이와 같이 추론된 궤도 유형에 따라 달리 구성하였다. 작성된 퍼지 프로그램은 국내외 실제 사고 및 실험 데이터를 활용하여 그 결과를 검증하였으며 차량의 충돌속도에서 좋은 일치를 보여주었다. 이는 본 연구를 통하여 개발한 퍼지도구의 정확성과 유용성을 입증하는 것이다.

• 동력기계공학회지
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• 제13권2호
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• pp.56-62
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• 2009

The fatalities of pedestrian account for about 40.0% of all fatalities in Korea 2005. Vehicle-Pedestrian accident generates trajectory of pedestrian. In pedestrian involved accident, the most important data to inspect accident is throw distance of pedestrian. The throw distance of pedestrian can be influenced by many variables. But existing studies have been done for simple factors. The variables that influence trajectory of pedestrian can be classified into vehicular factors, pedestrian factors, and road factors. The trajectory of pedestrian, dynamic characteristics of multi-body were analyzed by PC-CRASH, a kinetic analysis program for a traffic accident. PC-CRASH enables an analyst to investigate the effect of many variables. The influence of the offset of impact point was analyzed by Working Model. Based on the results, the variables that influence trajectory of pedestrian were vehicular frontal shape, vehicular impact speed, the offset of impact point, the height of pedestrian, friction coefficients of pedestrian. However the weight of pedestrian did not affect trajectory of pedestrian considerably.

• 한국기계가공학회지
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• 제6권3호
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• pp.71-76
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• 2007

The fatalities of pedestrian account for about 40.0% of all fatalities in Korea 2005. Vehicle-Pedestrian accident generates trajectory of pedestrian. In pedestrian involved accident, the most important data to inspect accident is throw distance of pedestrian. The throw distance of pedestrian can be influenced by many variables. The variables that influence trajectory of pedestrian can be classified into vehicular factors, pedestrian factors, and road factors. Vehicular factors are the frontal shape of vehicle, impact speed of vehicle, the offset of impact point. Many studies have been done about the relation between impact speed and throw distance of pedestrian. But the influence of the offset of impact point was neglected. The influence of the offset of impact point was analyzed by Working Model, and the trajectory of pedestrian, dynamic characteristics of multi-body were analyzed by PC-CRASH, a kinetic analysis program for a traffic accident. Based on the results, the increase of offset reduced the throw distance of pedestrian. However box type vehicle just like bus, the offset of impact point did not influence the throw distance of pedestrian considerably.

• 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.

• 한국기계가공학회지
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• 제6권3호
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• pp.105-111
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• 2007

The type of pedestrian accident can be characterized by vehicular frontal shape and the height of pedestrian. The trajectory of pedestrian after collision by passenger car is different from that by bus due to vehicular frontal shape. The frontal shape of SUV vehicles is dissimilar to passenger car and bus. So, the trajectory and throw distance of pedestrian by SUV vehicles is not the same of passenger car and bus. In this paper, a series of pedestrian kinetic simulation were conducted to inspect the difference in throw distance between SUV vehicle and passenger car and bus by PC-CRASH that is the program for kinetic analysis of articulated body. From the results, if the height of pedestrian is taller than 1.70m, there is no difference in throw distance between SUV vehicle and passenger car, but if the height of pedestrian is about 1.55m throw distance of SUV vehicle is about 4m longer than that of passenger car at each impact speed. The throw distance of pedestrian by Bus is shorter than that of passenger car and SUV at each impact speed.

• 한국자동차공학회논문집
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• 제18권3호
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• pp.104-109
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• 2010

The fatality of pedestrian accounts for about 21.2% of all fatality at 2007 year in Korea. In car to pedestrian accident it is very important to inspect the throw distance of pedestrian after collision for exact reconstructing of the accident. The variables that influence on the throw distance of pedestrian can be classified into the factors of vehicle and pedestrian, and road condition. It was simulated by PC-CRASH, a kinetic analysis program for a traffic accident in sedan type vehicle and SPSS program was used for regression analysis. From the results, the throw distance of pedestrian increased with the increasing of vehicle velocity, and decreased with the increasing of impact offset. Also it decreased with the increasing of velocity of pedestrian at accident, and throw distance at the road condition of wet was longer than that at dry condition. Finally, the regression model of sedan type vehicle on the throw distance of pedestrian was as follows; $$dist_i=2.39-0.11offset_i+0.59speed_i-545height_i-0.25walk_i+2.78wet_i+{\epsilon}_i$$.

• 동력기계공학회지
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• 제13권5호
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• pp.76-81
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• 2009

The fatalities of pedestrian account for about 21.2% of all fatalities at 2007 year in Korea. To reconstruct exactly the accident, it is important to calculate the throw distance of pedestrian in car to pedestrian accident. The frontal shape of SUV vehicle is dissimilar to passenger car and bus, so the trajectory and throw distance of pedestrian by SUV vehicle is not the same of passenger car and bus. The influencing on it can be classified into the factors of vehicle and pedestrian, and road factor. It was analyzed by PC-CRASH for simulation, and SPSS s/w was used for regression analysis. From the simulation results, the maximum impact energy of multi-body of pedestrian was occurred to that of torso body at the same time. And the throw distance increased with the increasing of impact velocity, and decreased with the increasing of impact offset. Also it decreased with the increasing of velocity of pedestrian at accident, and the throw distance of wet road was longer than that of dry road. Finally, the regression analysis model of SUV(Nissan Pathfinder type)vehicle in car to pedestrian accident was as follows; $$disti_i=-0.87-0.11offseti_i+0.69speed_i-4.27height_i+0.004walk_i+0.63wet_i+{\epsilon}_i$$.