본 연구에서는 통계적인 방법을 통해 DSM 제작에 있어, 토지피복과 식생의 영향을 정량적으로 살펴보았다. 산림지역이 DSM과 DEM 사이의 고도 차이를 증가시키는데 가장 큰 역할을 하였으며, 수종에 따라 약간의 차이는 있지만 침엽수림과 혼효림보다 는 활엽수림의 영향이 더 큰 것으로 나타났다. 항공사진의 촬영 문제, 왜곡, 촬영 당시 형태나 위치가 변하는 문제와 그늘 지역이 통계적인 관련을 낮춘 주요 원인으로 생각된다. 통계적인 관련을 낮춘 여러 원인에도 불구하고, 본 연구의 결과는 식생에 따른 임관의 형태적 특성을 직접적으로 반영한 것으로 보인다. 본 연구와 같은 자료가 보다 쌓인다면, DSM과 DEM의 특성을 통해 산림 속성과 수종 분포와 같은 정보를 확인할 수 있을 것으로 기대된다.
이 논문은 자체 개발된 드론을 이용하여 사진측량기술을 적용하여 3차원 수치지표면모델(DSM)개발 연구를 수 행하였다. 이 DSM을 개발하기 위하여 제주도 지역을 선정하여 24장의 사진을 개발된 드론으로 직접 촬영을 수행하였 다. 촬영된 사진의 정확한 3차원 좌표를 부여하기 위하여, 10개의 지표기준점(GCP)점을 선정하여 상대측위 지구위치시 스템(DGPS)측량을 실시하였다. 사진의 정확도를 평가하기 위하여 3개의 GCP점을 선정하여 사진상의 좌표와 지상점의 좌표의 정확도를 비교하였다. 사진좌표계과 지상좌표계의 정확도를 평가한 결과 수평오차는 8.8-14.7 cm로 나타났으며, 연직오차는 12.4 cm로 나타났다. 이 정확도는 국토지리정보원(NGII)이 인정하는 1/1,000 수치지도의 정확도를 가지는 측량결과이다. 이 연구를 통하여 본 연구에서 개발된 드론과 사진측량기법이 제주지역에서 우리가 원하는 DSM자료를 얻는데 유용한 기술임을 알 수 있었다.
The train-centric control systems development has some distinct points in that a big size of government budget is in general expended in there and the development duration seems to be long. In addition, the changes are ever made continuously in the capability and operational requirements for Trains. Thus, the impact of the potential changes in the required operational capability on the development activities can induce some type of project risks [7]. As such, proper management of project risk has been one of crucial subjects in the train systems development. All these notes combined together make it the significance of the safety management process be raised further up in the train-centric control systems development. As such, the underlying safety management process should be capable of appropriately handling the potential risks that can be created due to the unexpected changes and the long-term development period. The process should also be complemented for the safety consideration of train-centric control systems, for instance, stop. To study these aspect is the objective of the paper. To do so, a step-by-step approach to analyzing the safety management process is first presented. Then, to enhance the process some necessary and useful activities are added in terms of risk and safety management. Then, to pursue some enhancement on the process, a set of necessary and useful activities are added in terms of risk and safety management. The resultant process is further analyzed and tailored using a design structure matrix method. The resultant process is applied in a train-centric control development as a case study.
The weapon systems development has some distinct characteristics in that a big size of government budget (derived from national tax) has been expended frequently and the completion of the development projects seems to take long. Thus, the impact of the potential changes in the required operational capability on the development activities can induce some type of project risks. As such, proper management of project risk has been one of crucial subjects in the weapon systems development. Although a variety of methods can be considered, an approach based on the test and evaluation (T&E) process has been selected in this paper in order to appropriately handle those potential risks. In the study of the underlying T&E process, the safety consideration (for instance, explosiveness) of weapon systems is also included. To achieve the objective of the paper, a step-by-step procedure is first presented in the analysis of the T&E process. Then, to pursue some enhancement on the process, a set of necessary and useful activities are added in terms of risk and safety management. The resultant process is further analyzed and tailored based on a design structure matrix method. The case study of a tank development is also discusse
The demand from customers on better products and systems seems to be ever increasing. To meet the demand, the systems are becoming more and more complicated in terms of both scale and functionality, thereby requiring enormous effort in the development. One bright spot of this trend is that such effort has been the driving forces of the remarkable advancement in modern systems development. On the other hand, safety issues appear to be critical in many large-scale systems such as transportation and weapon systems including high-speed trains, airplanes, ships, missiles/rockets launchers, and so on. Such systems turn out to be prone to a variety of faults and thus the resultant failure can cause disastrous accidents. For the reason, they can be referred to as safety-critical systems. The systems failure can be attributed to either random or systemic factors (or sometimes both). The objective of this paper is on how to reduce potential systemic failure in safety critical systems. To do so, a proper system design is pursued to minimize the risk of systemic failure. A focus is placed on the fact that complex systems have a lot of complicated interfaces among the system elements. To effectively handle the sources of hazards at the complicated interfaces and resultant failure, a method is developed by utilizing a design structure matrix. As a case study, the developed method is applied in the design of train control systems.
Generally, the system evolution is oriented toward the gradual diminution of human effect on the system. TRIZ is introducing the direction of technical system through the 'Law of Technology Evolution'. And Design Structure Matrix(DSM) can show the relationship among elements in a way easy to understand. Oh and Park stated that the direction of system evolution could be modeled by applying the ‘Law of Technology Evolution’ of TRIZ to DSM. This paper aims to validate the effectiveness by applying the evolution model - which applies DSM- to the hypothetical combat helicopter.
In this study, in order to determine whether this flood inundated by any route when the levee was destroyed, which can simulate the path of the flood inundation model was developed for the SIMOD(Simplified Inundation MODel). Multi direction method((MDM) for differential distributing the adjacent cells by using the slope and Flat-water assumption(FWA)-If more than one level higher in the cell adjacent to the cell level is the lowest altitude that increases the water level is equal to the adjacent cells- were applied. SIMOD model can significantly reduce simulation time because they use a simple input data of topography (DEM) and inflow flood. Therefore, predicting results within minutes will be possible, if you can only identify inflow flood through the runoff model or levee collapse model. Therefore, it could be used to establish an evacuation plan due to flooding, such as EAP (Emergency Action Plan).