본 연구는 지형공간정보체계 기반에서 리스크 요인의 변동을 고려한 의사결정을 적용하여 정량적 평가를 수행할 수 있는 기법을 연구한 결과, 다음과 같은 결론을 얻을 수 있었다. 첫째, 리스크 요인의 변동을 고려한 의사결정을 통하여, 기존의 노선에 대한 평가를 정량적인 값으로 산출 할 수 있었으며, 이를 신설될 노선에 대하여 적용하면 도로 계획 및 기본 설계시에 객관적이고 신뢰성 있는 설계를 할 수 있을 것으로 판단된다. 둘째, 리스크 요인의 변동을 고려한 평면선형과 종단선형을 지형공간정보체계 기반에서 쉽게 추출할 수 있었으며, 도로의 계획에서 의사결정에 의한 신속한 3차원 선형 계획 및 분석이 가능하다. 셋째, 본 연구에서 구축된 정량적 평가 시스템을 이용하면 노선선정이 자동화됨으로서, 비교적 많은 비교안을 짧은 시간 내에 리스크 분석을 할 수 있으므로, 도로설계기술발전에 기여 할 수 있다고 판단된다.
Typoon Maemi landed on the southern coast of Korean Peninsula at 21:00, September 12, 2003 with a central pressure of 950 hPa. A three dimensional (3D) inundation model was established to calculate the storm surge and flooded area due to Typoon Maemi. A f
The inhibitory effects of mercury ions on the growth of barley seedlings were studied and the distribution of metal elements in the organs of treated plants was investigated by using synchrotron radiation induced X-ray emission (SRIXE). Although the treatment of mercury ions caused growth inhibition, the mercury-specific increase in variable fluorescence and the abolishment of energy-dependent quenching in broken barley chloroplasts as shown by Moon et al. (1992) were not observed in the leaves of growth-inhibited seedlings. Instead the treatment of mercury decreased Fmax and Fo values. However, Fmax/Fo ratio and photochemical and nonphotochemical quenching coefficients were not affected significantly. By SRIXE analysis of 10μM mercury chloride treated seedlings, accumulation of mercury in roots was observed after 1 hour of treatment and similar concentration was sustained for 48 hours. Relative contents of mercury was high in roots and underground nodes where seeds were attached, but was very low in leaves. Iron and zinc were also distributed mainly in the lower parts of the seedlings. However after 72 hours of treatment the contents of these metals in roots decreased and their distribution became more uniform, which may lead to death of the plants. These results suggest that the observed inhibitory effects on barley seedlings upto 48 hours after the treatment is not due to direct damages in the photosynthetic apparatus, but due to its accumulation in roots and the consequent retardation of the growth of barley seedlings. The decrease in Fmax and Fo is probably due to the decrease in chlorophyll and protein contents caused by the retardation of growth. The observed slow expansion of primary leaves could be also explained by the retardation of growth, but the fluorescence induction pattern from the leaves did not show characteristic symptoms of leaves under water stress.