• 대기
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• 제23권2호
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• pp.143-160
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• 2013

The effect of 3DVAR (Three Dimension Variational data Assimilation) was examined by comparing observation and the simulations of CNTL (to which data assimilation was not applied) and ALL (to which data assimilation was applied using ground observation data and radar data) for the case of a heavy snowfall event (case A) of 11-12 February 2011 in the Yeongdong region. In case A, heavy snow intensively came in the Yeongdong coastal region rather than Daegwallyeong, in particular, around the Gangneung and Donghae regions with total precipitation in Bukgangneung at approximately 91 mm according to the AWS observation. It can be seen that compared to CNTL, ALL simulated larger precipitation along the Yeongdong coastline extending from Sokcho to Donghae while simulating smaller precipitation for inland areas including Daegwallyeong. On comparison of the total accumulated precipitations from simulations of CNTL and ALL, and the observed total accumulated precipitation, the positive effect of the assimilation of ground observation data and radar data could be identified in Bukgangneung and Donghae, on the other hand, the negative effect of the assimilation could be identified in the Daegwallyeong and Sokcho regions. In order to examine the average accuracy of precipitation prediction by CNTL and ALL for the entire Gangwon region including the major points mentioned earlier, the three hour accumulated precipitation from simulations of CNTL and ALL were divided into 5, 10, 15, 20, 25 and 30 mm/3hr and threat Scores were calculated by forecasting time. ALL showed relatively higher TSs than CNTL for all threshold values although there were some differences. That is, when considered generally based on the Gangwon region, the accuracy of precipitation prediction from ALL was improved somewhat compared to that from CNTL.

• 대한지리학회지
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• 제47권5호
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• pp.641-653
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• 2012

강원 영동지역의 천진호와 쌍호에서 확보한 석호 퇴적물을 분석한 결과, 천진호는 AD 780에, 쌍호는 100 BC에 벼농경이 개시된 것으로 추정된다. 두 지점이 멀지 않은 거리 내에 있고 해안으로 연결되어 있음에도 불구하고 벼농경 시작 시점에 큰 차이가 나타나고 있다. 이는 화분자료를 활용하여 특정지역 벼농경문화의 정확한 전파 시점을 파악하는 것이 쉽지 않음을 시사한다. 강원 영동 지역의 경우, 낮은 농경 생산성으로 말미암아 벼농경 문화가 최초로 전파된 시점과 벼농경이 본격적으로 시작된 시점 간에 시간적인 차이가 있었던 것으로 사료된다. 천진호 및 쌍호 분석 자료 모두에서 벼농경이 본격적으로 시작된 지 약 250년 후부터 농경지시화분들의 중요도가 더욱 커지고 산지의 침식이 빠르게 증가하는 모습이 나타난다. 이는 벼농경의 활성화로 인구가 증가함에 따라 저지대에서 산지로 거주지역의 확대가 나타났고 이로 인해 산림이 영향을 받았음을 시사한다.

• 한국측량학회지
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• 제40권3호
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• pp.187-193
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• 2022

강원 영동지방에서 연안은 문화적, 사회적, 경제적으로 중요한 자원이다. 그러나 강원도 해안은 다른 지역과 비교하여 매우 심각한 침식을 겪고 있으며, 이로 인한 피해가 점차 증가할 것으로 우려된다. 본 연구에서는 강원도 양양 남대천 하구 주변과 강릉 옥계 해변의 장기간에 걸친 해안선 변화를 추적하고 분석하였다. 시계열 영상자료를 구축하기 위해 해방 직후부터 최근까지의 항공사진을 주로 이용하였으며, 1960년대부터 70년대 초까지 운용된 CORONA 위성영상을 수집하여 함께 활용하였다. 51cm 해상도 정사영상과 2m 해상도 수치고도모형(DEM)을 이용하여 기준점을 설정하고 항공사진과 위성영상을 기하보정하였다. 이들 영상에 Canny 경계검출 연산자를 적용하여 해안선을 추출하고 벡터화하였다. 해안선을 해방 직후부터 시간 순서대로 중첩하여 분석한 결과, 인공 구조물 주변과 인근 해변에서 발생한 침식과 퇴적을 관찰할 수 있었으며, 구조물 건설 시점을 전후한 주변 해안선 변화도 관찰할 수 있었다. 다만 본 연구에서는 해안선의 계절적 변화와 조석, 그리고 양빈사업을 비롯한 각종 해안침식 방지사업에 따른 영향은 고려되지 않았다. 해안침식은 지리적 요인에 크게 영향을 받기 때문에 지역마다 원인과 해결방안이 다르며, 따라서 지자체별로 지속적인 연구와 데이터 축적이 필요하다.

• 대한원격탐사학회지
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• 제34권3호
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• pp.465-480
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• 2018

2017년 1월 20일 영동 뇌설 사례는 강수 초기 3시간 동안 20 cm 이상의 강한 강설이 낙뢰와 함께 영동 해안 지역에 나타났다. 이 연구에서는 강한 강수 기간 동안 고층 관측 자료를 이용하였고, 고층 관측 장비는 북강릉 지점의 연직바람관측장비, 라디오미터 그리고 레윈존데를 사용하였다. 북강릉과 강릉원주대학교에서 강한 강수가 나타났을 때 연직 바람과 기온의 특징을 조사한 결과는 다음과 같다: 1) 2~6 km에서 강한 북동풍 그리고 4~6 km에서 $-18^{\circ}C\;km^{-1}$ 이상의 기온 감률을 보이는 강한 대기불안정이 관측되었다. 이러한 특징은 대류운이 6 km 이상 고도까지 발달하였음을 나타낸다. 2) 1 km 이하에서 기온의 감소가 나타났으며, 이것은 북강릉 지점 AWS 지상 기온이 약 30분 동안 $4^{\circ}C$ 감소한 것과 잘 일치한다. 이러한 기온 감소는 동서 방향의 좁은 영역에서 나타나고 레이더 에코와 낙뢰 분포 영역도 동일한 위치에서 관측되었다. 이것은 중위도 저기압의 한랭전선형 강수의 특징과 유사하다. 결과적으로 영동 뇌설 사례는 한랭전선형 강수와 대류성 강수의 영향이 결합된 시스템으로 분석하였다.

• 대기
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• 제25권1호
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• pp.51-66
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• 2015

This study was conducted to perform various sensitivity experiments using WRF (Weather Research and Forecasting) model in order to determine the effects of terrains of the Korean Peninsula and the land-sea thermal contrast on the formation and development of the convergent cloud band for the cases of 1 February 2012. The sensitivity experiments consist of the following five ones: CNTL experiment (control experiment), and TMBT experiment, BDMT experiment and ALL experiment that set the terrain altitude of Taeback Mountains and Northern mountain complex as zero, respectively, and the altitude of the above-mentioned two mountains as zero, and LANDSEA experiment that set to change the Korean Peninsula into sea in order to find out the land-sea thermal contrast effect. These experiment results showed that a cold air current stemming from the Siberian high pressure met the group of northern mountains with high topography altitude and was separated into two air currents. These two separated air currents met each other again on the Middle and Northern East Sea, downstream of the group of northern mountains and converged finally, creating the convergent cloud band. And these experiments suggested that the convergent cloud band located on the Middle and Northern East Sea, and the cloud band lying on the southern East sea to the coastal waters of the Japanese Island facing the East Sea, were generated and developed by different dynamical mechanisms. Also it was found that the topography of Taeback Mountains created a warm air advection region due to temperature rise by adiabatic compression near the coastal waters of Yeongdong Region, downstream of the mountains. In conclusion, these experiment results clearly showed that the most essential factor having an effect on the generation and development of the convergent cloud band was the topography effect of the northern mountain complex, and that the land-sea thermal contrast effect was insignificant.

• 대기
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• 제26권1호
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• pp.159-183
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• 2016

On 31 July 2014, there was a localized torrential rainfall ($58.5mm\;hr^{-1}$) caused by a strong convective cell with thunder showers over Daegwallyeong. In the surface synoptic chart, a typhoon was positioned in the East China Sea and the subtropical high was expanded to the Korean peninsula. A WRF (Weather Research and Forecasting) numerical simulation with a resolution of 1 km was performed for a detailed analysis. The simulation result showed a similar pattern in a reflectivity distribution particularly over the Gangwon-do region, compared with the radar reflectivity. According to the results of the WRF simulation, the process and mechanism of the localized heavy rainfall over Daegwallyeong are as follows: (1) a convective instability over the middle part of the Korean peninsula was enhanced due to the low level advection of warm and humid air from the North Pacific high. (2) There was easterly flow from the coast to the mountainous regions around Daegwallyeong, which was generated by the differential heating of the insolation among Daegwallyeong and the Yeongdong coastal plain, and nearby coastal waters. (3) In addition, westerly flow from the western part of Daegwallyeong caused a strong convergence in this region, generating a strong upward motion combined by an orographic effect. (4) This brought about a new convective cell over Daegwallyeong. And this cell was more developed by the outflow from another thunderstorm cell to the south, and finally these two cells were merged to develop as a strong convective cell with thunder showers, leading to the record breaking maximum rainfall per hour ($58.5mm\;hr^{-1}$) in July.

• 대기
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• 제30권3호
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• pp.221-236
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• 2020

The Gangneung region has the complicated geographical characteristics being adjacent to East Sea and Taeback mountains, and thus sea breeze could play an important role in local weather in various aspects. This study aims to understand overall characteristics of sea breeze largely based on long-term (2009~2018) ground-based observation data. We also propose a selection criteria of sea breeze occurrence day; 1) daily precipitation is less than 10 mm, 2) surface wind direction is 0~110° (northerly to easterly) for more than 3 hours during the daytime, 3) wind direction is 110~360° for more than 3 hours during the nighttime, and 4) land and sea temperature difference is positive during the daytime, 5) sea and land sea-level pressure difference is more than 0.5 hPa. As a result, a total of 595 days was selected for the past 10 years. The occurrence of sea breeze is the highest in late Spring to early Summer (May to June). The passage time of sea breeze at the inland station (1.6 km farther inland) is one hour later than the coastal station. On the typical sea breeze event of April 12, 2019, the passage speed and duration of sea breeze was 15 km hr^-1 and about 9 hours, respectively, with its depth of about 500 m and its head swelling. The current results emphasize the critical role of sea breeze in forecasting surface temperature and wind, and contribute to relieve heat wave especially in summer in the Yeongdong region.