• 한국작물학회지
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• 제49권2호
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• pp.105-109
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• 2004

Field studies were conducted in the southeastern Korea ($36^{\circ}$N) on a commerce silt loam soil at paddy field. Seed were manually planted on 16 July 2003. Plants were planted with plant densities of 70${\times}$10 cm (row width x plant spacing), 50 x 10 cm, and 30 ${\times}$10 cm. Two seedlings per hill were taken prior to V3 stage. Fertilizer was applied prior to plant at a rate of 30-30-34 kg (N-$\textrm{P}_2\textrm{O}_5$-$\textrm{K}_2\textrm{O}$) per ha. Experimental design was a randomized complete block in a split plot arrangement with three replications. Yield from different planting densities responded similarly in three soybean cultivars and increased when planting density increased. Somyeongkong showed the highest increasing rate of yield about 26% by 338 g $\textrm{m}^{-2}$ at 30 x l0 cm compared to yield of conventional planting density (70 x 10 cm). Also, the planting density significantly affected pod and seed number and seed weight, but not seed per pod. The tallest plant appeared at 30${\times}$10 cm. The change of leaf area according to days after emergence showed differently in soybean cultivars. The highest and lowest total dry matter production per square meter appeared at 30 x 10 cm and at 70 x 10 cm, respectively. Crop growth rate (CGR) showed greater at R3∼R4 stages compared with V7∼R2 or R2∼R3 growth stages and showed the greatest at 30 x 10 cm in three soybean cultivars. As late planted soybean, there was a significant relation between seed yield and CGR, and leaf area index (LAI) according to planting densities at before and after the flowering stage. Relationship between seed yield and CGR in three planting densities showed a highly significant positive relation ($\textrm{R}^2$=0.757) at R3 to R4 stages, and significant relations ($\textrm{R}^2$=0.505, 0.617) at V7 to R2 and V2 to V3. Also, there was a highly significant positive difference between seed yield and LAI during R3 to R4 and R2 to R3 stages.

• 전기전자학회논문지
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• 제22권4호
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• pp.1012-1018
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• 2018

본 논문에서는 IoT 센서 처리를 위한 1.8V 공급전압의 CMOS SAR(Successive Approximation Register) A/D 변환기를 설계하였다. 본 논문에서 2개의 A/D 변환기를 병렬로 사용하여 샘플링 속도를 향상시킨 12비트 SAR A/D 변환기를 제안한다. 2개의 A/D 변환기 중 1개의 A/D 변환기는 12자리 비트를 모두 결정하고, 또 다른 A/D 변환기는 다른 A/D 변환기의 상위 6비트를 그대로 사용하여 전력소모와 스위칭 에너지를 최소화하였다. 두 번째 A/D 변환기는 상위 6비트를 결정하지 않기 때문에 컨트롤 회로와 SAR 로직이 필요하지 않아 면적을 최소화하였다. 또한 스위칭 에너지는 커패시터 용량과 C-DAC 내 전압 변화가 클수록 값이 커지는데 두 번째 A/D 변환기는 상위 6비트를 결정하지 않아 스위칭 에너지를 줄일 수 있다. 또한 커패시터 내 스플릿 커패시터 용량을 유닛 커패시터 용량과 동일하게 회로를 구성하여 C-DAC 내 공정오차를 줄일 수 있다. 제안하는 SAR A/D 변환기는 180nm CMOS 공정을 이용하여 설계하였고, 1.8V의 공급전압, 10MS/s의 변환속도, 10.2비트의 ENOB(Effective Number of Bit)이 측정되었다. 핵심 블록의 면적은 $600{\times}900um^2$, 총 전력소모는 $79.58{\mu}W$, FoM(Figure of Merit)는 6.716fJ/step로 확인할 수 있다.

• 한국산림과학회지
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• 제81권1호
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• pp.53-65
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• 1992

본(本) 연구(硏究)는 자연성(自然性)을 유지(維持)하고 자연생태계(自然生態系)를 보전(保全)하면서 동시에 산림휴양(山林休養)에 이용(利用)하려는 산림지역(山林地域)에서 이용객(利用客)들의 답압(踏壓)에 의하여 훼손(毁損)된 임상식생(林床植生)을 복원(復元)할 수 있는 방법을 구명(究明)하기 위하여 파종(播種), 시비(施肥) 및 표토처리(表土處理)의 요인실험(要因實驗)을 임간나지(林間裸地)에서 4년 동안 (1987~1990) 실시하였다. 경기도(京畿道) 안양시(安養市) 관악산(冠岳山) 수목원(樹木園)에서 임상식생복원실험(林床植生復元實驗)을 위하여 분할구배치법(分割區配置法)(주구(主區): 시비(施肥), 세구(細區): 표토처리(表土處理)${\times}$파종(播種)), 난괴법(亂塊法)(시비(施肥)${\times}$파종(播種))에 의한 요인실험(要因實驗)을 3반복(反復)으로 실시한 바 다음과 같은 연구결과(硏究結果)를 얻었다. 표토(表土)의 연화(軟化)를 위한 굴혈처리후(堀穴處理後) 70% 피복도(被覆度)를 나타내는 볏짚거적 피복처리(被覆處理)가 임간나지(林間裸地)에서 파종(播種)한 종자(種子)의 발아(發芽), 활착(活着) 및 생장(生長)에 미치는 효과(效果)가 가장 크게 나타났으며, 특히 볏짚거적 피복처리(被覆處理)는 표토침식지(表土浸蝕地)의 표토안정(表土安定) 및 치수활착(稚樹活着)에 미치는 효과가 양호하였고, 삽으로 파서 뒤엎은 완전표토연화처리(完全表土軟化處理)는 식생천이계열상(植生遷移系列上) 후기(後期)에 속하는 수종(樹種)들의 발아(發芽), 활착(活着) 및 초기생장(初期生長)에 특히 효과적(效果的)인 것으로 나타났다. 다년간(多年間) 계속적인 답압(踏壓)으로 임상표토(林床表土)의 토괴경도(土壞硬度)가 높아지고, 또 자생식물(自生植物)들의 종자(種子)가 잔류(殘留)할 수 있는 표토(表土)가 유실(流失)된 임간나지(林間裸地)에서 조기(早期)에 임상식생(林床植生)을 복원(復元)할 때에는 식생천이계열상(植生遷移系列上) 초기(初期)에서 중기계열(中期系列)에 속하는 자생수종(自生樹種)들을 파종(播種)하는 것이 효과적(效果的)인 것으로 나타났다. 자생식물(自生植物)들의 종자(種子)가 잔류(殘留)할 수 있는 표토(表土)가 유실(流失)된 임간나지(林間裸地)에서 임상식생복원(林床植生復元)(착생개체수(着生個體數)와 수관면적(樹冠面積))에는 파종(播種), 표토굴혈연화(表土掘穴軟化) 및 볏짚거적피복처리시(被覆處理時)에 약 3년이 소요되었다. 표사연화처리(表士軟化處理)는 처리 후 약 2년 동안 표토연화효과(表土軟化效果)가 지속되었으며 또 파종(播種) 및 표토처리(表土處理)는 활착개체수(活着個體數) 증대(增大)를 통해 표토연화(表土軟化), 낙엽퇴고정(落葉堆固定) 등 표토환경개선(表土環境改善)에 영향(影響)을 미치었다. 실험지표토(實驗地表土)의 열악(劣惡)한 물리적조건(物理的條件) 즉, 낮은 보수능(保水能)과 과건피해(過乾被害), 표토침식(表土浸蝕)으로 인한 치수(稚樹)들의 뿌리 노출과 고사(枯死) 및 양료유실(養料流失) 등으로 임상시비효과(林床施肥效果)는 대체적으로 나타나지 않았다. 그러나, 질소(窒素)와 인산시비(燐酸施肥)는 식생천이계열(植生遷移系列) 후기수종(後期樹種)들의 치수활착율(稚樹活着率)을 증진(增進)시키는 데는 효과적(效果的)이었다.

• Asian-Australasian Journal of Animal Sciences
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• 제22권6호
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• pp.836-842
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• 2009

The objectives of this study were to evaluate potential benefits of intercropping of corn with runner bean for a smallsized farming system, based on land equivalent ratio (LER) and silage yield and quality of corn intercropped with runner bean (Phaseolus vulgaris L.), in arid conditions of Turkey under an irrigation system. This experiment was established as a split-plot design in a randomized complete block, with three replications and carried out over two (consecutive) years in 2006 and 2007. Seven different mixtures (runner bean, B and silage corn sole crop, C, 10% B+90% C, 20% B+80% C, 30% B+70% C, 40% B+60%C, and 50% B+50%C) of silage corn-runner bean were intercropped. All of the mixtures were grown under irrigation. The corn-runner bean fields were planted in the second week of May and harvested in the first week of September in both years. Green beans were harvested three times each year and green bean yields were recorded each time. After the 3rd harvest of green bean, residues of bean and corn together were randomly harvested from a 1 $m^{2}$ area by hand using a clipper when the bean started to dry and corn was at the dough stage. Green mass yields of each plot were recorded. Silages were prepared from each plot (triplicate) in 1 L mini-silos. After 60 d ensiling, subsamples were taken from this material for determination of dry matter (DM), pH, organic acids, chemical composition, and in vitro DM digestibility of silages. The LER index was also calculated to evaluate intercrop efficiencies with respect to sole crops. Average pH, acetic, propionic and butyric acid concentrations were similar but lactic acid and ammonia-N levels were significantly different (p<0.05) among different mixtures of bean intercropped with corn. Ammonia-N levels linearly increased from 0.90% to 2.218 as the percentage of bean increased in the mixtures up to a 50:50 seeding ratio. While average CP content increased linearly from 6.47 to 12.45%, and average NDF and ADF contents decreased linearly from 56.17 to 44.88 and from 34.92 to 33.51%, respectively, (p<0.05) as the percentage of bean increased in the mixtures up to a 50:50 seeding ratio, but DM and OM contents did not differ among different mixtures of bean intercropped with corn (p>0.05). In vitro OM digestibility values differed significantly among bean-corn mixture silages (p<0.05). Fresh bean, herbage DM, IVOMD, ME yields, and LER index were significantly influenced by percentage of bean in the mixtures (p<0.01). As the percentage of bean increased in the mixtures up to a 50:50 seeding ratio, yields of fresh bean (from 0 to 24,380 kg/ha) and CP (from 1,258.0 to 1,563.0 kg/ha) and LER values (from 1.0 to 1.775) linearly increased, but yields of herbage DM (from 19,670 to 12,550 kg/ha), IVOMD (from 12,790 to 8,020 kg/ha) and ME (46,230 to 29,000 Mcal/ha) yields decreased (p<0.05). In conclusion, all of the bean-corn mixtures provided a good silage and better CP concentrations. Even though forage yields decreased, the LER index linearly increased as the percentage of bean increased in the mixture up to a 50:50 seeding ratio, which indicates a greater utilization of land. Therefore, a 50:50 seeding ratio seemed to be best for optimal utilization of land in this study and to provide greater financial stability for labor-intensive, small farmers.