• Proceedings of the Korean Society of Crop Science Conference
• /
• 2007.11a
• /
• pp.225.2-225.2
• /
• 2007

• Proceedings of the Korean Society of Crop Science Conference
• /
• 2007.11a
• /
• pp.225.1-225.1
• /
• 2007

• Journal of Bio-Environment Control
• /
• v.32 no.4
• /
• pp.484-491
• /
• 2023

Tomatoes in greenhouse are a widely cultivated horticultural crop worldwide, accounting for high production and production value. When greenhouse ventilation is minimized during low temperature periods, CO₂ enrichment is often used to increase tomato photosynthetic rate and yield. Plant-induced electrical signal (PIES) can be used as a technology to monitor changes in the biological response of crops due to environmental changes by using the principle of measuring the resistance value, or impedance, within the crop. This study was conducted to investigate the relationship between tomato growth data, vital response, and PIES resulting from CO₂ enrichment in greenhouse tomatoes. The growth of tomato treated with CO₂ enrichment in the morning was significantly better in all items except stem diameter compared to the control, and PIES values were also higher. The growth of tomato continuously applied with CO₂ was better in the treatment groups than control, and there was no significant difference in chlorophyll fluorescence and photosynthesis. However, PIES and SPAD values were higher in the CO₂ treatment group than control. CO₂ enrichment have a direct relationship with PIES, growth increased, and transpiration increased due to the increased leaf area, resulting in increased water absorption, which appears to be reflected in PIES, which measures vascular impedance. Through this, this study suggests that PIES can be used to monitor crops due to environmental changes, and that PIES is a useful method for non-destructively and continuously monitoring changes of crops.

• The Bimonthly Magazine for Agrochemicals and Plant Protection
• /
• v.6 no.1
• /
• pp.75-79
• /
• 1985

우리나라의 밭면적은 851천ha로서 전체 경지면적의 40$\%$에 달하고 있으나 경사지(傾斜地)가 많고 유형별(類型別)로도 숙전비율(熟田比率)이 41.8$\%$밖에 되지 않아 비옥도가 낮은 형편이다. 밭의 이용률은 ''83년에 130.9$\%$로서 일본이나 대만등에 비하여 매우 낮은 편이고 그나마 밭에서의 식량작물재배가 절반 이상 점하고 있는 실정이다. 한편 우리나라는 ''70년대 중반이후 지속적인 고도경제성장에 따른 국민생활수준의 향상으로 식품소비도 고급화 내지 다양화(多樣化)의 수요가 크게 늘어나고 있다. 오늘날 우리 농촌은 자급자족적 영농형태(自給自足的營農形態)에서 소득증대를 위한 상품생산적영농형태(商品生産的營農形態)로의 전환기에 와 있음을 감안할 때 밭농사에서의 전작목 선정 및 합리적인 각부체계 도입은 소득증대에 지름길이 될것임은 자명하다 할것이다.

• Proceedings of the Korean Society of Crop Science Conference
• /
• 2006.04a
• /
• pp.526-527
• /
• 2006

• Journal of the Korea Academia-Industrial cooperation Society
• /
• v.21 no.4
• /
• pp.471-478
• /
• 2020

This study aimed to suggest implications for the future development of agricultural R&D through a priority analysis of excellent agricultural R&D performance considering productivity, marketability, and effects on region, which are important factors of agricultural R&D evaluation. The subjects of analysis were R&D of Rural Development Administration (RDA), which was selected as national R&D excellent Performance from 2006 to 2018, and the priority was analyzed using Analytic Hierarchy Process (AHP). The results are as follows. First, the relative importance of the criteria decreased in the order of marketability(0.423) > regional impact(0.360) > productivity(0.216). Second, as a result of analyzing the relative importance of the sub-criteria, the possibility of commercialization(0.515) was high in the category of marketability. The possibility of technology expansion(0.538) was high in the category of effects on region and the quality improvement(0.464) was high in the category of productivity. Third, the excellent agricultural R&D performance that had high relative importance was the technologies associated with improving the agricultural competitiveness of horticultural crops.

• Korean Journal of Medicinal Crop Science
• /
• v.6 no.3
• /
• pp.232-238
• /
• 1998

To analyse the management and production of medicinal crops in Uisong region, cultural conditions and standard income of 147 farms were investigated. Location quotient of medicinal crops cultivated was high as following order ; Paeonia lactiflora > Cornus ofidnalis> Bupleurm falcatum > Anemarhena asphodeloides > Rehmannia glutinosa > Eucommia ulmoides > Paeonia suffruticosa > Angelica dahurica. The average cultivated area per farm was 1.92ha : 1.35ha of upland field, 0.56ha of paddy field. Distribution of agricultural land in each farm was average 10.2 fields in 3.1 locations. Ratio of labor input in the medicinal plant sector was 31.1 %. The number of medicinal crops cultivated was 36 species among 147 farms and 2.4 species per farm. Among the cultivated medicinal plant, peony (Paeonia lactiflora) was the most popular medicinal plant, which was cultivated in 30.72ha of 85 farms. Income from medicinal plants was high in order of Carthamus tinctorius, Polygonatum stenophyllum, Angelica genuilexa. Medicinal crops should be selected based on farm condition, risk level and price settlement in order to maximize productivity and income.

• Journal of Wetlands Research
• /
• v.15 no.2
• /
• pp.179-189
• /
• 2013

The Haean basin is a unique geographical feature formed by differential erosion and it borders the military demarcation line. Recently the basin has become an interest of civilians due to security tour, highland vegetables and wetland. After the civil war, the population decreased but it has increased since 2007. The annual mean air temperature in the basin has increased with a rate of $+0.016^{\circ}C/yr$ and the annual precipitation also has increased with a rate of +10.41 mm/yr. The precipitation occurring in June~August (wet season) occupied most of the total precipitation increase. In addition, recently the number of groundwater wells and its use have gradually increased and most of them are for agriculture including cultivation of rice and highland vegetables. If the air temperature further increases in the future according to the climate change scenarios, the highland vegetables cultivation will be difficult. Furthermore, if the rainstorm in the summer will be enforced, the groundwater recharge and water management will be aggravated. Therefore, an evaluation for sustainable groundwater development in the basin and a reform of the current agriculture (change of cultivating crops) depending on much water are essentially required.

• Proceedings of the Korea Water Resources Association Conference
• /
• 2015.05a
• /
• pp.549-549
• /
• 2015

물 소비는 수자원 고갈을 야기하며, 수자원 고갈은 보건, 농업 생산력, 작물 생산력, 생태계에 악영향을 미친다. 따라서 물발자국 개념을 적용하고 이를 활용함으로써 일반생활에서 패러다임의 전환을 유도하는 것은 환경 및 물 문제를 저감하는 좋은 수단이 될 수 있다. 우리나라도 물발자국 개념 도입의 적극적인 검토가 필요하다. 따라서 본 연구에서는 스페인의 사례를 통하여 물발자국 도입 방안을 도출하고자 한다. 스페인은 2008년 9월 유럽연합에서 최초로 물발자국 평가를 정책으로 채택하였다. 스페인은 물 부족 국가로서 물발자국 연구를 수행해왔으며 강 유역 및 국가적 차원의 방법론을 연구하고 검증해왔다. 특히 도시와 산업 분야에서 물의 재사용을 증대시키기 위해 통합농업 및 생태농업을 장려하고 있다. 이와 관련하여 태양에너지, 관광, 전통 작물 재배 지역의 물발자국 계정의 비교우위를 통해 환경, 농업, 에너지, 무역 정책과 관련되는 물 정책의 조정 중에 있다. 또한 지나친 용수개발로 인한 생태적 위험에 대처하기 위해 강을 상류, 중류, 하류로 나누어 작물별 가상수량과 물 효율성을 분석하였다. 이에 따른 결과로 지역마다 적합한 수출입전략으로 물 효율성이 높은 작물을 주로 재배하는 상류지역은 농산물을 다른 지역으로부터 수입하는 동시에 채소류와 같은 물 효율성이 높은 농산물을 특화하여 수출할 필요성을 농가로 제시하고 있다. 이를 통하여 스페인은 지역의 환경 조건에 가장 적합한 제품의 생산을 촉진하고 본질적인 물 사용 패턴의 변화를 통하여 효율적인 물 분배 및 사용이 가능하게 됨으로서 관개용수 사용의 감소를 실현하였다. 본 연구를 통하여 스페인은 유역관리계획의 개발을 위한 기술적 표준으로서 다양한 사회경제 분야의 물발자국 분석을 포함하고 있음을 확인하였다. 이를 통하여 물발자국 정책의 활용방안을 파악하였고, 물발자국의 도입 방향성을 도출하였다. 환경 및 물 문제를 저감할 수 있는 물발자국 개념은 향후 우리나라의 수자원 관리에 있어 중요한 지표의 역할을 할 것으로 기대한다.

• The Journal of the Korea institute of electronic communication sciences
• /
• v.16 no.3
• /
• pp.559-564
• /
• 2021

With the development of ICT, research on smart farms is steadily progressing in the agricultural field for the modernization of cultivation facilities. However, most of the current smart farms are not specific crops, but general-purpose systems that can be used in various fields. In this paper, an environmental control device and an integrated control system capable of creating a aseptic growing environment required for mushroom cultivation were proposed, and the system was designed, manufactured, and programmed. Through this, it is possible to build a smart farm optimized for crops that is needed to maintain a precise growing environment.