Agricultural Land Dryness Distribution Using the Normalized Difference Drought Index (NDDI) Algorithm on Landsat 8 Imagery in Eromoko, Indonesia

Q3 Environmental Science

Environment and Natural Resources Journal Pub Date : 2023-01-30 DOI:10.32526/ennrj/21/202200157

M. Mujiyo, Ramadhina Nurdianti, K. Komariah, S. Sutarno

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引用次数: 0

Abstract

The study area, Eromoko, has agricultural land covering 79.76% of the area, which experiences drought every year, causing a decrease in crop yields. Information on agricultural land dryness is needed to reduce the impact of dryness conditions on the agricultural sector. The effect of drought can be minimized using the transformation of the Normalized Difference Drought Index (NDDI) algorithm on Landsat 8 Imagery because it is considered capable of being used for land drought analysis that is accurate and efficient in time and cost. This study created a model for estimating soil moisture with actual soil moisture as the dependent variable and NDDI as the independent variable in several agricultural land uses in Eromoko. The results showed that the estimation model could estimate soil moisture with accuracy in plantations at 85.31%, irrigated paddy fields at 75.99%, rainfed paddy fields at 76.62%, and moors at 88.48%. The dryness category in the study area is 3,314.82 ha (35% of the total area). The variability of land use greatly affects the drying conditions. Dryness conditions can be reduced by controlling the dryness factors. Mitigation efforts to maintain soil moisture include irrigation planning based on the estimation model, applying bio-mulch and organic mulch, organic fertilization, and meeting water requirements in the harvesting period.

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基于归一化干旱指数(NDDI)算法的印尼Eromoko地区Landsat 8影像农业用地干旱分布

研究区Eromoko有79.76%的农业用地，每年都经历干旱，导致作物产量下降。为了减少干旱条件对农业部门的影响，需要有关农业土地干旱情况的信息。使用归一化干旱指数(NDDI)算法在Landsat 8图像上的转换可以最大限度地减少干旱的影响，因为它被认为能够用于土地干旱分析，在时间和成本上是准确和高效的。本研究建立了以实际土壤水分为因变量，以NDDI为自变量的Eromoko几种农用地土壤水分估算模型。结果表明:该模型在人工林、灌溉水田、雨养水田和沼地土壤水分估算精度分别为85.31%、75.99%、76.62%和88.48%。研究区干旱区面积为3314.82 ha，占总面积的35%。土地利用的变异性对干旱条件影响很大。干燥条件可以通过控制干燥因素来减少。保持土壤湿度的缓解措施包括基于估算模型的灌溉规划、应用生物地膜和有机地膜、有机施肥以及满足收获期的用水需求。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Environment and Natural Resources Journal Environmental Science-Environmental Science (all)

CiteScore

1.90

自引率

0.00%

发文量

审稿时长

8 weeks

期刊介绍： The Environment and Natural Resources Journal is a peer-reviewed journal, which provides insight scientific knowledge into the diverse dimensions of integrated environmental and natural resource management. The journal aims to provide a platform for exchange and distribution of the knowledge and cutting-edge research in the fields of environmental science and natural resource management to academicians, scientists and researchers. The journal accepts a varied array of manuscripts on all aspects of environmental science and natural resource management. The journal scope covers the integration of multidisciplinary sciences for prevention, control, treatment, environmental clean-up and restoration. The study of the existing or emerging problems of environment and natural resources in the region of Southeast Asia and the creation of novel knowledge and/or recommendations of mitigation measures for sustainable development policies are emphasized. The subject areas are diverse, but specific topics of interest include: -Biodiversity -Climate change -Detection and monitoring of polluted sources e.g., industry, mining -Disaster e.g., forest fire, flooding, earthquake, tsunami, or tidal wave -Ecological/Environmental modelling -Emerging contaminants/hazardous wastes investigation and remediation -Environmental dynamics e.g., coastal erosion, sea level rise -Environmental assessment tools, policy and management e.g., GIS, remote sensing, Environmental -Management System (EMS) -Environmental pollution and other novel solutions to pollution -Remediation technology of contaminated environments -Transboundary pollution -Waste and wastewater treatments and disposal technology