Nutrient optimization for plant growth in Aquaponic irrigation using Machine Learning for small training datasets

IF 8.2 Q1 AGRICULTURE, MULTIDISCIPLINARY Artificial Intelligence in Agriculture Pub Date : 2022-01-01 DOI:10.1016/j.aiia.2022.05.001
Sambandh Bhusan Dhal , Muthukumar Bagavathiannan , Ulisses Braga-Neto , Stavros Kalafatis
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Abstract

With the recent trends in urban agriculture and climate change, there is an emerging need for alternative plant culture techniques where dependence on soil can be eliminated. Hydroponic and aquaponic growth techniques have proven to be viable alternatives, but the lack of efficient and optimal practices for irrigation and nutrient supply limits its applications on a large-scale commercial basis. The main purpose of this research was to develop statistical methods and Machine Learning algorithms to regulate nutrient concentrations in aquaponic irrigation water based on plant needs, for achieving optimal plant growth and promoting broader adoption of aquaponic culture on a commercial scale. One of the key challenges to developing these algorithms is the sparsity of data which requires the use of Bolstered error estimation approaches. In this paper, several linear and non-linear algorithms trained on relatively small datasets using Bolstered error estimation techniques were evaluated, for selecting the best method in making decisions regarding the regulation of nutrients in hydroponic environments. After repeated tests on the dataset, it was decided that Semi-Bolstered Resubstitution Error estimation technique works best in our case using Linear Support Vector Machine as the classifier with the value of penalty parameter set to one. A set of recommended rules have been prescribed as a Decision Support System, using the output of the Machine Learning algorithm, which have been tested against the results of the baseline model. Further, the positive impact of the recommended nutrient concentrationson plant growth in aquaponic environments has been elaborately discussed.

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利用机器学习对小型训练数据集进行水培灌溉中植物生长的养分优化
随着城市农业和气候变化的最新趋势,人们迫切需要能够消除对土壤依赖的替代植物栽培技术。水培和水培生长技术已被证明是可行的替代方法,但缺乏有效和最佳的灌溉和养分供应方法限制了其在大规模商业基础上的应用。本研究的主要目的是开发基于植物需求的统计方法和机器学习算法来调节水培灌溉水中的营养浓度,以实现最佳植物生长并促进水培培养在商业规模上的广泛采用。开发这些算法的关键挑战之一是数据的稀疏性,这需要使用增强误差估计方法。在本文中,几种线性和非线性算法在相对较小的数据集上训练,使用强化误差估计技术进行评估,以选择最佳方法来制定有关水培环境中营养调节的决策。经过对数据集的反复测试,我们决定使用线性支持向量机作为分类器,将惩罚参数的值设置为1,半加强的再替换误差估计技术在我们的情况下效果最好。已经使用机器学习算法的输出规定了一组推荐规则作为决策支持系统,这些规则已经针对基线模型的结果进行了测试。此外,还详细讨论了推荐营养浓度对水培环境中植物生长的积极影响。
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来源期刊
Artificial Intelligence in Agriculture
Artificial Intelligence in Agriculture Engineering-Engineering (miscellaneous)
CiteScore
21.60
自引率
0.00%
发文量
18
审稿时长
12 weeks
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