Aquaphotomics determination of nutrient biomarker for spectrophotometric parameterization of crop growth primary macronutrients using genetic programming

IF 7.7 Q1 AGRICULTURE, MULTIDISCIPLINARY
Ronnie Concepcion II , Sandy Lauguico , Jonnel Alejandrino , Elmer Dadios , Edwin Sybingco , Argel Bandala
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引用次数: 20

Abstract

Water quality assessment is currently based on time-consuming and costly laboratory procedures and numerous expensive physicochemical sensors deployment. In response to the trend of device minimization and reduced outlays in sustainable aquaponic water monitoring, the integration of aquaphotomics and computational intelligence is presented in this paper. This study used the combination of temperature, pH, and electrical conductivity sensors in predicting crop growth primary macronutrient concentration (nitrate, phosphate, and potassium (NPK)), thus, limiting the number of deployed sensors. A total of 220 water samples collected from an outdoor artificial aquaponic pond were temperature perturbed from 16 to 36 °C with 2 °C increments to mimic ambient range, which varies water compositional structure. Aquaphotomics was applied on ultraviolet, visible light, and near-infrared spectral regions, 100 to 1 000 nm, to determine NPK compounds. Principal component analysis emphasized nutrient dynamics through selecting the highly correlated water absorption bands resulting in 250 nm, 840 nm, and 765 nm for nitrate, phosphate, and potassium respectively. These activated water bands were used as wavelength protocols to spectrophotometrically measure macronutrient concentrations. Experiments have shown that multigene symbolic regression genetic programming (MSRGP) obtained the optimal performance in parameterizing and predicting nitrate, phosphate, and potassium concentrations based on water physical properties with an accuracy of 87.63%, 88.73%, and 99.91%, respectively. The results have shown the established 4-dimensional nutrient dynamics map reveals that temperature significantly strengthens nitrate and potassium above 30 °C and phosphate below 25 °C with pH and electrical conductivity ranging between 7 and 8 and 0.1 to 0.2 mS cm−1 respectively. This novel approach of developing a physicochemical estimation model predicted macronutrient concentrations in real-time using physical limnological sensors with a 50% reduction of energy consumption. This same approach can be extended to measure secondary macronutrients and micronutrients.

Abstract Image

用遗传程序测定作物生长主要常量营养素的分光光度参数化的营养生物标志物
目前的水质评估是基于耗时且昂贵的实验室程序和大量昂贵的物理化学传感器的部署。针对可持续水共生监测中设备最小化和费用降低的趋势,提出了水共生学与计算智能相结合的方法。本研究使用温度、pH和电导率传感器的组合来预测作物生长的主要宏量营养素浓度(硝酸盐、磷酸盐和钾(NPK)),从而限制了部署传感器的数量。从室外人工水共生池中采集220个水样,在16 ~ 36°C范围内以2°C的增量进行温度扰动,以模拟环境范围,从而改变水的组成结构。在100 ~ 1 000 nm的紫外、可见光和近红外光谱区采用水光组法测定氮磷钾化合物。主成分分析强调养分动态,通过选择高度相关的吸水带,硝酸盐、磷酸盐和钾分别在250 nm、840 nm和765 nm吸水。这些活化水带被用作波长协议分光光度法测量常量营养素浓度。实验结果表明,多基因符号回归遗传规划(MSRGP)在基于水体物理性质参数化和预测硝酸盐、磷酸盐和钾浓度方面具有最优的性能,精度分别为87.63%、88.73%和99.91%。结果表明,建立的4维营养动态图显示,温度显著增强了30°C以上的硝酸盐和钾,25°C以下的磷酸盐,pH和电导率分别在7 ~ 8和0.1 ~ 0.2 mS cm−1之间。这种开发物理化学估算模型的新方法使用物理湖泊传感器实时预测宏量营养素浓度,能耗降低50%。同样的方法可以扩展到测量次级宏量营养素和微量营养素。
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来源期刊
Information Processing in Agriculture
Information Processing in Agriculture Agricultural and Biological Sciences-Animal Science and Zoology
CiteScore
21.10
自引率
0.00%
发文量
80
期刊介绍: Information Processing in Agriculture (IPA) was established in 2013 and it encourages the development towards a science and technology of information processing in agriculture, through the following aims: • Promote the use of knowledge and methods from the information processing technologies in the agriculture; • Illustrate the experiences and publications of the institutes, universities and government, and also the profitable technologies on agriculture; • Provide opportunities and platform for exchanging knowledge, strategies and experiences among the researchers in information processing worldwide; • Promote and encourage interactions among agriculture Scientists, Meteorologists, Biologists (Pathologists/Entomologists) with IT Professionals and other stakeholders to develop and implement methods, techniques, tools, and issues related to information processing technology in agriculture; • Create and promote expert groups for development of agro-meteorological databases, crop and livestock modelling and applications for development of crop performance based decision support system. Topics of interest include, but are not limited to: • Smart Sensor and Wireless Sensor Network • Remote Sensing • Simulation, Optimization, Modeling and Automatic Control • Decision Support Systems, Intelligent Systems and Artificial Intelligence • Computer Vision and Image Processing • Inspection and Traceability for Food Quality • Precision Agriculture and Intelligent Instrument • The Internet of Things and Cloud Computing • Big Data and Data Mining
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