Predicting sorghum moisture content with radiofrequency dielectric functions

Q2 Engineering
Pedro Amorim Berbert , Karina de Jesus Soares , Eros Estevão de Moura , Marília Amorim Berbert-Molina , Marcia Terezinha Ramos de Oliveira , Ana Paula Martinazzo
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引用次数: 0

Abstract

Accurate grain and food moisture content (mc) estimation is an issue of great economic importance in agro-food industry operations such as drying, storage, and processing. Nonetheless, there is a high level of unmet need for on-line mc sensing that could lead to more reliable grain processing automation. Dielectric models that relate product mc to its relative permittivity ε′ and loss factor ε" are considered promising solutions for continuous measurement of moisture in grain. The object of this paper was to investigate the applicability of three dielectric models derived from the function [(ε' – 1)/ε"] for mc measurement of sorghum from 7 to 23% w.b. Of the three dielectric models tested, the most satisfactory was the function [(ε′-1)/ε"]/[(2√ε′)/(1+√ε′)] at 0.1 and 1.0 MHz. However, the moisture range had to be divided into two intervals. The corresponding equations could estimate sorghum mc with standard errors of calibration of 0.6 and 0.7, and standard errors of prediction of 0.6 and 0.8 percentage point moisture, for calibration and validation sets respectively. Comparison of the results obtained here with those reported in literature revealed that the function [(ε′-1)/ε"]/[(2√ε′)/(1+√ε′)] produced mc values which are well within the performance of commercial moisture meters.

用射频介电函数预测高粱水分含量
准确的粮食和食品水分含量(mc)估算是农业食品工业操作(如干燥,储存和加工)中具有重要经济意义的问题。尽管如此,对在线mc传感的需求仍未得到满足,这可能导致更可靠的粮食加工自动化。将产品mc与其相对介电常数ε '和损耗因子ε '联系起来的介电模型被认为是谷物中水分连续测量的有前途的解决方案。本文的目的是研究由[(ε' -1)/ε"]函数推导出的三种介电模型在7 ~ 23% w.b范围内对高粱的mc测量的适用性。在测试的三种介电模型中,最令人满意的是0.1和1.0 MHz下的[(ε' -1)/ε"]/[(2√ε ')/(1+√ε ')]函数。然而,湿度范围必须分为两个区间。相应的方程可以估算出校准集和验证集高粱水分的标准误差分别为0.6和0.7个百分点,预测水分的标准误差分别为0.6和0.8个百分点。本文所得结果与文献报道的结果比较表明,函数[(ε ' -1)/ε ']/[(2√ε ')/(1+√ε ')]产生的mc值完全符合商用湿气仪的性能。
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来源期刊
Engineering in Agriculture, Environment and Food
Engineering in Agriculture, Environment and Food Engineering-Industrial and Manufacturing Engineering
CiteScore
1.00
自引率
0.00%
发文量
4
期刊介绍: Engineering in Agriculture, Environment and Food (EAEF) is devoted to the advancement and dissemination of scientific and technical knowledge concerning agricultural machinery, tillage, terramechanics, precision farming, agricultural instrumentation, sensors, bio-robotics, systems automation, processing of agricultural products and foods, quality evaluation and food safety, waste treatment and management, environmental control, energy utilization agricultural systems engineering, bio-informatics, computer simulation, computational mechanics, farm work systems and mechanized cropping. It is an international English E-journal published and distributed by the Asian Agricultural and Biological Engineering Association (AABEA). Authors should submit the manuscript file written by MS Word through a web site. The manuscript must be approved by the author''s organization prior to submission if required. Contact the societies which you belong to, if you have any question on manuscript submission or on the Journal EAEF.
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