Prediction of Drying Time and Moisture Content of Wild Sage Seed Mucilage during Drying by Infrared System Using GA-ANN and ANFIS Approaches
Subject Areas : food scienceGhazale Amini 1 , Fakhreddin Salehi 2 , Majid Rasouli 3
1 - MSc of the Faculty of Agriculture, Bu-Ali Sina University, Hamedan, Iran.
2 - Associate Professor of the Department of Food Science and Technology, Bu-Ali Sina University, Hamedan, Iran.
3 - Assistant Professor of the Faculty of Agriculture, Bu-Ali Sina University, Hamedan, Iran.
Keywords: Sensitivity analysis, Subtractive clustering, Genetic algorithm, Infrared drying,
Abstract :
This study investigated the use of an adaptive neuro-fuzzy inference system (ANFIS) and genetic algorithmartificial neural network (GA-ANN) for the prediction of drying time and moisture content of wild sage seed mucilage (WSSM) in an infrared (IR) dryer. These models (ANFIS and GA-ANN) were fed with three inputs of IR radiation intensity (150, 250, and 375 W), the distance of mucilage from the lamp surface (4, 8, and 12 cm), mucilage thickness (0.5, 1, and 1.5 cm) for prediction of average drying time. Also, to predict the moisture content, these models were fed with 4 inputs IR power, lamp distance, mucilage thickness, and treatment time. The GAANN model structure that used 4 hidden neurons, and modeled the drying time of WSSM with a correlation coefficient (r) of 0.984. Also, the GAANN model with 9 neurons in one hidden layer, predicts the moisture content with a high r-value (r=0.999). The calculated r-values for the prediction of drying time and moisture content using the ANFIS-based subtractive clustering algorithm were 0.925 and 0.998, respectively, that shows a higher correlation among predicted data and experimental data. Sensitivity analysis results demonstrated that IR intensity and mucilage distance were the main factors for the prediction of drying time and moisture content of WSSM drying, respectively. In summary, the GAANN approach performs better than the ANFIS approach and this method can be applied to relevant IR drying process with satisfactory results.
Aktaş, M., Sözen, A., Amini, A. & Khanlari, A. (2017). Experimental analysis and CFD simulation of infrared apricot dryer with heat recovery. Drying Technology, 35(6), 766-783.
Al-Amoudi, R.H., Taylan, O., Kutlu, G., Can, A.M., Sagdic, O., Dertli, E. & Yilmaz, M.T. (2019). Characterization of chemical, molecular, thermal and rheological properties of medlar pectin extracted at optimum conditions as determined by Box-Behnken and ANFIS models. Food Chemistry, 271, 650-662.
Amini, G., Salehi, F. & Rasouli, M. (2021). Drying kinetics of basil seed mucilage in an infrared dryer: Application of GA-ANN and ANFIS for the prediction of drying time and moisture ratio. Journal of Food Processing and Preservation, 45(3), e15258.
Amini, G., Salehi, F. & Rasouli, M. (2022). Color changes and drying kinetics modeling of basil seed mucilage during infrared drying process. Information Processing in Agriculture, 9(3), 397-405.
Baeghbali, V., Niakousari, M., Ngadi, M.O. & Hadi Eskandari, M. (2019). Combined ultrasound and infrared assisted conductive hydro-drying of apple slices. Drying Technology, 37(14), 1793-1805.
Briki, S., Zitouni, B., Bechaa, B. & Amiali, M. (2019). Comparison of convective and infrared heating as means of drying pomegranate arils (Punica granatum L.). Heat and Mass Transfer, 55(11), 3189-3199.
Chen, M.-Y. (2013). A hybrid ANFIS model for business failure prediction utilizing particle swarm optimization and subtractive clustering. Information Sciences, 220, 180-195.
Jalal, M., Grasley, Z., Nassir, N. & Jalal, H. (2020). Strength and dynamic elasticity modulus of rubberized concrete designed with ANFIS modeling and ultrasonic technique. Construction and Building Materials, 240, 117920.
Keshavarzi, A., Sarmadian, F., Shiri, J., Iqbal, M., Tirado-Corbalá, R. & Omran, E.-S.E. (2017). Application of ANFIS-based subtractive clustering algorithm in soil Cation Exchange Capacity estimation using soil and remotely sensed data. Measurement, 95, 173-180.
Łechtańska, J.M., Szadzińska, J. & Kowalski, S.J. (2015). Microwave- and infrared-assisted convective drying of green pepper: Quality and energy considerations. Chemical Engineering and Processing: Process Intensification, 98, 155-164.
Lertworasirikul, S. (2008). Drying kinetics of semi-finished cassava crackers: A comparative study. LWT - Food Science and Technology, 41(8), 1360-1371.
Madadlou, A., Emam-Djomeh, Z., Mousavi, M.E. & Javanmard, M. (2010). A network-based fuzzy inference system for sonodisruption process of re-assembled casein micelles. Journal of Food Engineering, 98(2), 224-229.
Ojediran, J.O., Okonkwo, C.E., Adeyi, A.J., Adeyi, O., Olaniran, A.F., George, N.E. & Olayanju, A.T. (2020). Drying characteristics of yam slices (Dioscorea rotundata) in a convective hot air dryer: application of ANFIS in the prediction of drying kinetics. Heliyon, 6(3), e03555.
Rahman, M.S., Rashid, M.M. & Hussain, M.A. (2012). Thermal conductivity prediction of foods by Neural Network and Fuzzy (ANFIS) modeling techniques. Food and Bioproducts Processing, 90(2), 333-340.
Salehi, F. (2017). Rheological and physical properties and quality of the new formulation of apple cake with wild sage seed gum (Salvia macrosiphon). Journal of Food Measurement and Characterization, 11(4), 2006-2012.
Salehi, F. (2020a). Effect of common and new gums on the quality, physical, and textural properties of bakery products: A review. Journal of Texture Studies, 51(2), 361-370.
Salehi, F. (2020b). Recent advances in the modeling and predicting quality parameters of fruits and vegetables during postharvest storage: A review. International Journal of Fruit Science, 20(3), 506-520.
Salehi, F. (2020c). Recent applications and potential of infrared dryer systems for drying various agricultural products: A review. International Journal of Fruit Science, 20(3), 586-602.
Satorabi, M., Salehi, F. & Rasouli, M. (2021). The influence of xanthan and balangu seed gums coats on the kinetics of infrared drying of apricot slices: GA-ANN and ANFIS modeling. International Journal of Fruit Science, 21(1), 468-480.
Shewale, S.R. & Hebbar, H.U. (2017). Effect of infrared pretreatment on low-humidity air drying of apple slices. Drying Technology, 35(4), 490-499.