Artificial neural network (ANN) prediction of compressive strength of VARTM processed polymer composites

Seyhan, Aybeniz; Tayfur, Gökmen; Karakurt, Murat; Tanogˇlu, Metin

doi:10.1016/j.commatsci.2004.11.001

Cited by 55 publications

(19 citation statements)

References 9 publications

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“…These techniques have been widely used to solve a wide variety of problems regarding the strength of materials in many engineering fields. The following literature lists some of ANN and MLR applications in predicting strength properties of various materials [9,11,[14][15][16][17][18]. These modeling approaches have been also employed for predicting strength properties of wood and wood products.…”

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confidence: 99%

Predictive Performance of Artificial Neural Network and Multiple Linear Regression Models in Predicting Adhesive Bonding Strength of Wood

et al. 2016

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Ðàçðàáîòàíû íåéðîííàÿ ñåòü è ìíîaeåñòâåííûå ëèíåéíûå ðåãðåññèîííûå ìîäåëè äëÿ îöåíêè àäãåçèîííîé ïðî÷íîñòè äåðåâÿííûõ êîíñòðóêöèé ñ ó÷åòîì èõ âëàaeíîñòè è âðåìåíè ïîëíîé ñáîðêè ýëåìåíòîâ êîíñòðóêöèè äî èõ ïðåññîâàíèÿ. Ðåçóëüòàòû ïðîâåäåííûõ ýêñïåðèìåíòàëüíûõ èññëåäîâàíèé èñïîëüçîâàëè â ðàçðàáîòàííûõ ìîäåëÿõ. Ïîêàçàíî, ÷òî ïðè óâåëè÷åíèè âëàaeíîñòè è âðåìåíè ñáîðêè àäãåçèîííàÿ ïðî÷íîñòü âíà÷àëå ðàñòåò, à çàòåì óìåíüøàåòñÿ. Ñ ïîâûøåíèåì âðåìåíè ïîëíîé ñáîðêè àäãåçèîííàÿ ïðî÷íîñòü ñíèaeàåòñÿ. Ñðàâíåíèå ðàñ÷åòíûõ ðåçóëüòàòîâ, ïîëó÷åííûõ ñ ïîìîùüþ èñêóññòâåííîé íåéðîííîé ñåòè è ìíîaeåñòâåííûõ ëèíåéíûõ ðåãðåññèîííûõ ìîäåëåé, ñâèäåòåëüñòâóåò î ïðåèìóùåñòâå ïåðâîãî ïîäõîäà, ñîãëàñíî êîòîðîìó êîýôôèöèåíò êîððåëÿöèè R 2 = 97,7%, ñðåäíåå îòêëîíåíèå ñîñòàâëÿåò 3,587%. Óñòàíîâëåíî, ÷òî èñêóññòâåííàÿ íåéðîííàÿ ñåòü ÿâëÿåòñÿ ýôôåêòèâíîé äëÿ ïðîãíîçèðîâàíèÿ àäãåçèîííîé ïðî÷íîñòè äåðåâÿííûõ êîíñòðóêöèé, ÷òî ïîçâîëÿåò ñîêðàòèòü êîëè÷åñòâî òðóäîåìêèõ è äîðîãîñòîÿùèõ ýêñïåðèìåíòàëüíûõ èññëåäîâàíèé.Êëþ÷åâûå ñëîâà: èñêóññòâåííàÿ íåéðîííàÿ ñåòü, ïðîãíîçèðîâàíèå, íàïðÿaeåíèå ñöåïëåíèÿ, ìíîaeåñòâåííàÿ ëèíåéíàÿ ðåãðåññèÿ, ñðàâíåíèå ìîäåëåé.Introduction. The adhesive bond of wood is one of the main connection methods used in modern load-bearing constructions [1]. The quality and durability of a wooden product primarily depends on the quality of its adhesive bonding [2]. The moisture content is among the most important factors affecting the final strength and durability of adhesive bonding [3]. The prolonged exposure to high moisture content severely reduces the

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confidence: 99%

Predictive Performance of Artificial Neural Network and Multiple Linear Regression Models in Predicting Adhesive Bonding Strength of Wood

et al. 2016

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“…This approach may be used to solve highly nonlinear and complex problem by finding the optimum learning patterns of relationship between input and output variables . ANN models have been applied in various polymer applications as a predictive model for polymer properties and polymerization kinetics …”

Section: Introductionmentioning

confidence: 99%

On the Robustness of Forward and Inverse Artificial Neural Networks for the Simulation of Ethylene/1‐Butene Copolymerization

Charoenpanich

Anantawaraskul

Soares

2017

Macro Theory & Simulations

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Forward and inverse artificial neural network (ANN) models are used to describe ethylene/1‐butene copolymerization with a model catalyst having two site types. The forward ANN predicts number and weight average molecular weights, average comonomer content, and polymer yield as a function of a set of polymerization conditions, while the inverse model estimates polymerization conditions needed to produce copolymers with desired microstructures. The forward model is found to be robust and resilient to random noise introduced into the datasets. The inverse model, however, leads to multiple solutions (several polymerization conditions can produce polymers with similar microstructures) and is sensitive to random noise in the data. Although the polymerization conditions estimated from inverse ANN are different from the model data, the estimated polymerization conditions are found to provide similar microstructures even with the random noise.

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“…The ANN modeling is typically applied when the process under interest is too complex or unknown to be modeled statistically. The ANN is especially useful in modeling complex nonlinear, multidimensional functional relationships (Seyhan et al, 2005; Tompos et al, 2007).…”

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“…The ANN offers a distinct advantage over statistical models (i.e., mechanistic and empirical models) because of the elegance by which the technique can be implemented, and because no a priori assumptions about the shape of the fitting functions have to be made (Seyhan et al, 2005). ANN models do not depend on assumptions about functional form, probability distribution or smoothness, and have been proven to be universal approximators (Mittal and Zhang, 2000).…”

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confidence: 99%

“…One of the characteristics of ANN is its ability to learn the relationship between dependent and independent variables through the data itself rather than assuming the functional form of the relationship (Mittal and Zhang, 2000). Learning is a data‐driven self‐adaptive process by which experience arising from exposure to measurements of empirical phenomena is converted to knowledge, embodied in internal parameter weights of the network (Seyhan et al, 2005). This could help overcome the lack of knowledge about the crop growth process.…”

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Yield Estimation and Clustering of Chickpea Genotypes Using Soft Computing Techniques

et al. 2008

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A gronomy J our n al • Volu me 10 0 , I s sue 4 • 2 0 0 8 ABSTRACT Crop growth is a multifactorial nonlinear process and diff erent kinds of models have been developed to predict crop yield. In recent years, crop growth models have become increasingly important as major components of agriculture-related decision-support systems. Moreover, clustering is a multivariate analysis technique widely adopted in agricultural studies. Using this method, diff erent genotypes (accessions) of crops can be classifi ed and characterized. Th is paper discusses the use of soft computing techniques such as artifi cial neural networks (ANN) and fuzzy logic based approaches in regression and clustering problems. Th e ANN technology was used for modeling the correlation between crop yield and 10 yield components of chickpea (Cicer arietinum L.). Also, the fuzzy c-means (FCM) clustering technique was used for the classifi cation of 362 chickpea genotypes based on their agronomic and morphological traits. Th e ANN performed very well. Among the various ANN structures, a model of good performance was produced by 10-14-3-1 structure with a training algorithm of back-propagation and hyperbolic tangent transfer function in the hidden and output layers. Th e model was able to predict the chickpea yield data of 0.32 to 14.38 g plant -1 with a RMSE and T value of 0.0195 g plant -1 and 0.988, respectively. T statistics measures the scattering around line (1:1). When T is close to 1.0, the fi tting is desirable. Th e mean absolute error, relative error, and coeffi cient of determination between actual and predicted data were 0.0109 g plant -1 , -1.07%, and 0.991, respectively. Th e ANN model predicted 90.3% of the yield data with relative errors ranging between ±5%. Th e consequent reduction in the number of training data from 250 to 50, decreased the training RMSE, but increased the prediction error. It was found that even with a few number of patterns in the training dataset (50 patterns), the prediction error of the ANN model was in the range of acceptance for yield modeling. Obviously, with 25 × 10 3 iterations, the ANN models with 5 and 10 input variables gave almost the same estimation of the chickpea yield. Th e results of clustering showed that the FCM clustering technique can be successfully applied to classify chickpea genotypes in terms of agronomic and morphological traits.

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Artificial neural network (ANN) prediction of compressive strength of VARTM processed polymer composites

Cited by 55 publications

References 9 publications

Predictive Performance of Artificial Neural Network and Multiple Linear Regression Models in Predicting Adhesive Bonding Strength of Wood

Predictive Performance of Artificial Neural Network and Multiple Linear Regression Models in Predicting Adhesive Bonding Strength of Wood

On the Robustness of Forward and Inverse Artificial Neural Networks for the Simulation of Ethylene/1‐Butene Copolymerization

Yield Estimation and Clustering of Chickpea Genotypes Using Soft Computing Techniques

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