Pepper is widely planted and used all over the world as fresh vegetable and spice. Genetic and morphological information of pepper are stored through seeds. Determination of seed variety is crucial for correctly identifying genetic materials. Pepper varieties cannot be easily classified even by an expert eye due to the very small size of seeds and visual similarities. Hence, more advanced technologies are required to determine the variety of a pepper seed. A classification method was proposed to discriminate pepper seed based on neural networks and computer vision. Image acquisition was conducted using an office scanner at a resolution of 1200 dpi. Image features representing color, shape, and texture were extracted and used to classify pepper seeds. By calculating features from different color components, a feature database was constructed. Effective features were selected using sequential feature selection with different criterion functions. As a result of the feature selection procedure, the number of the features was significantly reduced from 257 to 10. Cross validation rules were applied to obtain a reliable classification model by preventing overfitting. Different numbers of neurons in the hidden layer and various training algorithms were investigated to determine the best multilayer perceptron model. The best classification performance was obtained using 30 neurons in the hidden layer of the network. With this network, an accuracy rate of 84.94% was achieved using the sequential feature selection and the training algorithm of resilient back propagation in classifying eight pepper seed varieties.
Keywords: pepper seed, neural networks, variety classification, computer vision
DOI: 10.3965/j.ijabe.20160901.1790

Citation: Kurtulmuş F, Alibas İ, Kavdır I. Classification of pepper seeds using neural network. Int J Agric & Biol Eng, 2016; 9(1): 51－62.

pepper seed, neural networks, variety classification, computer vision

Chen X, Xun Y, Li W, Zhang J. Combining discriminant analysis and neural networks for corn variety identification. Computers and Electronics in Agriculture, 2010; 71: S48–S53.

Bae H, Jayaprakasha G K, Jifon J, Patil B S. Variation of antioxidant activity and the levels of bioactive compounds in lipophilic and hydrophilic extracts from hot pepper (Capsicum spp.) cultivars. Food Chemistry, 2012; 134: 1912–1918.

Alvarez-Parrilla E, de la Rosa L A, Amarowicz R, Shahidi F. Antioxidant activity of fresh and processed Jalapeño and serrano peppers. Journal of Agricultural and Food Chemistry, 2010; 59: 163–173.

Hervert-Hernández D, Sáyago-Ayerdi S G, Goñi I. Bioactive compounds of four hot pepper varieties (Capsicum annuum L.), antioxidant capacity, and intestinal bioaccessibility. Journal of Agricultural and Food Chemistry, 2010; 58: 3399–3406.

Jeong W Y, Jin J S, Cho Y A, Lee J H, Park S, Jeong S W, et al. Determination of polyphenols in three Capsicum annuum L. (bell pepper) varieties using high-performance liquid chromatography–tandem mass spectrometry: Their contribution to overall antioxidant and anticancer activity. Journal of Separation Science, 2011; 34: 2967–2974.

Granitto P M, Navone H D, Verdes P F, Ceccatto H A. Weed seeds identification by machine vision. Computers and Electronics in Agriculture, 2002; 33: 91–103.

Paliwal J, Shashidhar N S, Jayas D S. Grain kernel identification using kernel signature. Transactions of the ASAE, 1999; 42: 1921–1924.

Chen X, Xun Y, Li W, Zhang J. Combining discriminant analysis and neural networks for corn variety identification. Computers and Electronics in Agriculture, 2010; 71(1): S48–S53.

Pourreza A, Pourreza H, Abbaspour-Fard M H, Sadrnia H. Identification of nine Iranian wheat seed varieties by textural analysis with image processing. Computers and Electronics in Agriculture, 2012; 83: 102–108.

Avila F, Mora M, Fredes C. A method to estimate Grape Phenolic Maturity based on seed images. Computers and Electronics in Agriculture, 2014; 101, 76–83.

Valiente-Gonzalez J M, Andreu-Garcia G, Potter P, Rodas-Jorda A. Automatic corn (Zea mays) kernel inspection system using novelty detection based on principal component analysis. Biosystems Engineering, 2014; 117: 94–103.

Szczypiński P M, Klepaczko A, Zapotoczny P. Identifying barley varieties by computer vision. Computers and Electronics in Agriculture, 2015; 110, 1–8.

Chupawa P, Kanjanawanishkul K. Sweet Pepper Seed Inspection Using Image Processing Techniques. Advanced Materials Research, 2014; 931-932: 1614–1618.

Oliphant T E. Python for scientific computing. Computing in Science and Engineering, 2007; 9(3), 10–20.

Coelho L P. Mahotas: Open source software for scriptable computer vision. Journal of Open Research Software, 2013; 1(1): e3. doi: http://dx.doi.org/10.5334/jors.ac.

Walt S V D, Schönberger J L, Nunez-Iglesias J, Boulogne F, Warner J D, Yager N, et al. Scikit-image: Image processingin Python. PeerJ, 2014; 2:e453.

OpenCV. Open source computer vision. Available at: www.opencv.org. Accessed October 4, 2014.

Donis-González I R, Guyer D E, Leiva-Valenzuela G A, Burns J. Assessment of chestnut (Castanea spp.) slice quality using color images. Journal of Food Engineering, 2013; 115: 407–414.

Hu M K. Visual Pattern Recognition by Moment Invariants. IRE Transactions on Information Theory, 1962; 8(2): 179–187.

Chen Q, Petriu E, Yang X. A comparative study of Fourier descriptors and Hu’s seven moment invariants for image recognition. Electrical and Computer Engineering, Canadian Conference on 1, 2004; p103-106.

Teague M. Image analysis via the general theory of moments. Journal of the Optical Society of America, 1980; 70(8): 920–930.

Wang J, He J, Han Y, Ouyang C, Li D. An Adaptive Thresholding algorithm of field leaf image. Computers and Electronics in Agriculture, 2013; 96: 23–39.

Ding M Y, Chang J L, Peng J X. Research on moment invariant algorithm. Journal of Data Acquisition and Processing, 1992; 7(1): 1–9.

Wang X F, Huang D S, Du J X, Xu H, Heutte L. Classification of plant leaf images with complicated background. Applied Mathematics and Computation, 2008; 205(2): 916–926.

Haralick R M. Statistical and structural approaches to texture. Proc. IEEE, 1979; 67(5): 786–804.

Zhang J, Tan T, Ma L. Invariant texture segmentation via circular Gabor filters. 16th International Conference on Pattern Recognition (ICPR 2002), 11-15 August 2002, Quebec, Canada.

Kurtulmuş F, Lee W S, Vardar A. Green citrus detection using ‘eigenfruit’, color and circular Gabor texture features under natural outdoor conditions. Computers and Electronics in Agriculture, 2011; 78(2): 140–149.

Aghbashlo M, Mobli H, Rafiee S, Madadlou M. The use of artificial neural network to predict exergetic performance of spray drying process: A preliminary study. Computers and Electronics in Agriculture, 2012; 88: 32-43.

Boniecki P, Koszela K, Piekarska-Boniecka H, Weres J, Zaborowicz M, Kujawa S, et al. Neural identification of selected apple pests. Computers and Electronics in Agriculture, 2015; 110: 9–16.

Kujawa S, Nowakowski K, Tomczak R J, Dach J, Boniecki P, Weres J, et al. Neural image analysis for maturity classification of sewage sludge composted with maize straw. Computers and Electronics in Agriculture, 2014; 109: 302–310.

Omid M, Mahmoudi A, Omid M H. An intelligent system for sorting pistachio nut varieties. Expert Systems with Applications, 2009; 36(9): 11528–11535.

Nazghelichi T, Aghbashlo M, Kianmehra M H. Optimization of an artificial neural network topology using coupled response surface methodology and genetic algorithm for fluidized bed drying. Computers and Electronics in Agriculture, 2011; 75(1): 84–91.

Wang W, Paliwal J. Generalisation performance of artificial neural networks for near infrared spectral analysis. Biosystems Engineering, 2006; 94(1): 7–18.

Beale M H, Hagan M T, Demuth H B. Neural Network Toolbox User's Guide. The MathWorks, Inc., 2014; Natick, MA, USA.

Craninx M, Fievez V, Vlaeminck B, De Baets B. Artificial neural network models of the rumen fermentation pattern in dairy cattle. Computers and Electronics in Agriculture, 2008; 60(2): 226–238.

Møller M F. A scaled conjugate gradient algorithm for fast supervised learning. Neural Networks, 1993; 6(4): 525–533.

Riedmiller M, Braun H. A direct adaptive method for faster backpropagation learning: the RPROP algorithm. Proceedings of the IEEE International Conference on Neural Networks, 1993; 1, p586–591.

Patnaik L M, Rajan K. Target detection through image processing and resilient propagation algorithms. Neurocomputing, 2000; 35(1–4): 123–135.

Santra A K, Chakraborty N, Sen S. Prediction of heat transfer due to presence of copper–water nanofluid using resilient-propagation neural network. International Journal of Thermal Sciences, 2009; 48(7): 1311–1318.

Heaton J. Introduction to Neural Networks for Java: Feedforward Backpropagation Neural Networks. Available at: http://www.heatonresearch.com/node/707. Accessed on [2014-10-04].

Priddy K L, Keller P E. Artificial Neural Networks: An Introduction (SPIE Tutorial Texts in Optical Engineering, Vol. TT68), The International Society for Optical Engineering, 2005; Bellingham, Washington, USA.

Nixon M S, Aguado A S. Feature Extraction and Image Processing. Elsevier, 2008; London, UK.